Patent Publication Number: US-2003223979-A1

Title: Therapeutic method for treating patients with acute intermittent porphyria (AIP) and other porphyric diseases

Description:
FIELD OF THE INVENTION  
       [0001] The present invention relates to novel methods of treating and preventing disease caused by absence or deficiency of the activity of enzymes belonging to the heme biosynthetic pathway. More specifically, the invention pertains to methods of alleviating the symptoms of certain  porphyrias , notably acute intermittent  porphyria  including gene therapy, therapy wiht a combination of encymatically active substances and therapy with recombinant produced enzymes such as PBGD. In addition the invention relates to an expression plasmid and a linear DNA fragment for use in the production of rhPBGD.  
       BACKGROUND OF THE INVENTION  
       [0002] Heme Biosynthetic Pathway  
       [0003] Heme is a vital molecule for life in all living higher animal species. Heme is involved in such important processes as oxygen transportation (haemoglobin), drug detoxification (cytochrome P450), and electron transfer for the generation of chemical energy (ATP) during oxidative phosphorylation in mitochondria.  
       [0004] Heme is synthesised in eight consecutive enzymatic steps starting with glycin and succinyl-CoA. Sassa S. 1996, Blood Review, 10, 53-58 shows a schematic drawing (FIG. 1 in the article) of the heme biosynthetic pathway indicating that that the first enzymatic step (delta-aminolevulinic-synthetase) and the last three steps (coproporphyrinogen oxidase, protoporphyrinogen oxidase and ferrochelatase) are located in the mitochondrion whereas, the remaining are cytosolic enzymes.  
       [0005] Important regulation of the heme biosynthetic pathway is delivered by the end product of the metabolic pathway, namely heme, which exerts a negative inhibition on the first rate-limiting enzymatic step (conducted by delta-aminolevulinic-synthetase) in the heme biosynthetic pathway (Strand et al. 1970, Proc. Natl. Acad. Sci. 67, 1315-1320).  
       [0006] Deficiencies in the heme biosynthetic enzymes have been reported leading to a group of diseases collectively called  porphyrias.    
       [0007] A defect in the third enzymatic step leads to acute intermittent  porphyria , AIP.  
       [0008] Acute Intermittent Porphyria  
       [0009] Acute intermittent  porphyria  (AIP) is an autosomal dominant disorder in man caused by a defect (50% reduction of activity) of the third enzyme in the heme biosynthetic pathway, porphobilinogen deaminase, (also known as porphobilinogen ammonia-lyase (polymerizing)), E.C. 4.3.1.8. (Waldenström 1937, J. Acta.Med. Scand. Suppl.82). In the following, this enzyme and the recombinant human form will be termed “PBGD” and “rhPBGD”, respectively.  
       [0010] Clinical Manifestation of AIP  
       [0011] The reduction in enzymatic PBGD activity makes this enzyme the rate limiting step in the heme biosynthetic pathway, with a concomitant increase in urinary and serum levels of delta-aminolevulinic acid (ALA) and porphobilonogen (PBG).  
       [0012] The clinical manifestation of AIP involves abdominal pain and a variety of neuropsychiatric and circulatory dysfunctions. As a result of the enzymatic block, heme precursors such as PBG and ALA are excreted in excess amounts in the urine and stool. In acute attacks, high levels of PBG and ALA are also found in serum. These precursors are normally undetectable in serum in healthy individuals.  
       [0013] The neuropsychiatric disturbances observed in these patients are thought to be due to interference of the precursors with the nervous system or due to the lack of heme. For instance, ALA bears a close resemblance to the inhibitory neurotransmitter 4-aminobutyric acid (GABA) and has been suggested to be a neurotoxin. (Jeans J. et al. 1996, American J. of Medical Genetics. 65, 269-273).  
       [0014] Abdominal pain is the most frequent symptom in AIP patients and occurs in more than 90% during acute attacks, which will be followed rapidly by the development of peripheral neuropathy with weakness in proximal muscles, loss of pinprick sensation, and paraesthesia. Tachycardia, obstipation or diarrhoea may also be present. During acute attacks behavioral changes, confusion, seizures, respiratory paralysis, coma and hallucinations may be present.  
       [0015] Hypertension is also associated with AIP, with as high as 40% of patients showing sustained hypertension between attacks. An association between chronic renal failure (Yeung L. et al. 1983, Q J. Med 52, 92-98) and AIP as well as hepatocellular carcinoma. (Lithner F. et al. 1984, Acta.Med.Scand. 215, 271-274), has been reported.  
       [0016] The AIP is a lifelong disease, which usually becomes manifest in puberty.  
       [0017] Factors Precipitating Acute Attacks.  
       [0018] Most precipitating factors exhibit an association with the first rate-limiting enzyme in the heme biosynthetic pathway through heme, the final product of the pathway. A lowering of the heme concentration will immediately increase the rate of ALA-synthetase. An overproduction of ALA then makes the partially deficient PBGD enzyme (50% activity) now rate-limiting with an accumulation of the heme precursors ALA and PBG. Drugs that induces cytochrome P450 such as barbiturates, estrogens, sulphonamides, progesterone, carbamyazepine, and phenytoin can all precipitate acute attacks. (Wetterberg L. 1976, In Doss M. Nowrocki P. eds.  Porphyrias  in Human Disease. Reports of the discussion. Matgurg an der Lahn, 191-202).  
       [0019] The clinical manifestation is more common in women, especially at time of menstruation. Endocrine factors such as synthetic estrogens and progesterone are known precipitating factors. A significant factor is also the lack of sufficient caloric intake. Hence, caloric supplementation during acute attacks reduces clinical symptoms. (Welland F. H. et al. 1964, Metabolism,13, 232).  
       [0020] Finally, various forms of stress including illness, infections, surgery and alcoholic excess have been shown to lead to precipitation of acute attacks. There are also cases of acute attacks where no precipitating factor can be identified.  
       [0021] Prevalence of AIP  
       [0022] Prevalence of 0.21% has been reported (Tishler P. V. et al. 1985, Am.J.Psychiatry 142,1430-1436), with as high a prevalence as 1 per 1500 in geographic isolates in northern Sweden (Wetterberg L. 1967, Svenska bokförlaget Nordstedt, Stockholm). Prevalence up to 200 per 10,000 inhabitants has been reported from Arjepong in Northern Sweden (Andersson, Christer, Thesis, 1997, ISBN 91/7191/280/0, pp. 22-23).  
       [0023] Existing Treatment of AIP  
       [0024] The treatment of AIP as well as of other types of  porphyrias  such as  variegata , hereditary  coproporphyria, harderoporphyria , and aminolevulinic acid dehydratase deficiency, are basically the same. Existing therapies for AIP, are all aimed at reducing circulating PBG and ALA by inhibiting the first rate-limiting enzymatic step ALA-synthetase. This inhibition of ALA-synthetase is achieved by increasing circulating heme, since heme is a negative feed back regulator of ALA-synthetase. Hematin treatment, high caloric intake or inhibition of heme breakdown by Sn-mesoporphyrin administration are the existing therapies today. These therapies have shown limited efficacy.  
       [0025] Treatment between acute attacks involves sufficient caloric intake and avoidance of drugs and immediate treatment of infections.  
       [0026] Patients that experience acute attacks are treated with intravenous carbohydrates usually dextrose (300 g/day) and intravenous hematin (3-8 mg/(kg day)).  
       [0027] Treatments with long acting agonistic analogues of LHRH, have been shown to reduce the incidence of pre-menstrual attacks by inhibiting ovulation in AIP patients. Finally, treatments involving heme analogues Sn-mesoporphyrin, which inhibit heme breakdown have also been attempted.  
       [0028] Medical Need in AIP  
       [0029] The lack of effective treatment for AIP is well recognized. In a US mortality study in AIP patients requiring hospitalization it was concluded that the mortality rate was 3.2-fold higher as compared to a matched general population.  
       [0030] Suicide was also a major cause of death, occurring at a rate of 370 times that expected in the general population (Jeans J. et al. 1996, Am. J. of Medical Genetics 65, 269-273).  
       [0031] Hematin therapy is usually initiated when high caloric intake is not sufficient to alleviate acute attacks. Studies with hematin have been performed but these studies generally used the patients as their own control after the patients did not respond to high carbohydrate treatment (Mustajoki et al. 1989, Sem. Hematol. 26, 1-9).  
       [0032] The one controlled study with hematin treatment reported, failed to reach statistical significance due to too small a patient number (Herrick A. L. et al 1989, Lancet 1,1295-1297).  
       [0033] In conclusion, there is a definite need for the provision of novel therapeutic/prophylactic methods aimed at these diseases.  
       DISCLOSURE OF THE INVENTION  
       [0034] Levels of ALA and PBG found in urine in patients with symptomatic AIP, are in the range of 1-203 mg/day and 4-782 mg/day, respectively. Normal excretion of ALA and PBG is very low (0-4 mg/day). Important is the observation that these patients also have elevated levels of ALA and PBG in serum. It was shown in a study that AIP patients had significantly elevated levels of ALA (96 μg %) and PBG (334 μg %) in serum in connection with acute attacks and that the severity of the attacks were correlated to high levels of ALA and PBG. Hence, it is important to reduce the circulating levels of ALA and PBG in order to eliminate clinical symptoms and to normalize the heme pool.  
       [0035] The present inventors present a new therapeutic rational in the treatment of AIP, a rationale using PBGD, preferably recombinant human PBGD (rhPBGD), in order to reduce circulating high levels of PBG in serum by metabolizing (by enzymatic conversion) PBG to hydroxymethylbilane (HMB), which is the normal product of the reaction. This substitution therapy will lead to a normalization of PBG in serum as well as to a normalization of the heme pool. It will also lead to a normalization of ALA in serum, since these heme precursors are in equilibrium with each other. A lowering of serum ALA and PBG is expected to result in a concomitant relief of symptoms. The product of the reaction (HMB) will diffuse back into the cells and enter the normal heme biosynthetic pathway and will become subsequently metabolized to heme.  
       [0036] Alternatively investigations in treating the  porphyrias  have also suggested gene therapy, thus aiming at introducing genetic material in relevant cells, which will then take over the in vivo production of the enzyme of interest.  
       [0037] Hence, PBGD administered by injections will carry out its normal catalytic function by converting PBG to HMB in serum (extracellularly, not inside the cells). The new therapeutic idea is based on the assumption that ALA, PBG and HMB permeate cellular membranes or is transported specifically across them. An alternative to this is to administer a form of PBGD, which will be able to act intracellularly, either as a consequence of formulation or as consequence of modification of PBGD so as to facilitate its entry into cells from the extracellular compartment.  
       [0038] The observation that AIP patients have large amounts of these heme precursors in the serum supports the idea that PBG does not accumulate intracellularly, but is released from the cells into serum when the intracellular concentration increases due to the PBGD enzymatic block.  
       [0039] The basic new therapeutic concept for AIP is valid for all  porphyrias  and therefore the invention is in general aimed at treating these diseases by substituting the reduced or missing enzymatic activity characterizing the  porphyrias.    
       [0040] Hence, in its broadest aspect, the invention pertains to a method for treatment or prophylaxis of disease caused by deficiency, in a subject, of an enzyme belonging to the heme biosynthetic pathway, the method comprising administering, to the subject, an effective amount of a catalyst which is said enzyme or an enzymatically equivalent part or analogue thereof.  
       [0041] Hence, by the term “catalyst” is herein meant either the relevant enzyme which is substituted as it is, or an enzymatically equivalent part or analogue thereof. One example of an enzymatically equivalent part of the enzyme could be a domain or subsequence of the enzyme which includes the necessary catalytic site to enable the domain or subsequence to exert substantially the same enzymatic activity as the full-length enzyme or alternatively a gene coding for the catalyst.  
       [0042] An example of an enzymatically equivalent analogue of the enzyme could be a fusion protein which includes the catalytic site of the enzyme in a functional form, but it can also be a homologous variant of the enzyme derived from another species. Also, completely synthetic molecules that mimic the specific enzymatic activity of the relevant enzyme would also constitute “enzymatic equivalent analogues”.  
       [0043] In essence, the inventive concept is based on the novel idea of substituting the reduced enzymatic activity in the subject simply by administering a catalyst which will “assist” the enzyme which is in deficit. The precise nature, however, of the catalyst is not all-important. What is important is merely that the catalyst can mimic the enzymatic in vivo activity of the enzyme.  
       [0044] The term “the heme biosynthetic pathway” refers to the well-known enzymatic steps (cf. e.g. Sassa S. 1996, Blood Review, 10, 53-58) which leads from glycin and succinyl-CoA to heme, and enzymes belonging to this synthetic pathway are delta-aminolevulininic acid synthetase, delta-aminolevulinic acid dehydratase, porphobilinogen deaminase, uroporphyrinogen III cosythetase, uroporphyrinogen decarboxylase, coproporphyrinogen oxidase, protoporphyrinogen oxidase and ferrochelatase. Hence, in line with the above, a catalyst used according to the invention is such an enzyme or an enzymatically equivalent part or analogue thereof. It should be noted that the genes encoding all of the above-mentioned enzymes have been sequenced, thus allowing recombinant or synthetic production thereof.  
       [0045] The diseases related to reduced activity of these enzymes are acute intermittent  porphyria  (AIP), ALA deficiency  porphyria  (ADP),  Porphyria cutanea  tarda (PCT), Hereditary  coproporphyria  (HCP), Harderoporphyria (HDP),  Variegata porphyria  (VP),  Congenital erythropoetic porphyria  (CEP),  Erythropoietic protoporphyria  (EPP), and Hepatoerythropoietic  porphyria  (HEP).  
       [0046] By the term “effective amount” is herein meant a dosage of the catalyst which will supplement the lack or deficiency of enzymatic activity in a subject suffering from  porphyria  caused by reduced activity of one of the above-mentioned enzymes. The precise dosage constituting an effective amount will depend on a number of factors such as serum half-life of the catalyst, specific activity of the catalyst etc. but the skilled person will be able to determine the correct dosage in a given case by means of standard methods (for instance starting out with experiments in a suitable animal model such as with transgenic animals so as to determine the correlation between blood concentration and enzymatic activity).  
       [0047] The disease which is the preferred target for the inventive method is AIP, and therefore the catalyst is PBGD or an enzymatically equivalent part or analogue thereof. It is most preferred that the catalyst is a recombinant form of the enzyme belonging to the heme biosynthetic pathway or of the enzymatically equivalent part or analogue thereof, since recombinant production will allow large-scale production which, with the present means available, does not seem feasible if the enzyme would have to be purified from a native source.  
       [0048] Preferred formulations and dosage forms of the catalyst are exemplified for, but not limited to, PBGD in the detailed description hereinafter, and these formulations also are apparent from the claims. It will be appreciated that these formulations and dosage forms are applicable for all catalysts used according to the invention.  
       [0049] One important embodiment of the method of the inventions is one wherein the catalyst, upon administration, exerts at least part of its enzymatic activity in the intracellular compartment. This can e.g. be achieved when the catalyst is an enzymatically equivalent part or analogue of the enzyme, since such variations of the enzyme can be tailored to render them permeate cell membranes. Hence, when the catalyst is a small artificial enzyme or an organic catalyst which can polymerize porphobilinogen to hydroxymethylbilane, it should be possible for the skilled man to introduce relevant side chains which facilitates entry into the intracellular compartment. Alternatively, the catalyst is the enzyme, but formulated in such a manner that it exerts at least part of its enzymatic activity intracellularly upon administration to the subject. This can be achieved by tagging the enzyme with specific carbohydrates or other liver cell specific structures for specific liver uptake, i.e. the enzyme (or analogue) is modified so as to facilitate active transport into e.g. liver cells.  
       [0050] Although the above embodiments are interesting, it is believed that the normal, practical embodiment of the invention will involve use of a catalyst which exerts substantially all its enzymatic activity extracellularly in the bloodstream, since it is believed that the metabolic products of the enzymatic conversion of the relevant heme precursor will permeate freely into the intracellular compartment where the remaining conversions of the heme biosynthetic pathway can take place. Alternatively, the metabolic product may be excreted from the subject via urine and/or faeces at least to some extent.  
       [0051] As mentioned above, it is preferred that the catalyst is produced recombinantly, i.e. by a method comprising  
       [0052] a) introducing, into a suitable vector, a nucleic acid fragment which includes a nucleic acid sequence encoding the catalyst;  
       [0053] b) transforming a compatible host cell with the vector;  
       [0054] c) culturing the transformed host cell under conditions facilitating expression of the nucleic acid sequence; and  
       [0055] d) recovering the expression product from the culture and optionally subjecting the expression product to post-translational processing, such as in vitro protein refolding, enzymatic removal of fusion partners, alkylation of amino acid residues, and deglycosylation, so as to obtain the catalyst.  
       [0056] For relatively small catalysts (e.g. those constituted mainly of the active site of the enzyme), the catalyst can alternatively be prepared by liquid-phase or solid-phase peptide synthesis.  
       [0057] A more detailed explanation of the recombinant production of the model enzyme PBGD is given in the detailed section hereinafter, but as mentioned herein the same considerations apply for all other peptide catalysts of the invention. One of the main advantages of producing the catalyst by recombinant or synthetic means is, that if produced in a non-human cell, the catalyst is free from any other biological material of human origin, thus reducing problems with known or unknown pathogens such as viruses etc.  
       [0058] The dosage regimen will normally be comprised of at least one daily dose of the catalyst, (preferably by the intravenous route). Normally 2, 3, 4 or 5 daily dosages will be necessary, but if sustained release compositions are employed, less than 1 daily dosage are anticipated.  
       [0059] The daily dosage should be determined on a case by case basis by the skilled practitioner, but as a general rule, the daily dosage will be in the range between 0.01-1.0 mg/kg body weight per day of the catalyst. More often the dosage will be in the range of 0.05-0.5 mg/kg body weight per day, but it should never be forgotten that precise dosage depends on the dosage form and on the activity of the catalyst as well as on the degree of deficiency of the relevant enzyme or combinations of enzymes and an individualized treatment, where the dose is adjusted to normalize patient serum and urine precusor levels.  
       [0060] The most correct way of determining the correct dosage is based on the patient specific precursor levels. The precursor being the product of the enzymatic reaction.  
       [0061] For PBGD, the daily dosage is about 0.08-0.2 mg per kg body weight per day, and most often 0.1 mg per kg body weight per day will be the dosage of choice. It is believed that comparable dosages will be applicable for the other full-length enzymes or combinations of enzymes.  
       [0062] Finally, as will be appreciated from the above disclosure, the invention is based on the novel idea of providing substitution for the enzymes lacking in activity. To the best of the knowledge of the inventors, therapeutic use of catalysts having such effects have never been suggested before, and therefore the invention also pertains to a catalyst as defined herein for use as a pharmaceutical. Furthermore, use of such catalysts or combination of different catalysts for the preparation of pharmaceutical compositions for treatment of the above-discussed diseases is also part of the invention. 
     
    
    
     LEGENDS TO FIGURES  
     [0063]FIG. 1: Circular map of plasmid pPBGD1.1  
     [0064]FIG. 2: Flow chart for construction of plasmid pExp0  
     [0065]FIG. 3: Circular map of plasmid pExp0  
     [0066]FIG. 4: Flow chart for construction of plasmid pExp1  
     [0067]FIG. 5: Circular map of plasmid pExp1  
     [0068]FIG. 6: Flow chart for construction of pExp1-M2  
     [0069]FIG. 7: Circular map of plasmid pExp1-M2  
     [0070]FIG. 8: Flow chart for construction of rhPBGD expression plasmid pExp1-M2-BB  
     [0071]FIG. 9: Circular map of rhPBGD expression plasmid pExp1-M2-BB  
     [0072]FIG. 10: PCR strategy for construction of the EcoR I-Hind III linear DNA-fragment  
     [0073]FIG. 11: Structure of the EcoR I-Hind III linear DNA-fragment used for transformation  
     [0074]FIG. 12: Respiration and growth data from fermentation PD14 with strain PBGD-2  
     [0075]FIG. 13: rhPBGD expression in fermentation PD14 with strain PBGD-2  
     [0076]FIG. 14: Chromatography on DEAE-Sepharose FF (DEAE1)  
     [0077]FIG. 15: Chromatography on DEAE-Sepharose FF (DEAE2)  
     [0078]FIG. 16: Chromatography on Butyl-Sepharose 4 FF  
     [0079]FIG. 17: Circular map of rhPBGD-His expression plasmid pExp2  
     [0080]FIG. 18: PBGD reaction mechanism  
     [0081]FIG. 19: DEAE chromatography elution profile  
     [0082]FIG. 20: SDS-PAGE gel of DEAE eluates  
     [0083]FIG. 21: Cobalt chromatography elution profile  
     [0084]FIG. 22: SDS-PAGE gel results of cobalt eluates 
    
    
     SEQUENCE LIST  
     [0085] Seq. ID NO 1: Sequence of the expression plasmid pExp1-M2-BB  
     [0086] Seq. ID NO 2: Sequence of the EcoR I-Hind III linear fragment used for transformation in the hemC disruption strategy  
     [0087] Seq. ID NO 3: Sequence of the erythropoietic form (PBGD 1.1)  
     [0088] Seq. ID NO 4: Sequence of the non-erythropoietic form (PBGD 1.1.1)  
     [0089] Seq. ID NO 5: Sequence of PDGB from Spleen (PBGD 1.3)  
     [0090] Seq. ID NO 6: Sequence of PDGB from bone marrow (PBGD 2.1)  
     [0091] Seq. ID NO 7: Sequence of PDGB from bone marrow (PBGD 2.2)  
     [0092] Seq. ID NO 8: Sequence of PDGB from lymph node (PBGD 3.1)  
     [0093] Seq. ID NO 9: Sequence of PDGB from lymph node (PBGD 3.3)  
     [0094] Seq. ID NO 10: Sequence PDGB from total brain (PBGD 5.3)  
     [0095] Seq. ID NO 11: Sequence of PDGB from total brain (PBGD 6.1)  
     DETAILED DISCLOSURE OF THE INVENTION  
     [0096] In a first embodiment the invention relates to a method for treatment or prophylaxis of disease caused by deficiency, in a subject, of one or more enzymes belonging to the heme biosynthetic pathway, the method comprising administering, to the subject, an effective amount of a catalyst which is said enzyme or combination of enzymes or an enzymatically equivalent part or analogue thereof. The disease may be selected from the  phorphyria  group and the catalyst may be an enzyme selected from the group consisting of  
     [0097] delta-aminolevulininic acid synthetase,  
     [0098] delta-aminolevulinic acid dehydratase (ALAD),  
     [0099] porphobilinogen deaminase (PBGD),  
     [0100] uroporphyrinogen III cosythetase,  
     [0101] uroporphyrinogen decarboxylase,  
     [0102] coproporphyrinogen oxidase,  
     [0103] protoporphyrinogen oxidase, and  
     [0104] ferrochelatase,  
     [0105] or an enzymatically equivalent part or analogue thereof.  
     [0106] The invention also relates to any combination of the enzymes mentioned above because one enzymatic deficiency may cause such alterations of the pathway that alternative enzymatic reactions are needed wherein an otherwise normal production of an enzyme for such alternative pathway is not sufficient. In alternative, the disease relating to the heme biosynthetic pathway may also be due to a deficiency of more than only one enzyme. Accordingly, en the present context the term catalyst may also be interpreted as a combination of catalyst and the term enzyme may also include a mixture of different enzymes.  
     [0107] In a preferred embodiment, the disease is AIP and the enzyme is PBGD or an enzymatically equivalent part or analogue thereof optionally in combination with ALAD. In a further embodiment, the catalyst is a recombinant form of the enzyme belonging to the heme biosynthetic pathway or of the enzymatically equivalent part or analogue thereof.  
     [0108] The catalyst may be administered by a route selected from the group consisting of the intravenous route, the intraarterial route, the intracutaneous route, the subcutaneous route, the oral route, the buccal route, the intramuscular route, the anal route, the transdermic route, the intradermal route, and the intratechal route.  
     [0109] The catalyst is preferable formulated in an isotonic solution, such as 0.9% NaCl and 10-50 mM sodium phosphate pH 7.0+/−0.5 up to pH 8.0 or sodium phosphate, glycine, mannitol or the corresponding potassium salts. The catalyst may also be lyophilized, sterile filtered, and in a further embodyment formulated as lipid vesicles comprising phosphatidylcholine or phosphatidylethanolamine or combinations thereof. In a still other embodiment the catalyst is incorporated into erythrocyte ghosts.  
     [0110] Also a sustained release formulation may be performed involving biodegradable microspheres, such as microspheres comprising polylactic acid, polyglycolic acid or mixtures of these.  
     [0111] A further method according to the invention is wherein the catalyst is lyophilized in a two-compartment cartridge, where the catalyst will be in the front compartment and water for reconstitution in the rear compartment. The two compartment cartridge. may be combined with an injection device to administer the catalyst either by a needle or by a needle-less (high pressure) device.  
     [0112] It may also be very convenient to administer the catalyst in a formulation of a physiological buffer containing an enhancer for nasal administration.  
     [0113] Other formulations for the catalyst include an oral formulation containing lipid vesicles, such as those comprising phospatidylcholine, phosphatidylethanolamine, or sphingomyeline, or dextrane microspheres.  
     [0114] The formulation is preferable one that is able to enhance the half-life of the catalyst in the subject&#39;s bloodstream. This may by use of a formulation wherein the catalyst has a polyethylene glycol coating.  
     [0115] The catalyst may also be complexed with a heavy metal.  
     [0116] In a further aspect the catalyst is an enzymatically equivalent part or analogue of the enzyme and exerts at least part of its enzymatic activity intracellularly upon administration to the subject. This may be when the catalyst is a small artificial enzyme or an organic catalyst that can polymerise porphobilinogen to hydroxymethylbilane.  
     [0117] Furthermore, the catalyst may be said enzyme formulated in such a manner that it exerts at least part of its enzymatic activity intracellularly upon administration to the subject.  
     [0118] In addition the catalyst may be tagged with specific carbohydrates or other liver cell specific structures for specific liver uptake.  
     [0119] In a furhter aspect the catalyst exerts substantially all its enzymatic activity extracellularly in the bloodstream.  
     [0120] In a still further aspect, the enzymatic activity of the catalyst on its relevant heme precursor results in a metabolic product which 1) either moves into the intracellular compartment and is converted further via the remaining steps of the heme biosynthetic pathway or 2) is excreted from the subject via urine and/or faeces.  
     [0121] A further embodiment of the invention relates to a method wherein the catalyst has been prepared by a method comprising  
     [0122] a) introducing, into a suitable vector, a nucleic acid fragment which includes a nucleic acid sequence encoding the catalyst;  
     [0123] b) transforming a compatible host cell with the vector;  
     [0124] c) culturing the transformed host cell under conditions facilitating expression of the nucleic acid sequence; and  
     [0125] d) recovering the expression product from the culture and optionally subjecting the expression product to post-translational processing, such as in vitro protein refolding, enzymatic removal of fusion partners, alkylation of amino acid residues, and deglycosylation, so as to obtain the catalyst.  
     [0126] The catalyst may be prepared by liquid-phase or solid-phase peptide synthesis and it is preferable free from any other biological material of human origin.  
     [0127] As mentioned above the catalyst may be administered at least once a day, such as 2, 3, 4, and 5 times daily depending on the specific treatment regimen outlined for the patient in that precursor levels for each patient are measured before and/or during treatment for evaluation of the specific dosage.  
     [0128] Accordingly the daily dosage may be in the range of 0.01-1.0 mg/kg body weight per day, such as in the range of 0.05-0.5 mg/kg body weight per day. And the present invention also relates to the use of the catalyst for the preparation of a pharmaceutical composition.  
     [0129] It is estimated that a dosage will often be about 0.1 mg per kg body weight per day.  
     [0130] Accordingly, the invention also relates to a catalyst which is an enzyme of the heme biosynthetic pathway or an enzymatically equivalent part or analogue thereof, for use as a medicament. Thus in a further embodyment, the invention relates to a catalyst which is an enzyme of the heme biosynthetic pathway or an enzymatically equivalent part or analogue thereof for the preparation of a pharmaceutical composition for the treatment or prophylaxis of diseases caused by deficiency of said enzyme.  
     [0131] Naturally, the catalyst may be a recombinant form of the enzyme. An example is a recombinant human PBGD based on any of Seq. ID NO 3 and Seq. ID NO 4.  
     [0132] In a preferred embodiment and as will be disclosed in detail below, the invention also relates to a method for treating a patient having af mutation in the PBGD gene causing an enzyme defect, the method comprising use of a human PBGD cDNA sequence of either non-erythropoitic form or erythropoitic form according to the tissue in which PBGD should be expressed, and transfecting the patient with the relevant cDNA. Preferably the enzyme deficiency is selected from enzyme deficiencies resulting in a disease selected from Acute intermittent  porphyria , (AIP), ALA deficiency  porphyria  (ADP),  Porphyria cutanea  tarda (PCT), Hereditary  coproporphyria  (HCP), Harderoporphyria (HDP),  Variegata porphyria  (VP), Congenital erythropoietic  porphyria  (CEP),  Erythropoietic protoporphyria  (EPP), and  Hepatoerythropoietic porphyria  (HEP).  
     [0133] In a preferred embodiment, the human PBGD cDNA sequence is selected from Seq. ID NO 3 and Seq. ID NO 4.  
     [0134] The transfection may be by use of a vector vector selected from adenovirus, retrovirus and associated adenovirus. The PBGD gene transfer vector into human cells (erythropoeitic and/or non-erythropoietic) preferable results in normal PBGD activity or in an activity wherin the patient is free of symptoms of disease.  
     [0135] A further method of gene therapy treatment of patients with Acute Intermittent Porphyria (AIP) according to the invention is by a correction of one of the specific point mutations identified causing AIP by use of chimeraplasty gene repair. This involve specific designed oligonucleotides and a specific knowledge of both the mutation to be corrected and to the sequence on both sides on the mutation.  
     [0136] In a specific embodiment of chimeraplasty gene repair is by use of a delivery system for transfection by use of non-viral vectors formulated in a vehicle preparation comprisng one or more components selected from cationic phospholipids, phospholipids, phospholipids mixed with neutral lipids, lictosylated PEI, liposomes liposomes comprising mixtures of natural phopholipids and neutral lipids.  
     [0137] The mutation may be selected from the mutations shown in Table A.  
     [0138] The following description of preferred embodiments of the invention will focus on recombinant production of PBGD and formulations and uses thereof. It will be appreciated, however, that all disclosures relating to this polypeptide apply also for the other enzymes mentioned above. Hence, production and use of PBGD only exemplifies the invention, but all other enzymes of the heme biosynthetic pathway can substitute PBGD in the embodiments described hereinafter.  
     [0139] Production of Recombinant Human PBGD (rhPBGD)  
     [0140] As mentioned above, it is preferred to administer recombinant human versions of the various enzymes of the heme biosynthetic pathway. In the following will be described recombinant production of one of these enzymes, namely PBGD.  
     [0141] The gene for the erythropoietic PBGD, which is located in the human genome in the chromosomal region 11q24, is composed of 15 exons spanning 10 kb of DNA and is shown in Grandchamp B. et al. 1996, J. of Gastroenerology and Hepatology 11, 1046-1052.  
     [0142] The gene coding the erythropoietic PBGD enzyme (344 amino acids) (Raich N. et al 1986, Nucleic. Acid. Res, 14, 5955-5968), will be cloned from a human erythropoietic tissue by use of a nested PCR (polymerase chain reaction) strategy.  
     [0143] The PBGD coding region will be inserted in a plasmid and transformed into a suitable host cell (a bacterium such as  E. coli  and  B. subtilis , or a fungus such as Saccharomyces). The expression of the PBGD gene will be regulated by a promoter which is compatible with the selected host cell.  
     [0144] For bacterial production: An endogenous ATG sequence is located at the NH 2 -terminal end of the PBGD structural gene for initiation of translation and cytoplasmic expression. Alternatively insert in front of the PBGD coding region a bacterial signal sequence for example an  E. coli  periplasmic enzyme signal peptide or a signal peptide from a secreted enterotoxin or endotoxin in  E. coli , to obtain secretion in  E. coli.    
     [0145] The plasmid used for production of rhPBGD in  E. coli  was constructed in the following way:  
     [0146] Construction of the Plasmid Harboring the Coding Region of Human Wild Type PBGD (pBPGD1.1)  
     [0147] Introduction:  
     [0148] The erythropoietic expressed form of porphobilinogen deaminase (PBGD) (Raich N. et al. Nucleic Acids Research 1986 14(15): 5955-67) was cloned and sequence determined. Two forms of PBGD are known. The erythropoietic form is expressed specifically in erythroid progenitors and the constitutive form is expressed in all cells (Grandchamp B. et al. 1987, Eur J Biochem. 162(1):105-10). The two are expressed from the same gene and are identical except for the addition of 17 amino acids at the amino terminus of the constitutive form through alternative exon usage. It was decided to clone and express the erythropoietic form. There are three sequences for PBGD in the Genebank, the two isoforms mentioned above and the genomic sequence (Yoo H W. et al. 1993, Genomics. 15(1):21-9). These all have nucleotide differences translating to amino acid changes. Before choosing a specific sequence to be expressed for a human therapeutic it was therefore necessary to determine what is the wild type allele. To accomplish this, PBGD cDNA clones were isolated and sequenced from a number of sources to define the most common amino acid usage. Oligonucleotide primers were designed to amplify the coding region from cDNAs by Polymerase Chain Reaction (PCR) (Saiki R. K. et al. 1985, Science 230(4732):1350-4). These were used to isolate cDNAs from 5 sources of mRNA which were then cloned into a plasmid vector. Eight of these clones were sequenced and along with the published sequences define a wild type allele, which should be the most common amino acid sequence in the population. This wild type allele will be used for protein expression.  
     [0149] Strategy:  
     [0150] A nested PCR strategy was devised to clone PBGD. The first primer set, (see Table 1) Ico379 and Ico382, are 20mers that bind to sequence outside of the coding region. Ico379 is specific for the 5′ untranslated region of the mRNA (cDNA) of the erythropoietic form of PBGD. The binding site is in an exon region not expressed in the constitutive form of the enzyme. Ico382 binds to the 3′ untranslated region of both forms of PBGD. Internal to these are a second set of oligonucleotide primers to be used for the second round of PCR, Ico375 and Ico376, designed to distal ends of the PBGD coding region. Ico375 has 22 bases of sequence homologous to the 5′ end of the coding region of the erythropoietic form of PBGD with the ATG start codon followed by an EcoR I endonuclease cleavage site for cloning of the PCR product and 4 bases of sequence to ensure efficient restriction. Ico376 has 33 bases homologous to the 3′ end of the PBGD coding region with 3 bases changed internally to introduce a Mun I/Mfe I endonuclease cleavage site through silent mutations and ending with the TAA stop codon. This restriction site will be used to easily introduce sequence encoding a His-Tag to the DNA with oligonucleotide adapters or to enable other 3′ modifications. Following the stop codon is a second stop codon to ensure good termination of translation and a Hind III endonuclease cleavage site for cloning the PCR product followed by 4 bases to ensure efficient restriction. The EcoR I and Hind III endonuclease cleavage sites introduced onto the ends of the PBGD PCR product ligate into the respective unique restriction sites in the high copy number pBluescriptII SK-(Stratagene) vector for sequencing and will then be used to move the PBGD DNA into an  E. coli  expression vector for production of recombinant human porphobilinogen deaminase, rhPBGD.  
     [0151] PCR:  
     [0152] Six cDNAs were used as a PCR source; spleen, bone marrow, lymph node, lung, whole brain and adipose tissue each from a different pool of human donors (produced by Donald Rao using BRL Superscript II with 500 ng Clontech poly-A RNA in 20 μl reaction volumes per manufacturers instructions except adipose which was made from 5 μg of Clontech total RNA from a single donor). List of equipment and supplies used (see lists below). One μl of each cDNA (approximately 25 ng) was amplified with Advantage cDNA polymerase mix (Clontech) with 0.2 mM dNTP (PE/ABI) and 0.3 μM each of Ico379 and Ico382 in 50 μl reaction volumes. Two cycle PCR was used, with an initial heat denaturation step at 94° C. for 1′40″ then 28 cycles of 96° C. for 16″ and 68° C. for 2′. A final extension of 6′ at 74° C. ensured that extension products were filled out. One fifth of the reaction was run out on a 1.2% agarose gel with 2 μl of 6× ficol loading dye in 0.5× TBE buffer (Maniatis T., E. F. Fritsch, J. Sambrook. Molecular Cloning (A laboratory Manual) Cold Spring Harbor Laboratory. 1982). The predicted band of 1.1 kb. was observed by ethidium bromide staining with all sources but lung tissue cDNA. These bands were excised and DNA was isolated with Microcon-30 with micropure inserts (Amicon/Millipore) per manufacturers instructions and buffer exchanged with dH 2 O. One tenth of the recovered DNA was amplified with Advantage cDNA polymerase mix (Clontech) with 0.2 mM dNTP (PE/ABI) and 0.3 μM each of the internal nested oligonucleotides (Ico375 and Ico376) at 0.3 μM in 50 μl reactions. Two cycle PCR was used again with an initial heat denaturation step at 94° C. for 1′ 40″ then 2 cycles of 96° C. for 16″ and 68° C. for 2′ then 13 cycles of 96° C. for 16″ and 72° C. for 2′ with a final extension of 6′ at 74° C. Ten μl of the 50 μl reactions were run on a 1.2% agarose gel with 2 μl 6× loading dye. The resulting bands were of the expected size, 1.05 kb. The remainder of the PCR reactions were passed through Chromaspin-400 columns (Clontech) per manufacturers instructions to remove reaction components and to exchange buffer with TE (10 mM Tris-HCl pH8.0/1 mM EDTA). The DNA containing eluates were washed with dH 2 O and concentrated with Microcon-100 spin-filters (Amicon/Millipore) as described by the manufacturer&#39;s instructions.  
     [0153] Cloning:  
     [0154] The purified PBGD DNA was digested for 6 hours with 40 Units each of EcoR I and Hind III in EcoR I “U” buffer (New England Biolabs (NEB)) in 50 μl reactions at 37° C. Enzymes were heat killed for 20 minutes at 68° C. and reactions were spun in Microcon 100 spin-filters to remove small DNA end pieces, washed with dH 2 O and concentrated. One fifth of the resulting DNA was ligated with approximately 50 ng EcoR I and Hind III digested and twice gel purified pBluescriptII SK-(Stratagene) and 200 units T4 DNA ligase (NEB cohesive end units) for 15 hours at 16° C. The ligase was heat killed at 75° C. for 10 minutes. The reactions were then buffer exchanged with dH 2 O and concentrated in Microcon-100 spin filters and volumes taken up to 5 μl with dH 2 O. One μl each was electroporated into 25 μl DH10B Electromax cells (Gibco/BRL) at 2.5 Kv/200 Ohms/25 μF in 0.1 cm cuvets with a BioRad electroporator. One ml of SOC medium (Gibco/BRL) was added and the cells were outgrown at 37° C. for one hour at 250 rpm. Cells were plated out on LB plates (Maniatis T., E. F. Fritsch, J. Sambrook. Molecular Cloning (A laboratory Manual) Cold Spring Harbor Laboratory. 1982) with 150 μg/ml ampicillin. The efficiency of all five were approximately twice background (vector ligated without insert). Colony PCR was used to analyze 18 transformants of each electroporation for the presence of PBGD. An internal PBGD specific primer (ICO381) was used with a pBluescript specific primer (ICO385) to both confirm identity and proper orientation in the vector. The 25 μl reactions were set up on ice to inactivate proteases with primer concentrations of 0.4 μM, 0.125U Taq polymerase (Fisher), and 0.2 mM dNTP(PE/ABI.) Two cycle PCR was used, with an initial heat denaturation step at 94° C. for 1′ 40″ a further denaturing step at 96° C. for 20 seconds, then 30 cycles of 96° C. for 16″ and 68° C. for 1′ with a final extension of 4′at 74° C. Five μl of 6× loading dye was added and 12.5 μl each were run out on a 1.2% agarose gel. Results are as follows: 12/18 positive colonies for spleen; 10/18 for bone marrow; 8/18 for lymph node; 9/18 for brain and 10/18 for adipose tissue. Two positive colonies each for the first 3 and 1 each for the latter two were grown up in 25 ml. liquid LB culture with 150 μg/ml ampicillin over night at 37° C. with 250 rpm. Plasmid DNA was purified from the cultures with Qiagen&#39;s Tip-100 DNA purification kit per manufacturer&#39;s instructions. UV absorbance at 260 nm was used to determine the plasmid yields which varied from between 131 and 169 μg of highly purified DNA.  
     [0155] Sequencing:  
     [0156] Sequencing reactions of double stranded plasmid DNA with Big Dye terminator cycle sequencing were performed in a 9700 thermocycler (Perkin Elmer/Applied Biosystems) Two vector primers (ICO383 and ICO384) and two PBGD specific internal primers (ICO380 and ICO381) were used for all 8 plasmids. In addition a fifth vector primer (ICO385) was used for the brain and adipose derived clones. Reaction conditions were per manufacturers protocol as follows: 500 ng plasmid DNA and 4 pmol oligonucleotide primer with 8 μl ready mix in 20 μl volumes with 30 cycles of 96° C. for 12″ and 60° C. for 4′. Extension products were purified by isopropanol precipitation. To each reaction 20 μl of dH 2 O and 60 μl isopropanol were added. These were mixed by inversion and allowed to sit at room temperature for 15 minutes then spun for 40′ at 3250 rpm in a Beckman GS-6KR centrifuge with the GH3 rotor and Microplate+carriers. Reactions were inverted then spun at 1680 rpm for 1′ to remove liquid from the pelleted DNA. DNA sequence analysis was performed at the University of Washington Biochemistry Department sequencing Laboratory with an Applied Biosystems 377 sequencer.  
     [0157] Analysis:  
     [0158] The inserts of all 8 clones were confirmed to be PBGD by complete double strand sequence analysis (see sequences 1-8). Each has some change(s) from the published sequences. Some changes are unique and some are shared with other clones (see Table 2 and Table 3). For differences found only in one clone, it is difficult to distinguish between PCR or cloning artifacts and actual allelic variations without additional sampling. However, when the same base difference is found in more than one sequence it is unlikely to be from cloning errors. From the alignment of all 11 PBGD sequences a set of common bases emerged, the consensus or wild type allele sequence. Five of the eight clones (1.1, 1.3, 2.1, 3.3, and 5.3.) have the wild type amino acid sequence. Within this set with wild type amino acid sequence, there is only one difference at the nucleic acid level. At position 555, 4 of the 5 sequences have a dGTP while 1 along with the published erythropoietic and genomic PBGD have a dTTP. These appear to be two common alleles, which result in no amino acid difference. There are 2 base changes between clone number 1.1 and the published erythropoietic PBGD. An adenine to guanine change at base 513 (Leu 171) is a silent mutation, which is also present in 9 out of the 11 sequences, compared. The second difference is a cytosine to adenine substitution at base 995 (Thr 332.) This is not a silent change, with a threonine to asparagine non-conservative mutation. It appears however that the difference is an error in the published erythropoietic PBGD sequence since all 10 other sequences have an adenine at this position. In addition to these natural variations, there are three additional silent mutations introduced during the cloning at positions 1017, 1018 and 1020 to create a Mun I site for future manipulations. The PBGD gene was ligated into pBluescript SK plasmid generating the pSK-PBGD 3988 bp plasmid, which was sequenced.  
     [0159] Conclusion:  
     [0160] For any recombinant therapeutic protein it is important that the wild type allele be used to reduce the potential for immunogenicity. We feel confident through our survey of the literature and analysis of PBGD sequence from different individuals that clone number 1.1 represents the most prevalent “wild type” allele in the population with respect to amino acid sequence. Clone number 1.1 contains the consensus wild type amino acid sequence and differs from the published erythropoietic PBGD sequence by only one amino acid. Because this difference is found in all the other PBGD clones besides the erythropoietic PBGD sequence, it, rather than the published erythropoietic sequence, is deemed to be the prevalent wild type sequence. For this reason PBGD encoded by clone number 1.1 was chosen for production of recombinant human porphobilinogen deaminase (rhPBGD). In the following, the plasmid encoding the human wild type PBGD in clone number 1.1 will be termed “pPBGD1.1”.  
     [0161] Equipment and supplies lists are shown in appendix 1 and 2, respectively.  
                   TABLE 1                       Oligonucleotide primers used for PCR amplification           and sequencing of PBGD:                                        Ico375-pbgds    (32 mer)   coding region 5′ end w/EcoRI site sense           5′CGT G GA ATT C AT GAG AGT GAT TCG CGT GGG TA 3′               Ico376-pbgda    (47 mer)   coding region 3′end w/HindIII site antisense       5′GGA G AA GCT T AT TAA TGG GCA TCG TTC AAT TGC CGT GCA ACA TCC AG 3′               Ico379-esnonc  (20 mer)   erythropoietic form non-coding sense       5′TCG CCT CCC TCT AGT CTC TG 3′               Ico380-sinter  (21 mer)   internal coding sense       5′CAG CAG GAG TTC AGT GCC ATC 3′               Ico381-ainter  (21 mer)   internal coding antisense       5′GAT GGC ACT GAA CTC CTG CTG 3′               Ico382-anonc    (20 mer)   non-coding antisense       5′CAG CAA CCC AGG CAT CTG TG 3′               Ico383-pSKT7    (22 mer)   pBluescript T7 promoter       5′GTA ATA CGA CTC ACT ATA GGG C 3′               Ico384-pSKpjrev (22 mer)   pBluescript reverse1       5′CTA AAG GGA ACA AAA GCT GGA G 3′               Ico385-pSKrev   (21 mer)   pBluescript reverse2       5′CAG CTA TGA CCA TGA TTA CGC 3′                  
 
     [0162]               TABLE 2                          Variation of PBGD clones from published erythroid sequence:                             Differences from               Erythroid mRNA                                             non-   total   Genebank           PBGD clone   silent   silent   diffs   No.   Reference/Source               Erythroid   0   0   0   X04217   Raich. N. et. al. 1986, Nucleic Acids                           Res. 14 (15), 5955-5968       Constitutive   1   2   3   X04808   Grandchamp. B. et. al. 1987, Eur. J. Biochem.                           162 (1), 105-110       Genomic   1   2   3   M95623   Yoo, H. W. et. al. 1993,                           Genomics 15 (1), 21-29       1.1   1   1   2   —   Spleen (Clontech mRNA Lot No. 7120266)       1.3   2   1   3   —   Spleen (Clontech mRNA)       2.1   2   1   3   —   Bone Marrow (Clontech mRNA)       2.2   2   2   4   —   Bone Marrow (Clontech mRNA)       3.1   2   4   6   —   Lymph Node (Clontech mRNA)       3.3   3   1   4   —   Lymph Node (Clontech mRNA)       5.3   2   1   3   —   Total Brain (Clontech mRNA)       6.1   3   2   5   —   Adipose Tissue (Clontech mRNA)                    
     [0163] Table 2:  
     [0164] Summary of the number of differences in amino acid sequence of our sequenced PBGD clones and clones from Genebank entries for the constitutive and genomic PBGD with published Erythropoietic PBGD sequence. Shown in different columns are the total number of silent mutations with a DNA base change not causing a corresponding amino acid change, the number of non-silent mutations with a DNA change causing an amino acid difference and the sum of the two types of mutations. Not included in this table are the three silent mutations introduced into the clones to create an internal Mun I endonuclease cleavage site. Note that clone number 1.1 which will be used for production of recombinant human porphobilinogen deaminase (rhPBGD) has only one of each type of difference with the least number of total differences.  
               TABLE 3                          Summary of mutations found in PBGD clones:                                                                             aa   aa No.   bp No.   mutation   aa change   cons.   gen.   1.1   1.3   2.1   2.2   3.1   3.3   5.3   6.1   No./10                                                                                     Asp   19   56   A→G   Asp→Gly                           X               1       Phe   108   322   T deletion   frame shift                       X                   1       Lys   140   419   A→G   Lys→Arg                           X               1       Leu   160   478   C→A   Leu→Met       X                                   1       Ala   168   503   C→T   Ala→Val                           X               1       Leu   171   513   A→G   silent       X   X   X   X   X   X   X   X   X   9       Val   185   555   T→G   silent   X           X   X   X       X   X   X   7       Glu   193   577   G→A   Glu→Lys   X                                       1       Gly   243   729   C→T   silent                               X           1       Ala   280   840   T→C   silent                                       X   1       Ala   286   856   G→A   Ala→Thr                                       X   1       Lys   328   984   A→G   silent                           X               1       Thr   332   995   C→A   Thr→Asn   X   X   X   X   X   X   X   X   X   X   10       Gln   339   1017   G→A   silent           X   X   X   X   X   X   X   X   8       Gln   339   1018   C→T   silent           X   X   X   X   X   X   X   X   8       Leu   340   1020   T→G   silent           X   X   X   X   X   X       X   7       Leu   340   1020   T deletion   frame shift                                   X       1                       # Listed in different columns are the amino acid, base number from the ATG start codon, the actual genetic difference with corresponding amino acid change if any and a listing of the clones with differences shown with an X. In the final column the total number of clones with the different mutations are shown. The three mutations at position 1017, 1018 and 1020 are introduced with IC0376 during PCR amplification to create a Mun 1 endonuclease cleavage site.        # Note that clone number 1.1 which will be used for represented by a number of other clones.           
 
     [0165] Expression Plasmids  
     [0166] Construction of the Basic Expression Plasmid pExp0  
     [0167] The basic expression plasmid pExp0 was constructed by excising the PBGD coding sequence (cDNA) from plasmid pPBGD1.1 (see FIG. 1) with EcoR I and Hind III and inserting it into the vector pKK223-3 (Pharmacia, Catalogue #27-4935) cut with the same enzymes, thus operatively linking it to the IPTG-inducible tac promoter (Amann E. et al. 1983, Gene 25(2-3):167-178). FIG. 1 shows the construction details. Plasmid pExp0 was constructed for a preliminary assessment of the expression levels and does not directly lead to the construction of the final expression plasmid.  
     [0168] Construction of the Final Expression Plasmid  
     [0169] The final expression plasmid pExp1-M2-BB (FIG. 9) was constructed in a multi-step process. The individual steps used and all the intermediate plasmids are outlined below.  
     [0170] Construction of Plasmid pExp1  
     [0171] Plasmid pExp1 was first constructed with modifications to the 5′ untranslated region and the initial part of the coding sequence both aimed at improving translation efficiencies (Gold L. and Stormo G. D. 1990, Methods Enzymol 185:89-93). The changes are indicated below, and include, insertion of a second ribosome binding site, an AT-rich sequence preceding the ATG and three silent base substitutions shown in boldface.  
                          AATTCTAACA TAAGTTAAGG AGGAAAAAAA A ATG AGA GT T  ATT CG T  GT C  GGT AC                                              Met-Arg-Val-Ile-Arg-Val-Gly          
 
     [0172] A naturally occurring Kpn I site six amino acid residues into the coding sequence of the human cDNA for PBGD (pPBGD1.1) was exploited for this purpose. Oligonucleotides ICO386 and ICO387 were designed to provide upon annealing to each other a 5′ EcoR I adhesive end and a 3′ Kpn I sticky end and the elements described above including the codons for the first six amino acid residues as shown. Oligonucleotides ICO386 and ICO387 were annealed and ligated with the Kpn I-Hind III, PBGD fragment from pPBGD1.1 into EcoR I-Hind III linearised pBluescript II SK-(Stratagene, Catalogue#212206) to yield plasmid pPBGD1.1Tra. In the second step, the EcoR I-Hind III fragment from pPBGD1.1Tra was ligated into pKK223-3 cut with the same enzymes resulting in plasmid pExp1 (FIGS. 4 and 5).  
     [0173] Construction of Plasmid pExp1-M2  
     [0174] The tetracycline resistance gene was next restored using the following strategy. Plasmid pExp1 was cut with Sal I and BamH I and the 5349 base-pair fragment containing part of the tetracycline coding sequence and the bulk of the plasmid was isolated. Into this was ligated the Sal I-Hind III fragment from pBR322 (New England BioLabs, Catalogue #303-3S) containing rest of the coding sequence and an adapter formed by annealing oligonucleotides ICO424 and ICO425 to each other. The adapter contains part of the tetracycline promoter and provides Hind III and BamH I overhangs for ligation but destroys the Hind III and BamH I restriction sites. The resulting plasmid was called pExp1-M2 (FIGS. 6 and 7).  
     [0175] Construction of Plasmid pExp1-M2-BB  
     [0176] In the final step the rop gene contained between BsaA I and BsaBI was deleted to increase copy number (Makrides S. C. 1996, Microbiol.Rev. 60(3):512-538). For this the plasmid pExp1-M2 was cycled through the dam minus strain, JM110 (F′[traD36 proA +  proB +  lacI q  A (lacZ)M15] dam dcm supE44 hsdR17 thi leu thr rpsL lacY galK galT ara tonA tsx Δ (lac-proAB) lambda − ) as restriction with BsaB I is blocked by overlapping dam methylation. It was then cut with BsaA I and BsaB I to excise the rop gene and the 5446 base-pairs long linear fragment was circularised by blunt-end ligation to yield the production plasmid pExp1-M2-BB (FIGS. 8 and 9).  
     [0177] Construction of the hemC-Deletion Host and the Final Expression Strain  
     [0178] The parent strain JM105 (F′[traD36 proA+proB+lacI q  Δ(lacZ)M15] Δ(pro-lac) hsdR4 sbcB15 rpsL thi endA1 lambda − ), a derivative of  E. coli  K12 was obtained from Parmacia, Catalogue #27-1550-01. The hemC gene coding for the endogenous  E. coli  Porphobilinogen Deaminase was partially deleted. This was necessary to ensure that the purified product (rhPBGD) was free from contaminating  E. coli  PBGD as the  E. coli  and human enzymes are very similar in properties (Jordan P. M. 1994, Wiley, Chichester (Ciba Found Symp 180), p70-96) and may co-purify. The hemC-deletion host was derived from JM105 according to Scheme A. First a hemin-permeable variant was obtained by a three-step process. This was essential as a hemC-deletion mutant would require hemin for good growth and  E. coli  K12 strains are not freely permeable to hemin.  
                 
 
     [0179] All mutant isolation was spontaneous. Approximately 5×10 −8 -5×10 −9  cells were plated on selective media. The media compositions are included as Appendix 1.  
     [0180] * For details on the linear DNA-fragment see FIG. 11.  
     [0181] In the first step, a heme-minus mutant was isolated carrying a defect in any of the biosynthetic steps leading to the formation of heme. Heme −  strains fall into the general class of respiration deficient mutants that are defective in active transport and consequently resistant to low levels of antibiotics of the aminoglycoside family such as gentamicin (Lewis L. A. et al. 1991, Microbiol.Immunol. 35(4):289-301). Several spontaneous mutants were isolated as a dwarf colonies on LB+glucose +G-418 (gentamicin)-containing plates (Lewis L. A. et al. 1991, Microbiol.Immunol. 35(4):289-301). These were screened for their ability to respond weakly to hemin, indicating that they were heme −  (as opposed to other respiration deficient mutants which would not respond to hemin at all). One such heme-strain (JM105-2-4, see Scheme A) which could also revert back spontaneously to robust growth on LB (as this is essential for the third step, see below) was selected. This strain was next plated on LB+hemin to obtain a better grower in the presence of hemin and was called JM105-H. It showed improved growth only in the presence of hemin, which meant that it still was heme −  but had become hemin-permeable. To restore the functionality of the heme biosynthetic pathway in JM105-H, spontaneous revertants were isolated on LB plates and only those retained which resembled the starting strain JM105 in growth, both untransformed and after transformation with the expression plasmid. One such strain used in this study was called JM105-H-R6 and should have retained the heme-permeable trait of its parent strain.  
     [0182] Strain JM105-H-R6 was transformed with the EcoR I-Hind III fragment (see Scheme A), to obtain the hemC-deletion host called JM105-H-R6-C by homologous gene replacement. This strain has the genotye, F′[traD36 proA+proB+lacI q  Δ(lacZ)M15] Δ(pro-lac) hsdR4 sbcB15 rpsL thi endA1 lambda −  hemC:CAT hemin-permeable. It was transformed with the expression plasmid pExp1-M2-BB to yield the final production strain PBGD-2 (PBGD-2 was deposited under the Budapest Treaty on Jul. 9, 1999 with DSMZ (Deutsche Sammlung von Mikroorganismen und Zellkulturen, GmbH, Mascheroder Weg 1b, D-38124 Braunschweig, Germany) under the accession No. DSM 12915).  
     [0183] In order to obtain the EcoR I-Hind III fragment, a multiple PCR strategy was used. Olignucleotide pairs ICO437, 1C0438 and ICO505, ICO440 were used to amplify separately, portions of  E. coli  JM105 genomic DNA segments flanking the hemC gene (see FIG. 10). These amplified gene products were digested with pairs of enzymes EcoR I, Xho I and Xho I, Hind III respectively, and in essence, assembled together between the EcoR I and Hind III sites of pUC19 to give plasmid phemCd. Next the fragment containing the chloramphenicol-resistance gene was PCR amplified from plasmid pBC SK+ (Stratagene, Catalogue #212215) using oligonucleotides ICO510 and ICO511. This product was cut with Xho I and inserted into plasmid phemCd at the Xho I site. In essence, the plasmid having the Cam gene in the orientation shown was called phemCdCm and formed the source of the EcoR I-Hind III linear DNA-fragment depicted in FIG. 11.  
     [0184] In FIG. 11 the structure of the linear DNA-fragment used for the transformation is shown. The genetic organization of the  E. coli  polypeptides depicted by gray arrows (cyaA, hemC-5′, hemC-3′, hemX and hemD) is derived from the GenBank report Accession number AE000456. The black arrow represents the 767 base-pairs long PCR fragment carrying the cholamphenicol-resistance gene (Cam), encoding chloamphenicol acetyltransferase (CAT), replacing 806 base-pairs of the hemC coding sequence. HemC-5′ and hemC-3′ correspond to 149 and 16 base-pairs respectively, of the coding sequence of the disrupted hemC gene. EcoR I, Xho I and Hind III are engineered restriction sites. The sequence of this 3225 base-pairs long fragment is shown in Seq. ID NO 2. The two Xho I sites are at positions 1072 and 1839 in the sequence, respectively.  
                   TABLE 4                       Oligonucleotide primers used in the construction of the production           strain PBGD-2                                        ICO386     (54 mer)    Construction of plasmid pExp1           5′ AAT TCT AAC ATA AGT TAA GGA GGA AAA AAA AAT GAG AGT TAT TCG TGT       CGG TAC 3′               ICO387     (46 mer)   Construction of plasmid pExp1       5′ CGA CAC GAA TAA CTC TCA TTT TTT TTT CCT CCT TAA CTT ATG TTA G 3′               ICO424     (32 mer)   Construction of plasmid pExp1-M2       5′ GAT CAC TCA TGT TTG ACA GCT TAT CAT CGA TT 3′               ICO425     (31 mer)   Construction of plasmid pExp1-M2       5′ AGC TAA TCG ATG ATA AGC GTC AAA CAT GAG T 3′               ICO437     (32 mer)   Amplification of product P1       5′ AGT CAG AAT TCA GAC GCA CGG CGG TAC GAT AA 3′               ICO438     (32 mer)   Amplification of product P1       5′ ATT CAC TCG AGG TCA CCA TCG GTA CCA GTT CA 3′               ICO440     (32 mer)   Amplification of product P2       5′ AGA TCA AGC TTC GGC CAG ACG CAG GTT ATC TA 3′               ICO505     (34 mer)   Amplification of product P2       5′ ATA CAC TCG AGA CCG GCA TGA GTA TCC TTG TCA C 3′               ICO510     (30 mer)   Amplification of Cam gene       5′ ACT GAC CTC GAG CGG CAC GTA AGA GGT TCC 3′               ICO511     (29 mer)   Amplification of Cam gene       5′ ACT GAA CTC GAG AAT TAC GCC CCG CCC TG 3′                  
 
     [0185] Accordingly, the cDNA used for expressing rhPBGD was derived from plasmid pPBGD1.1.  
     [0186] The starting host strain was derived from JM105 and is called JM105-H-R6-C. The genotype and the details on its construction are described above. A large part of the coding region of the hemC gene was replaced by the Cam gene, encoding chloramphenicol acetyltransferase. This gene replacement was confirmed by PCR amplification of the segment of the  E. coli  genome followed by restriction analysis of the amplified product. As a result of the gene replacement, the strain is resistant to chloramphenicol and grows extremely poorly on LB medium. Growth improves when LB medium is supplemented with hemin.  
     [0187] Expression Construct  
     [0188] The expression plasmid in the final production strain is pExp1-M2-BB. Its construction is described above. A detailed map of the plasmid showing the open reading frames and functionally relevant regions is shown in FIG. 9. The complete DNA sequence is included in Seq. ID NO 1. All synthetic adapters and linkers used during the construction have been sequenced along with all junctions created during ligation which directly impinge upon the expression of the cloned gene.  
     [0189] Production Strain  
     [0190] The final production strain is called PBGD-2. It was obtained by introducing the expression plasmid pExp1-M2-BB into the host strain JM105-H-R6-C, essentially, by rendering the cells competent with 100 mM CaCl 2  (Morrison D. A. 1979, Methods.Enzymol. 68:326-331) and selecting for transformants on LB+ampicillin media at 30° C. The plasmid is a derivative of pBR322 without the rop gene and should be present extrachromosomally in moderate copy number at 30° C. with a slightly higher copy number at elevated temperatures 37° C. and greater (Makrides S. C. 1996, Microbiol.Rev. 60(3):512-538). It has both the ampicillin and tetracycline resistance genes as selectable markers. It also expresses rhPBGD which can complement the hemC defect of the host strain. As a result, the production strain should grow normally on LB/M9 media, be resistant to the antibiotics ampicillin and tetracycline and also be resistant to the antibiotic chloramphenicol (because of the presence of the Cam gene in the genome). It was confirmed to have all these characteristics.  
     [0191] Expression  
     [0192] The expression of rhPBGD is driven by the tac promoter which is regulated by the copy of the lacI q  gene present in the host. Due to the modifications made to the system as described in the study plan, the uninduced level of expression is 1.8 units/mg (see Appendix 3 for assay details), which amounts to approximately 10% of the total soluble protein. The culture is grown throughout at 30° C. and no induction step is used to increase expression.  
     [0193] Evaluation and Conclusions  
     [0194] The expression system developed for the production of rhPBGD in  E. coli  is a stable system, producing good amounts of rhPBGD in a constitutive manner when the cells are grown at 30° C. The host strain employed is partially deleted for the gene producing the endogenous  E. coli  porhobilinogen deaminase. After transformation with the expression plasmid, the resulting production strain PBGD-2 grows as well as the strain PBGD-1 (which is JM105 carrying the same expression plasmid) and makes the same amount of rhPBGD.  
     [0195] Alternative Expression Construct:  
     [0196] Expression Plasmid pExp1-M2-Puc-BB and Expression of rhPBGD in  E. coli    
     [0197] The plasmid pExp1-M2 was digested with Pvu I and Afl III and the larger of the two fragments corresponding to a size of 4745 base-pairs was isolated. This was ligated to the 1257 base-pairs long Pvu I-AflIII fragment derived from pUC19 containing the origin of replication and part of the ampicillin resistance gene to obtain plasmid pExp1-M2-Puc. This was passaged through JM110 and cut with BsaA1 and BsaB1 to excise the rom gene contained between the two sites and blunt-ended together to yield the final expression plasmid pExp1-M2-Puc-BB. The pExp1-M2-Puc-BB plasmid has been fully sequenced and differs from pExp1-M2-BB only in that C in position 2769 is T in pExp1-M2-Puc-BB.  
     [0198] Expression of rhPBGD in  E. coli    
     [0199] The  E. coli  K12 host strain JM105 genotype endA thi rpsL sbcB15 hsdR4 Δ(lac-proAB) [F′traD36 proAB lacI q  Δ(lacZ)M15] containing the expression plasmid pExp1-M2-Puc-BB was grown in LB broth containing 100 μg/ml ampicillin at to mid-log phase at 30° C. from a 1 to 40 dilution of an overnight inoculum. The culture was then split into three and growth was continued for another 4 hours at 30° C., 37° C. and 42° C. respectively. Cells were spun down from 1 ml samples and frozen at −20° C. The thawed cell pellets were resuspended in 200-300 μl of B-PER reagent PIERCE Cat. #78243, incubated at room temperature for 10 minutes, spun at 16,000 for 10 minutes and PBGD activity was determined in the supernatants. Total protein was estimated by the Bradford method using the BioRad reagent Cat #500-0006 and bovine serum albumin as stsndard. The specific activities in the crude lysates obtained at the three growth temperatures are tabulated below. The results clearly show an increase of PBGD units/mg with increasing temperature in the range from 30° C. to 40° C.  
                                                   Temperature   PBGD Units/mg                                                    30° C.   363           37° C.   573           42° C.   1080                      
 
     [0200] Other Production Systems For rhPBGD  
     [0201] For yeast production, the PBGD coding sequence can be inserted into a plasmid vector, for example YEP type, containing 2 u circular DNA (Ori) origin for high expression in yeast. YEP plasmids contain TRP 1 and URA 3 as markers for selective maintenance in trp1-, ura 3-yeast strains.  
     [0202] Alternatively, the PBGD gene can be inserted in bovine papilloma virus vectors BPV for high expression in a murine cell line C-127 (Stephens P. E. et. al. Biochem J. 248, 1-11, 1987) or vectors compatible with expression in CHO cells or COS cells.  
     [0203] An expression of PBGD can be made intracellularly.  
     [0204] A secretory signal in Saccharomyces, for example alpha-mating factor presequence, can be added in front of the rhPBGD structural gene for efficient secretion in yeast.  
     [0205] Similarly, a sequence encoding a mammalian signal peptide can be added for secretion of rhPBGD into the culture medium upon expression in for example CHO cells or COS cells.  
     [0206] A bacterial promoter for example the tryptophane (trp) promoter or the lac promoter or alternatively an alkaline phosphatase promoter, should be inserted before the PBGD coding region for efficient transcription in prokaryotes for example  E. coli.    
     [0207] A yeast promoter for example 3-phosphoglycerate kinase (PGK) or chelatin or alpha-mating factor should be inserted before the PBGD coding region for efficient transcription in yeast for example  Saccharomyces cerevesiae  or  Saccharomyces pombe.    
     [0208] A mammalian promoter for example Metallothionin-1 (MT-1) or Aspartate transcarbamylase or Dihydrofolate reductase (DHFR) should be inserted before the PBGD coding region for efficient transcription in mammalian cell lines for example CHO cells or COS cells.  
     [0209] The yeast plasmid (Y-G&amp;F-PBGD) containing a yeast promoter, signal and/or ATG codon (methionine) in front of the PBGD coding region and a yeast vector containing selectable markers such URA 3 or TRP 1 will be transformed into the yeast host cell such as  Saccharomyces cerevesiae  or  Saccharomyces pombe  for production of rhPBGD.  
     [0210] The mammalian plasmid (M-G&amp;F-PBGD) containing a mammalian promoter for example Metallothionine-1 or Dihydrofolate reductase and a mammalian signal sequence or an ATG codon in front of the PBGD coding region and vector pAT or pSV2 respectively. Plasmid (M-G&amp;F PBGD) may be transfected into a mammalian cell line for example CHO cells, for production of rhPBGD.  
     [0211] The  E. coli  cell containing plasmid (pExp1 or pExp1-M2 Puc-BB), may be fermented to stationary phase between 24-48 hours, in a medium containing casein hydrolysate, or yeast extract, glucose, vitamins and salts. pH oxygen may be monitored by electrodes during fermentation. Temperature will be kept at 37+/−2 C. during the fermentation.  
     [0212] The yeast cell containing the plasmid (Y-G&amp;F-PBGD), may be fermented to late log phase between 20-40 hours in a medium containing yeast extract, glucose, salts and vitamins. pH and temperature will be monitored by specific electrodes during fermentation. Temperature will be kept at 30±2 C. during fermentation.  
     [0213] The mammalian cell line containing the plasmid (M-G&amp;F-PBGD) may be fermented in a medium containing, foetal calf serum (or serum free), vitamins, glucose, antibiotics, growth factors. pH and temperature will be monitored continuously during fermentation by specific electrodes.  
     [0214] Fermentation and Purification  
     [0215] rhPBGD may be recovered from  E. coli  after fermentation by an extraction procedure involving for example ribipress, sonication, osmotic shock or total solubilization by detergent for example Tween 80, Triton X-100 or Brij. rhPBGD will be recovered from fermentation medium after production in yeast or from a total cellular extract using detergents such as Triton X-100, Tween 80 or Brij. rhPBGD will be recovered from mammalian culture medium or from a total cellular extract by ion-exchange chromatography or affinity chromatography.  
     [0216] rhPBGD may be purified from  E. coli  extract or from yeast medium or total cellular extract or from mammalian culture medium or total mammalian cellular extract by binding to an ion-exchange column for example DEAE-Sepharose or MonoQ-Sepharose and eluted with for example NaCl and Sodium phosphate buffer pH 7-8 or the corresponding potassium salts.  
     [0217] Alternatively, rhPBGD may be recovered from extracts by binding to an affinity chromatography column for example an anti-PBGD affinity column. rhPBGD will be eluted by lowering the pH to 4−2, or a thiol specific affinity column. rhPBGD has been “tagged” with thiols residues when a thiol affinity column step is used. Thiols will be removed by a specific enzymatic cleavage step to generate authentic rhPBGD.  
     [0218] The ion-exchange or affinity purified rhPBGD will be further purified by hydrophobic interaction chromatography on for example, TSK Phenyl 5 PW column or Octyl-Sepharose or Phenyl-Sepharose columns.  
     [0219] Binding of rhPBGD may be done at high ionic strength for example in 10-50 mM Tris-HCl pH 7-8, 1M NaCl or 10-15 mM Sodium phosphate pH 7-8, 0.5 M MgSO 4  and eluted by lowering the ionic strength for example with 10-50 mM Tris-HCl pH 7-8 or 10-50 mM Sodium phosphate pH 7-8.  
     [0220] Three hydrophobic interaction steps will be applied consecutively.  
     [0221] rhPBGD is further purified with preparative RP-HPLC for example C12 or C18 matrixes. The rhPBGD is be eluted from the column by a gradient of 10-50 mM Sodium phosphate and 1-10% acetonitrile buffer.  
     [0222] Formulation of rhPBGD is done by passing the enzyme over a G-100 Sephadex column and eluting it in an isotonic solution for example 0.9% NaCl and 10-50 mM Sodium phosphate pH7.0+/−0.5 or Sodium phosphate, glycin, mannitol or the corresponding potassium salts.  
     [0223] For the preparation of a medicament, the formulation solution of rhPBGD may be sterile filtered and filled aseptically in glass vials and lyophilised.  
     [0224] Alternatively, the sterile filtered rhPBGD solution is formulated in for example, lipid vesicles constituting phosphatidylcholine or phosphatidylethanolamine or combinations of these or incorporated into erythrocyte ghosts.  
     [0225] Reconstitution of lyophilised rhPBGD may be done in water for injection.  
     [0226] Alternatively, rhPBGD is formulated in a sustained release formulation involving a biodegradable microspheres, for example in polylactic acid, polyglycolic acid or mixtures of these.  
     [0227] Alternatively, rhPBGD is lyophilized in a two-compartment cartridge, where rhPBGD will be in the front compartment and water for reconstitution in the rear compartment. This two compartment cartridge may be combined with an injection device to administer either rhPBGD by a needle or needle less (by high pressure) device.  
     [0228] Alternatively, rhPBGD may be formulated in a physiological buffer containing an enhancer for nasal administration.  
     [0229] Alternatively, rhPBGD is formulated in an oral formulation containing for example, lipid vesicles (phospatidylcholine, phosphatidylethanolamine, sphingomyeline) or dextrane microspheres.  
     [0230] Although recombinant production of PBGD is preferred for the treatment of AIP, it can alternatively be produced from human red blood cells.  
     [0231] A general production and manufacturing of recombinant PBGD may be done by the following steps.  
     [0232] Recombinant PBGD Production Process; an Outline  
     [0233] A: Fermentation  
     [0234] 1. Master cell bank  
     [0235] 2. Working cell bank  
     [0236] 3. Production of seed culture  
     [0237] 4. Fermentation in large fermenter (250 L&gt;)  
     [0238] B. Purification  
     [0239] 1. Cell concentration by filtration/centrifugation  
     [0240] 2. Cell disruption  
     [0241] 3. Ultrafiltration  
     [0242] 4. Chromatography ion exchange, DEAE-Sepharose, MonoQ-Sepharose  
     [0243] 5. Hydrophobic interaction chromatography (Octyl/phenyl-Sepharose, TSK Phenyl, 5PW, Phenyl -Sepharose  
     [0244] 6. Chromatography ion exchange (MonoQ)  
     [0245] 7. Formulation by Gel filtration Sephadex G-100  
     [0246] C. Manufacturing  
     [0247] 1. Sterile filtration  
     [0248] 2. Aseptic filling  
     [0249] 3. Lyophilization  
     [0250] Treatment of Other Porphyrias  
     [0251] In analogy with the new treatment of AIP patients with (recombinant) PBGD, hepatic Porphyrias such as ALA deficiency  Porphyria  (ADP),  Porphyria cutanea  tarda (PCT), Hereditary Coproporphyria (HCP) and  Variegata Porphyria  (VP) can benefit from substitution therapy by rALA dehydratase, rUroporphyrinogen decarboxylase, rCoproporphyrinogen oxidase and rProtoporphyrinogen oxidase, respectively.  
     [0252] Patients having  Erythropoetic Porphyrias  such as Congenital  erythropoietic Porphyria  (CEP) or  Erythropoietic protoporphyria  (EPP) will benefit from substitution therapy with ruroporphyrinogen III syntetase and rFerrochelatase, respectively.  
     [0253] Hepatoerythropoietic Porphyrias  e.g.  Hepatoerythropoietic Porphyrias (HEP) can be treated with rUroporphyrinogen decarboxylase.  
     [0254] All  porphyrias  can be treated by the administration of the enzymatic activity lacking or being reduced (normally 50%) in any of the eight steps in the heme biosynthetic pathway as described above.  
     [0255] The substitution of the enzymatic activity can be achieved by adding the corresponding recombinant enzyme or other molecules that will provide the missing enzymatic activity.  
     [0256] Gene Therapy as and Alternative Treatment for Patients wiht Acute Intermittent Porphyria (AIP)  
     [0257] The human enzyme Porphobilinogen deaminase PBGD is coded for by a single gene located on chromosome 11q24.  
     [0258] Mutations in this gene causes the disease Acute Intermittent Porphyria (AIP). The disease has been shown to be inhereted in an autosomal dominat way.  
     [0259] Today over 100 mutations in the PBGD gene has been identified (Grandchamp B. J. Ganstroenterology and Hepathology, 11, 1046-1052, 1996, Table A) and the number is expected to increase when modern diagnostic systems based on screening programs will be applied more routinely in hospitals. A number of these mutations are shown in Table A.  
               TABLE A                          Reported mutations in the PBGD gene                                     Position   Mutation   Consequences   Reference                                             Exon 1   3   ATG→ATA   Translation   18                   impairment           33   GCG→GCT   DS   17       Intron 1    33 + 1   gtg→atg   DS   16       Exon 3   76   CGC→TGC   R26C   25           77   CGC→CAC   R26H   26       Exon 4   91   GCT→CACT   A31T   24           97   Del A   Frameshift   25           100   CAG→AAG   Q34K   27           100   CAG→TAG   Q34X   25           125   TTG→TAG   L42X   19       Exon 5   163   GCT→TCT   A55S   24           174   Del C   Frameshift   24           182   Ins G   Frameshift   24       Intron 5   210 + 1   gta→ata   DS (Del exon 5)   24       Exon 6   218-219   Del AG   Frameshift   24       Exon 7   277   GTT→TTT   V93F   24           293   AAG→AGG   K98R   25           331   GGA→AGA   G111R   28       Intron 7   345 − 1   cag→caa   AS (Del exon 8)   29       Exon 8   346   CGG→TGG   R116W   20           347   CGG→CAG   R116Q   30       Exon 9   445   CGA→TGA   R149X   25           446   CGA→CAA   R149Q   31           446   CGA→CTA   R149L   24           463   CAG→TAG   Q155X   32           470   Ins A   Frameshift   29       Intron 9   499 − 1   cag→caa   AS (Del exon 10)   21       Exon 10   499   CGG→TGG   R167W   33           500   CGG→CAG   R167Q   27, 34           518   CGG→CAG   R173Q   34           530   CTG→CGG   L177R   27           593   TGG→TAG   W198X   19           604   Del G   Frameshift   35           610   CAG→TAG   Q204X   30           612   CAG→CAT   DS (Del 9 bp   31                   exon 10)       Exon 11   625   GAG→AAG   E209K   28       Intron 11   652 − 3   cag→gag   AS (Del exon 12)   33       Exon 12   667   GAA→AAA   E223K   24           673   CGA→GGA   R225G   25           673   CGA→TGA   R225X   25           713   CTG→CGG   L238R   25           715-716   Del CA   Frameshift   19           730-731   Del CT   Frameshift   36           734   CTT→CGT   L245R   31           739   TGC→CGC   C247R   36           740   TGC→TTC   C247F   18           742   Ins 8 bp   Frameshift   24           748   GAA→AAA   E250K   24           754   GCC→ACC   A252T   36           755   GCC→GTC   A252V   36           766   CAC→AAC   H256N   27           771   CTG→CTA   DS (Del exon 12)   39           771   CTG→CTC   DS (Del exon 12)   37       Intron 12   771 + 1   gta→ata   DS (Del exon 12)   19       Exon 13   806   ACA→ATA   T269I   30           820   GGG→AGG   G274R   30       Exon 14   838   GGA→AGA   G280R   25           848   TGG→TAG   W283X   30           886   CAG→TAG   Q296X   25           900   Del T   Frameshift   31       Intron 14   912 + 1   gta→ata   DS (Del exon 14)   28       Exon 15   1062   Ins C   Frameshift   38           1073   Del A   Frameshift   25                  
 
     [0260] In one aspect, the present invention relates to a therapeutic method for AIP patients based on gene therapy.  
     [0261] The gene therapy treatment may involve the following steps.  
     [0262] 1. Identification mutations in the PBGD gene causing AIP in humans  
     [0263] 2. Selection of human PBGD cDNA sequence for gene therapy  
     [0264] 3. Construction of PBGD gene therapy vectors.  
     [0265] 4. Production of PBGD gene transfer vector  
     [0266] 5. Delivery system of PBGD gene transfer vector  
     [0267] 1. Identification of Mutations in the PBGD Gene Causing AIP in Humans  
     [0268] Patients having a point mutation in Exon 10 at position 593 TGG&gt;TAG have a change in the amino acid sequence of the PBGD enzyme from W198X (stop codon). This mutation is carried by approximately 50% of all AIP patients in Sweden (Lee J S. et al. Proc. NatI. Acad. Sci. USA, 88,10912-10915, and 1991). AIP patients with other mutations than W198X, which might also benefit from gene therapy, are given in Table A.  
     [0269] 2. Selection of Human PBGD cDNA Sequence for Gene Therapy  
     [0270] There are two isoenzyme forms of human PBGD e.g. erythropoietic and the non-erythropoietic form, which are formed by an alternative splicing mechanism. The non-erythropoietic form has a 17 amino acid extension on the N-terminal end of the erythropoietic PBGD form.  
     [0271] Non-Erythropoietic PBGD Form (nPBGD):  
                          Met-Ser-Gly-Asn-Gly-Asn-Ala-Ala-Ala-Thr-Ala-Glu-Glu-Asn-Ser-Pro-Lys- Met - Arg - Val . . .             ATG-TCT-GGT-AAC-GGC-ATT-GCG-GCT-GCA-ACG-GCG-GAA-GAA-AAC-AGC-CCA-AAG-ATG-AGA-GTG . . .           
 
     [0272] Erythropoietic PBGD Form (ePBGD):  
                                        Met - Arg - Val -               ATG-AGA-GTG . . .          
 
     [0273] The nucleotide and amino acid sequence for human PBGD that will be used for gene therapy differs from that published by Raich N. et al. Nucl. Acid. Res. 14, 5955-5968, 1986 in that the amino acid residue in position 332 is an Asn residue rather than Thr. In order to make the “wild type enzyme” and avoiding formation of antibodies the PBGD sequence has to contain an Asn residue in position 332. The cDNA sequence that will be used for the erythropoietic PBGD form is shown above.  
     [0274] Patient with a defect erythropoietic PBGD enzyme will be transfected with the erythropoietic PBGD cDNA sequence and patients with a defect in the non-erythropoietic form will be transfected with the non-erythropoietic cDNA sequence.  
     [0275] 3. Construction of PBGD Gene Therapy Vectors  
     [0276] Adenoviral Vector System  
     [0277] The vector is based on adenovirus type 5 (Ad5), containing three essential genetic loci E.g. E1, E2, E4, encoding important regulatory proteins and one locus E3 which is non-essential for virus growth. Deletion of E1A and E1B region renders the virus replication deficient in vivo. Efficient complementation of the E1 function (recombinant viral stocks) can be obtained in an E1 expressing cell line such as human 293-cell line.  
     [0278] The human PBGD cDNA will be inserted in an adenovirus vector system.  
     [0279] The PBGD transgenes will be driven by the endogenous PBGD promoter or a cytolomega virus promoter (CMV).  
     [0280] Retroviral Vectors  
     [0281] Retroviral vectors are well suited for gene delivery for several reasons:  
     [0282] 1. simplicity  
     [0283] 2. capacity to integrate up to 8 kbp DNA inserts  
     [0284] 3. their safety, non pathogenic to humans  
     [0285] 4. easy to improve and manipulate  
     [0286] 5. defined integration sites of genes  
     [0287] 6. long term regulated expression  
     [0288] One major disadvantage with the retroviral vectors though, is that they can only transduce dividing cells.  
     [0289] Most common retroviridae considered for gene therapy, are the lentiviridae and the mammalian C-type viridae. Other type retroviruses have also been considered. One such example, is a Moloney-murine leukemia retrovirus (Mo-MLV), which has been successfully used to transduce mouse and human fibroblasts with the uroporphyrinogen III synthetase (UROIIIS). (Moreau-Gaudry et al. Human Gene Therapy 6,13-20,1995).  
     [0290] The expression of the UROIIIS gene was driven by long terminal repeat (LTR). The UROIIIS cDNA was also successfully transduced by the retrovirus vectors into human peripheral blood progenitor cells.  
     [0291] The erythropoietic PBGD cDNA sequence can be inserted in a retrovirus vector LXSN (Miller et al BioTechniques 7, 980-990,1989) and pMFG ( Dranoff et al. Proc. Natl. Acad.Sci. USA. 90,3539-3543, 1993). This will lead to the following constructs e.g. LePSN and pMFG-ePBGD, respectively.  
     [0292] LePSN:  
                 
 
     [0293] For transduction of non-erythropoietic tissues the non-erythropoietic cDNA (See sequence 12) will be inserted in the LSXN vector and the pMFG vector resulting in the LSnPN and pMFG-nPBGD vectors, respectively.  
                 
 
     [0294] The LePSN and LnPSN vectors can be converted to the corresponding virus by transfer into an appropriate host cell line e.g. Ψ CRE as described by (Danos et al. Proc. Natl. Acad. Sci. USA. 85, 6460-6464,1988). Filtered supernatants from ectopic virus producing cells were added to amphotropic cells Ψ CRIP, in the presence of Polybrene. Clones can be isolated and tested for virus. Clones that show titers over 1.000.000 cfu/ml will be saved (resistant to G418). The LnPSN vector will be cotransfected with the pMCl-Neo plasmid (Pharmacia, Sweden) into the packaging cell line Ψ CRIP. Clones that shows integration of provirus and high expression levels of message will be selected.  
     [0295] Filtrate from supernatants from virus producing cells (erythropoietic PBGD form) can be mixed with Polybrene and incubated with peripheral blood progenitor cells (bone marrow transplant) from an AIP patient for several hours. The transduced progenitor cells can then be transplanted back into an AIP patient.  
     [0296] The success of the treatment will be measured as the increase in the PBGD activity in erythrocytes and reduced excretion of ALA and PBG in the urine. Clinically a success of the treatment can be evaluated as a reduction of frequency of spontaneous acute attacks or drug-induced attacks. This will be a more convenient way of administering the recombinant PBGD enzyme than regular injections. The efficacy of the therapy can be evaluated by measuring the PBGD activity in blood and reduced excretion of PBG and ALA in the urine. Clinically, a successful treatment should result in less number of acute attacks or preferably no more attacks.  
     [0297] Associated Adenovirus System (AAV)  
     [0298] AAV is a non-pathogenic human virus (Parvovirus) carried by more than 80% of all people.  
     [0299] The advantage with AAV as compared to retroviral systems is that AAV can transduce both dividing and non-dividing cells. The virus genome, which is small, contains two Inverted Therminal Repeats (ITR) and a REP and CAP functions. The REP and CAP functions can be deleted and exogenous cDNA inserted. Construction of an AAV vector containing the erythropoietic PBGD cDNA can be made. This AAV/PBGD vector will be suitable to transduce AIP patient&#39;s bone muscle cells, as a “muscle factory” for PBGD enzyme production. The PBGD cDNA will be engineered in such a way that a signal sequence for secretion will be added on the 5′-end of the cDNA. This will allow the erythropoietic PBGD enzyme to become secreted from the muscle cells into the blood stream. By this system patients will receive a constant delivery of active PBGD enzyme into the bloodstream, which will metabolize PBG thereby avoiding acute attacks.  
     [0300] Non-erythropoietic  
     [0301] Alternatively, liver cells can be transduced with AAV containing the non-erythropoietic PBGD cDNA. The construct will be engineered in such a way that the translated PBGD enzyme will remain intracellular e.g. contain a Met residue at the N-terminal end of the PBGD enzyme without a signal sequence for secretion in mammalian cells. The PBGD transgene will be transcribed and translated into new PBGD enzymes that will remain intracellularly. Levels of new PBGD enzymes made in the liver will be normalized the PBGD activity to 100%. AIP patients have usually reduced PBGD activity (50-80%) in the liver depending on the mutation and individual variations.  
     [0302] This treatment would aliviate the clinical symptom e.g. acute attacks with abdominal pain and reduce excretion of PBG and ALA in the urine. The AAV containing the non-erythropoietic PBGD form can also be used to correct the genetic defect in other cell types such as neuronal tissue, pancreas spleen e.g. non-erythropoietic tissue, by a similar mechanism.  
     [0303] Erythropoietic  
     [0304] The erythropoietic PBGD cDNA can be inserted in an AAV vector and used to transduce erythropoietic cells and stem cells in AIP patients, having a mutation affecting the erythropoietic form of PBGD.  
     [0305] 4. Production of PBGD Gene Transfer Vector  
     [0306] Adenovirus have approximately 36 kbp double stranded DNA, containing three essential early gene loci (E1, E2, and E4) encoding important regulatory proteins. Loci E3 codes for a gene product that block immune response to virus infected cells in vivo. The PBGD gene transfer adenovirus vector can be produced by deleting the E1 and E3 loci. The PBGD gene cassette is inserted in that position instead. The virus will be replication defective when the E1 locus has been deleted. Efficient E1 complementation and thus high yield of recombinant virus vector (PBGD) can be obtained in an E1 expressing cell line, such as the human 293 cell line. (Graham, F. et al. 1977, Characteristics of a human cell line transformed by DNA from human adenovirus 5. J. Gen. Virol. 36, 59-72).  
     [0307] 5. Delivery Systems of PBGD Gene Transfer Vectors.  
     [0308] Delivery of viral vectors are based on injection into the patient of a virus particle that will transduce human cells in vivo.  
     [0309] Correction of Point Mutations Causing AIP by Chimeraplasty Gene Repair  
     [0310] The basic technique involves the synthesis of chimeric (RNA-DNA) oligonucleotides. The oligonucleotide will repair point mutations on the chromosome by binding to the site of mutation and create a mismatch. The endogenous “mismatch repair system” which is present in all living cells, will correct the mutation.  
     [0311] The Chimeric oligonucleotides has the following general properties:  
     [0312] a. 68 mer (65-70 is acceptable size)  
     [0313] b. 25 base DNA stretches at the 5′-end homologous to the normal sequence of the gene  
     [0314] c. the 25 base DNA is designed in such a way the 12 bp on each side of the mutation is complementary to “wild-type DNA” where the mutation to be altered is located at position 13  
     [0315] d. the 25 mere contains 4 T bases at the one end to loop back the oligo to the other DNA strand with a 25 base sequence homologous to the other strand of the chromosomal DNA.  
     [0316] e. the second strand is chimeric in that it contains 10 homologous bases of 2′O methyl RNA followed by 5 bases of DNA (containing a central mismatch e.g. correction of the human point mutation by mismatch repair) followed by another stretch of 10 bases of homologous 2′O methyl RNA. This stretch of DNA/RNA is followed with 5 bases of GC clamp and 4 T bases to form the second loop and finally a 5 base CG clamps complementary to the other one.  
     EXAMPLE A  
     [0317] Correction of the PBGD Mutation at Position 593 TGG&gt;TAG Resulting in W198X  
     [0318] Normal Chromosomal Sequence:  
                                      5′-AG CGC ATG GGC T G G CAC AAC CGG GT-3′                  Gln Arg Met Gly  Trp  His Asn Arg Val          
 
     [0319] AIP Chromosomal Sequence:  
                                      5′-AG CGC ATG GGC T A G CAC AAC CGG GT-3′                          Stop          
 
     [0320] The sequence of the chimeric oligonucleotide ( Heme593W/X) is:  
                 
 
     [0321] The same principle of chimeric oligonucleotide can be constructed to correct any of the mutations causing AIP depicted in Table A.  
     [0322] Chimeric oligonucleotides can be used to correct any other point mutation causing any of the 8 known Porphyrias in a similarly as described above.  
     [0323] Delivery of PBGD Gene Transfer of Non Viral Vectors to Humans  
     [0324] The chimeric oligonucleotide can be formulated in a vechicles preparation containing anionic or cationic phospholipids or phospholipids mixed with neutral lipids or lictosylated PEI.  
     [0325] Alternatively, the non-viral vectors can be formulated in liposomes containing mixtures of natural phospholipids and neutral lipids.  
     [0326] Specific protein sequences can be incorporated into liposomal membranes, that recognizes cellular receptors for specific targeting of non-viral vectors to a specific cell type such as liver, neuronal tissue or erythropoietic tissues, can be incorporated. Alternatively specific antibodies recognizing specific cellular surface antigens can be used for targeting. Thirdly, carbohydrates on the liposomal membrane can be used for liver uptake of chimeric oligonucleotides.  
     [0327] The formulated chimeric oligonucleotide (HemeBiotech 595 W/X) will be administered by sc. or IV. injections to AIP patients.  
     [0328] The efficacy of the treatment can be evaluated as above.  
     [0329] Gene Therapy as an Alternative Treatment of Other Porphyric Diseases  
     [0330] The gene therapy strategies outlined herein can also be used for other Porphric diseases. The general principle is to increase the cellular or systemic content of a particular defective enzyme causing the disease. The following Porphyric diseases can be encompassed by this strategy:  
     [0331] 1. ALA deficiency  porphyria  (ADP)  
     [0332] 2.  Porphyria cutanea  tarda (PCT)  
     [0333] 3.  Hereditary coproporphyria  (HCP)  
     [0334] 4. Harderoporphyria (HDP)  
     [0335] 5.  Variegata porphyria  (VP)  
     [0336] 6.  Congenital erythropoietic porphyria  (CEP)  
     [0337] 7.  Erythropoietic protoporphyria  (EPP)  
     [0338] 8.  Hepatoerythropoietic porphyria  (HEP)  
     [0339] In the following Examples, preferred embodiments of the invention is disclosed relating to rhPBGD  
     EXAMPLE 1  
     [0340] Fermentation of Recombinant Human Porphobilinogen Deaminase (rhPBGD)  
     [0341] Strain PBGD-1 is an  E. coli  K12 host strain JM105 genotype endA thi rpsL sbcB15 hsdR4 Δ(lac-proAB) [F′traD36 proAB lacI q  Δ(lacZ)M15] containing the expression plasmid pExp1-M2-BB. Strain PBGD-2 has the same expression plasmid pExp1-M2-BB but the host cell is deleted for the hemc gene to facilitate rhPBGD purification. Since the strain PBGD-2 was not ready at the start of the study, the decision was made to start the study with strain PBGD-1. Both the strains are resistant against both tetracycline and ampicillin, but due to regulatory advantages it was decided to use oxytetracycline as selection pressure. To focus the first part of the study on the expression level of rhPBGD, and not the strain stability, it was decided to start the development with selection pressure in the fermenter. When the expression level was satisfactory strain stability without selection pressure in the fermenter should be investigated. Preliminary tests performed showed that the expression level of rhPBGD was 1,5 times higher at 37° C. compared to the expression at 30° C. At 42° C. it was as much as 3 times higher. Based on this knowledge one would suggest a temperature induction to either 37° C. or 42° C. during the fermentation to boost the rhPBGD production. However, at higher fermentation temperatures the strain stability might be a problem. The time frame was too narrow to study the rhPBGD expression at all three temperatures, so the decision was to start the study without temperature induction and to keep the temperature at 30° C. during the whole process.  
     [0342] Short Description of the Work  
     [0343] During the first two months the strain PBGD-1 was cultivated on agar plates and in shake flasks to obtain information about the strain characteristics. In parallel to this purchase of study dedicated chemicals, build up of the documentation system and technology transfer of the analytical methods took place. When the PBGD-1 intermediary cell bank was prepared the actual fermentation work started. First two “simple” 1-L batch fermentations of strain PBGD-1 were used to test the newly designed substrate and to calculate the maximum growth rate for the strain. After that three 10 L fed batch fermentations of strain PBGD-1 was performed.  
     [0344] As soon as the strain PBGD-2 was avaible and an intermediary cell bank was prepared, this strain was implemented in the fermentation procedure developed for strain PBGD-1. At present two 10-L fermentations of strain PBGD-2 have been performed.  
     [0345] The general outline of the fermentation is starting with inoculum preparation on M9-tc agar plates and shake flasks. The cells are incubated at 30° C. for 24 h on M9-tc agar plates and are then transferred to M9-tc shake flasks. The shake flasks are incubated for 12-14 h at 30° C. The broth from 1-2 shake flasks are used to inoculate the 10 L fermenter containing a minimal medium supplemented with yeast extract, trace elements, thiamine and oxytetracycline as selection pressure. The fermentation starts with a 14-h batch phase where the cells grow at maximum growth rate. The glucose feed is started after 14 h and the feed rate profile is varied between 25-75 ml/h of a 600 gl −1  glucose solution.  
     [0346] Broth taken from shake flasks and fermentations have been used to develop the down stream processing and to test and adjust the analytical methods provided. The general outline in the down stream processing is concentration of the fermentation broth on a 0,22 μm cross flow membrane followed by diafiltration (washing) with a buffer to exchange 90-95% of the substrate with buffer. The diafiltered cell concentrate is homogenised in a homogeniser, where the pressure has been varied between 600-1000 bars. The cell debris is then removed from the homogenate either by filtration on the same membrane as mentioned above or by centrifugation. Finally the extract is sterile filtered into sterile containers.  
     [0347] Results  
     [0348] Fermentation  
     [0349] The maximum growth rate for strain PBGD-1 was determined in shake flask experiments and in 1-L batch fermentations. The results are summarized in Table 5 below. The reason for the lower values in the shake flask with fermenter medium is probably acetic acid production and hence lower pH since the pH is not controlled. No experiments have been performed to calculate the maximum growth rate of strain PBGD-2, but from the fact that the batch phase has the same duration as for PBGD-1 we can draw the conclusion that the maximum growth rate is approximately the same.  
               TABLE 5                          Maximum growth rates                                 Maximum growth           Conditions   rate (μ max ) [h −1 ]                       M9-tc Shake flask   0.3           Shake flask with fermenter substrate   0.3           1 L Fermenter with pH controlled at 7.0   0.4                      
 
     [0350] The developed substrate for the fermentation is given in Table 6 on the next page. When implementing strain PBGD-2 it seems like this strain has different requirements on either the amount of yeast extract or the thiamine concentration in the substrate. When using the substrate developed for strain PBGD-1 the growth stops or lags during the fermentation (PD14). When adding extra yeast extract and thiamine the growth starts again. This pattern is repeated at least two times during the fermentation.  
               TABLE 6                          Fermenter substrate                             Component   Mw [g/mol]   Concentration   Unit                                     (NH 4 ) 2 SO 4     114.12   2.70   [g/l]       KH 2 PO 4     136.08   3.25   [g/l]       K 2 HPO 4  * 3H 2 O   228.23   2.80   [g/l]       C 6 H 5 Na 3 O 7  * 2H 2 O   258.07   0.60   [g/l]       Yeast extract       5.00-20.0   [g/l]       C 6 H 12 O 6  * H 2 O   198.17   10.00   [g/l]       MgSO 4  * 7H 2 O   246.50   1.07   [g/l]       Thiamine chloride       1.00-10.0   [mg/l]       C 12 H 18 Cl 2 N 4 OS * xH 2 O       H 3 BO 3     61.83   2.1   [mg/l]       CuSO 4  * 5H 2 O   249.70   10.5   [mg/l]       FeCl 3  * 6H 2 O   270.30   35.5   [mg/l]       MnSO 4  * H 2 O   169.02   6.6   [mg/l]       ZnSO 4  * 7H 2 O   287.50   5.3   [mg/l]       CoCl 2  * 6H 2 O   237.93   9.3   [mg/l]       CaCl 2  * 2H 2 O   147.02   14.0   [mg/l]       Na 2 MoO 4  * 2H 2 O   241.95   9.3   [mg/l]       HCl   34.46   6.9   [ml/l]       Oxytetracycline   496.90   6.0   [mg/l]       C 22 H 24 N 2 O 9  * HCl                  
 
     [0351] The strains seem to utilise different components in the yeast extract in a sequential order. The metabolism and respiration is different for different compounds. This gives rise to an irregular fermentation pattern with large changes in the respiration of the population during the fermentation, e.g. the CO 2  and the O 2  outlet gas analysis and the dissolved oxygen tension (DOT) signal (see FIG. 12).  
     [0352] As the fermentation proceeds, the fermentation broth is gradually coloured bright pink. When centrifuging broth for dry weight analysis it is observed that it is the actual cells and not the supernatant that is pink. The colonies on the M9-tc agar plates used to inoculate the shake flasks are not coloured pink, they are rather yellow or white like “normal”  E.coli  cells.  
     [0353] The colonies on the agar plates used for the colony forming units (CFU) analysis from the fermentation are also pink. However, on the CFU plates from PD14, the first fermentation with the new strain PBGD-2, a small portion of yellow or white colonies was observed. This observation was made already from the plates spread with broth from the inoculum shake flask. The percentage of yellow-white cells was varying in the range 2-8% during the fermentation. Both the white and red colonies were resistant against the antibiotic oxytetracycline. When observing the white and red colonies in the microscope they both appeared as  E.coli  rod like cells. It was hard to see any clear difference, but possibly the white cells were a little bit shorter than the red ones. To investigate this further shake flask cultivation were started with one red and one yellow colony. The CFU analysis showed that there were only red colonies from the shake flask inoculated with the red colony, but that the white colony gave rise to approximately 70% white and 30% red cells. The rhPBGD activity and protein concentration were measured in the broth from these shake flasks. The results are shown in Table 7 below. The difference in the protein concentration and the rhPBGD activity is in accordance with the difference in the OD 620  reached in the shake flask, probably due to different size of the inoculum colony.  
               TABLE 7                          rhPBGD activity and total protein from single colony shake flasks                                 Protein   PBGD activity   Specific activity       Start colony   [mg/ml broth]   [U/L broth]   [U/mg protein]               White   0.01    9   0.8       Red   0.04   27   0.7                  
 
     [0354] In the Table 8 below a summary of the final values of the fermentations are given. The lower OD 620  and Dw (dry weight) values in fermentation PD12 is a result of the lower amount of glucose that totally was fed into the fermenter in this fermentation (600 ml compared to approximately 850 ml in PD11 and PD14). It is also interesting to notice the very high expression and specific activity of rhPBGD in fermentation PD14 compared to the earlier fermentations.  
               TABLE 8                          Summary of final fermentation results                                                                 Specific                               PBGD                               activity               Time           PBGD activity   [U/mg       Batch   Strain   [h]   OD 620     Dw [g/l]   [U/ml broth]   protein]                                                 PD11   PBGD-1   27   82   29   7.7   2.6       PD12   PBGD-1   31   59   19   15.3   1.8       PD14   PBGD-2   30   87   32   39   3.1                  
 
     [0355] Until now we have achieved the best fermentation results in fermentation PD14. In the FIGS. 12 and 13 the fermentation results from this fermentation with the new strain PBGD-2 are shown. After a 14-h batch phase the glucose feed is started according to a schedule with three step changes in the feed rate. However after 16 h the glucose begins to accumulate in the fermenter due to that something else is limiting the growth more. The glucose feed is then stopped and restarted when the glucose concentration becomes limiting again.  
     [0356] The respiration pattern (i.e. CO 2 , O 2  and DOT signals) indicated that something in the substrate was depleted after 14,5 and 22,3 h and 26,3 h (see FIG. 12). When extra yeast extract and thiamine was added to the fermenter growth respiration increased dramatically for a while. There was a steady increase in the OD 620  and Dw during the whole fermentation and the final values are rather high. The increase in produced amount of rhPBGD correlates very well with the increase in biomass. This is something that has been observed also in the other fermentations. However, in fermentation PD14 there also seems to be a steady increase in the specific activity of the produced rhPBGD. Something that has been much less pronounced in the other fermentations.  
     [0357] Down Stream Processing  
     [0358] The different broths have been concentrated 1,9-6,9 times. The different values reflect problems with clogging of the membrane. This problem can probably be avoided by not concentrating the broth too much. Instead a somewhat longer diafiltration has to be done. The homogenisation has given a good yield of released enzyme compared to sonication. Removal of cell debris is in the laboratory scale rather easily done by centrifugation. For the production scale it would be preferred to use membrane filtration and because of that filtration has been tested. However, so far the transmission of enzyme through the membrane has been low resulting in low yields. This yield may be improved by better controlled filtration parameters or extended diafiltration. Otherwise a separator could be used in the production.  
     [0359] In Table 9 some data from the down stream processing are shown.  
               TABLE 9                          Summary of down stream results                             Sterile filtered extract                                         Spec.               activ-   activity                                         Debris   protein   ity   U/mg   Yield from broth, %                                         Broth   removal by   mg/ml   U/ml   protein   protein   U                                                 PD11   Filtration   2.7   5.1   1.9   30-60 1)   35-45 1)       PD12   Centrifugation   31   84   2.7   79    120 2)       PD14   Centrifugation   32   92   2.9   85   67       PD14   Filtration   3.8   11   2.8   15   18                                  
 
     [0360] Conclusions  
     [0361] Strain PBGD-2 has a maximum growth rate of approximately 0,4 h −1  in the fermenter substrate. This is similar to the maximum growth rate of strain PBGD-1, however the substrate requirement seems to be different for strain PBGD-2. An increase of the initial yeast extract and thiamine concentration in the substrate to 20 gl −1  and 10 mgl −1  respectively supports growth to a biomass similar to those achieved with the old strain PBGD-1.  
     [0362] The general fermentation process outline is a 14 h batch phase followed by a 16 h feed phase were the glucose feed rate is increased in three steps.  
     [0363] The production of rhPBGD correlates very well with the biomass production and the specific activity of the rhPBGD also seems to increase during the fermentation. The best result so far with strain PBGD-2 is a rhPBGD concentration of 39 U/ml and a specific activity of 3,1 U/mg protein after 30-hour fermentation. The final dry weight and OD 620 was 32 gl −1  and 87 respectively. The plasmid stability is good during the fermentation when oxytetracycline is present as selection pressure.  
     EXAMPLE 2  
     [0364] Development of a Purification Process for Recombinant Human Porphobilinoqen Deaminase (rhPBGD)  
     [0365] Introduction  
     [0366] For the capture step a weak anion exchange (DEAE-Sepharose FF) matrix has been tested primarily, because this has been the most common initial step for purification of PBGD. The disadvantage with anion exchange is that endotoxins and DNA adsorb on this type of gel. There is a risk that these impurities are coeluted with rhPBGD. To use a cation exchange in this project is not possible, because pI for rhPBGD is too low. For that reason a hydrophobic gel has also been tested as a capture step.  
     [0367] Material and Methods  
     [0368] Cell Extract  
     [0369] Cell extract (PD12, see Example 1) was supplied frozen (8×50 ml) from Biogaia. After the initial thawing a precipitation was found in the sample. The extract was centrifuged and the next day a new precipitation was found. This means that the extract has to be centrifuged in connection to a chromatography experiment. The protein content in the extract (BCA) was estimated to 29 mg/ml and the enzyme activity was found to be 63 U/ml. The pH and conductivity were estimated to 7.0 and 6 mS/cm, respectively.  
     [0370] Ion-Exchange  
     [0371] A DEAE-Sepharose FF hitrap (1 ml) column was used. The gel was equilibrated with Tris-HCl 25 mM, pH 8.5. The pH of the extract was adjusted to pH 8.5 with NaOH 5 M and the sample volume applied on the gel was 1.4 or 2.0 ml. After the sample has been applied, the gel was washed with 15 column volumes with equilibration buffer. For the desorption of the gel the following KCl concentrations have been tested: 40,120, 150 and 300 mM. Finally, after every experiment the gel was cleaned with NaOH 1 M.  
     [0372] Hydrophobic Interaction Chromatography  
     [0373] A Butyl-Sepharose 4 FF hitrap (1 ml) column was used. The gel was equilibrated with potassium phosphate 1.0-1.3 M pH 7.5. To the extract, potassium phosphate (2.5 M) was added to an end concentration of 1.0-1.3 M and the sample volume applied on the gel was 2.0 ml. After the sample has been applied, the gel was washed with 15 column volumes with equilibration buffer. For the desorption of the gel 500 mM, 20 mM potassium phosphate and water were tested. Finally, after every experiment the gel was cleaned with NaOH 1 M.  
     [0374] Results  
     [0375] Ion-Exchange  
     [0376] In FIGS. 14 and 15 chromatograms from two DEAE runs are shown. In Table 10 the results from these runs are shown. The difference between these experiments are that peak b in the first run was desorbed with 120 mM KCl and 150 mM in the second. Further, in the first run less sample was applied and the gel was also desorbed with 300 mM KCl. The recovery was in the best experiment found to be 75% and the yield 47%.  
     [0377] To get this recovery and yield 300 mM KCl has to be used. The purity of rhPBGD in peak b (DEAE2 ) was estimated to 31% (RPC).  
     [0378] Hydrophobic Interaction Chromatography  
     [0379] In FIG. 16 a chromatogram from a Butyl run is shown. In Table 11 the result from the run is shown. In this experiment 1.3 M potassium phosphate was used and the desorption was done with water. Conductivity in peak b was found to be 60 mS/cm. The recovery was calculated to 78% and the yield 75%. In an investigation it was found that a precipitation was formed in the extract at a potassium phosphate concentration of 1.5 M. The purity of rhPBGD in peak b was estimated to 40% (RPC).  
     [0380] Comments and Conclusions  
     [0381] From the results of the experiments it can be seen that the mass balance in all experiments are not in balance. This seems to be valid for all analyses. The main reasons for this are probably insecurity of the analyses and that all proteins are not eluted from the gel. The first reason is confirmed by the enzyme activity that seems to be too high in the extract when high concentration of potassium phosphate is added. The second reason is confirmed by the elution peak with NaOH in ion-exchange experiments. This peak is not analyzed. For the hydrophobic matrix a cleaning with organic solution can be necessary.  
     [0382] The conclusion of the results so far is that the Butyl-Sepharose 4 FF seems to be the best alternative for the capture step. The main reason for that is the higher yield of rhPBGD. Another advantage to use Butyl-Sepharose 4 FF is the small peak after cleaning with NaOH 1M compared with the large peak in DEAE-Sepharose FF runs. This probably means that few impurities stick on Butyl matrix. On the other hand there is a risk that a precipitation is formed when adding potassium phosphate. A desalting before the next chromatography step can be necessary, caused by the high ion strength in the product peak.  
                   TABLE 10                          Ion-exchange                                             Applied   Peak a   Peak b   Peak c                                                                             BCA   A280   Act.   BCA   A280   Act.   BCA   A280   Act.   BCA   A280   Act.               mg   mg   U   mg   mg   U   mg   mg   U   mg   mg   U                                                                                 Exp.                                                                   DEAE1   37   166   76   10   122   21   5   6   29   9   11   7               DEAE2   42   229   129   17   143   56   10   14   25   —   —   —                  
 
     [0383]                   TABLE 11                          Hydrophobic interaction chromatography                                             Applied   Peak a   Peak b   Peak c                                                                             BCA   A280   Act.   BCA   A280   Act.   BCA   A280   Act.   BCA   A280   Act.               mg   mg   U   mg   mg   U   mg   mg   U   mg   mg   U                                                                     Exp.                                                                   Butyl   31   137   93   7   84   3   11   23   70   —   —   —                    
     EXAMPLE 3  
     [0384] Development of a Method for the Purification of Recombinant Human Porphobilinogen Deaminase with a “His-Tag” (rhPBGD-His)  
     [0385] Nature and Purpose of the Study  
     [0386] Many groups have reported in the literature on the purification of porphobilinogen deaminase from various sources including  E. coli  and Human erythrocytes (Anderson P. M. and R. J. Desnick, 1979, The Journal of Biological Chemistry 255(5): 1993-99, Awan S. J. et al. 1997, Biochemistry 36(30): 9273-82, Grandchamp B. et al. 1987, Eur.J.Biochem. 162(1): 105-10, Jordan P. M. 1994, Wiley, Chichester (Ciba Found Symp 180), p70-96, Jordan P. M. et al. 1988, Biochhem.J. 254:427-435, Lambert R. et al. Wiley, Chichester (Ciba Found Symp 180), p97-110, Louie G. V. et al. 1996, Proteins 25(1): 48-78, Maniatis T., E. F. Fritsch, J. Sambrook. Molecular Cloning (A laboratory Manual) Cold Spring Harbor Laboratory. 1982, Miyagi K. et al. 1979, Proc.Natl.Acad.Sci. 76(12):6172-76, Racich N. 1986, Nucleic Acids Research 14(15): 5955-67, Shoolingin-Jordan P. M. et al. 1997, Methods in Enzymology, 281:317-327). Most use a combination of ion exchange, hydrophobic interaction and size exclusion chromatography to obtain fairly pure protein preparations. With the engineering of 5 additional Histidine residues on the C-terminus of recombinant human porphobilinogen deaminase, rhPBGD we have a convenient “Tag” to help with purification. Histidine has an affinity to electropositive transition metals such as nickel, copper, zinc and cobalt. When a series of 6 or more electron-rich histidine residues are expressed on the end of a protein they can function as an anchor, firmly attaching the protein to a solid support coated with metal ions. Very thorough washing can be done without dislodging the bound moiety. Elution can be accomplished in one of two ways, either by decreasing the pH to protonate the imidizole nitrogen (pKa of 5.97) of histidine, or by including imidizole, a molecule identical to the histidine side chain, in the elution buffer which competitively dislodges the tagged protein off the support. The purpose of this study is to obtain pure rhPBGD-His for antibody production and for use as a standard in assays and protein purification.  
     [0387] Study Objectives  
     [0388] The objective of this study is to obtain 10 mg of highly pure active rhPBGD-His.  
     [0389] Study Plan  
     [0390] Plan Outline  
     [0391] 1. Optimize induction time for the expression system and lysis  
     [0392] 2. Purify 10 mg of rhPBGD-His for antibody production and standard  
     [0393] (2.1) 2 liter scale induction and lysis of strain  
     [0394] (2.2) DEAE ion exchange chromatography  
     [0395] (2.3) Immobilized metal affinity chromatography  
     [0396] 3. Characterization of rhPBGD-His  
     [0397] (3.1) SDS-PAGE  
     [0398] (3.2) Amino acid analysis  
     [0399] (3.3) Specific activity  
     [0400] (3.4) HPLC  
     [0401] (3.5) Mass spectrometry  
     [0402] (3.6) Amino terminal sequencing  
     [0403] Plan Body  
     [0404] 1. Expression of rhPBGD-His is regulated by the bacterial Taq promoter, a derivative of the lac promoter which is inducible with IPTG (See FIG. 17 for plasmid map). Different proteins are produced at different rates in  E. coli  upon induction. This necessitates the optimization of the time required for optimum rhPBGD-His yield upon induction. To accomplish this a culture in mid-log phase will be induced with an excess of IPTG and expression followed at timepoints with activity and protein concentration measurements. After induction the cells must be lysed to release rhPBGD-His. Of the options available, sonication is the best for this scale of purification. It is compatible with any buffer system and should not be damaging to the protein. To follow efficiency of lysis, absorbance at 600 nm will be measured after each cycle.  
     [0405] 2. For use as a standard and for antibody production at least 10 mg of rhPBGD-His will be purified.  
     [0406] (2.1) For protein purification a 2 liter flask culture of the strain producing rhPBGD-His is sufficient. The culture will be inoculated with a fresh over-night culture of cells and grown to mid log phase then induced with IPTG.  
     [0407] (2.2) Plans are to utilize a two step purification process. After lysis the debris will be removed by centrifugation and supernatant loaded onto a DEAE ion exchange column. This will remove the vast majority of contaminants from the lysate and leave a limited number of protein contaminants in the elution fractions containing rhPBGD-His. Protein will be loaded in a high pH and low ionic strength buffer to ensure binding of the weakly charged rhPBGD-His. Extensive washing will be used to remove material that is not firmly bound to the column. A very shallow step gradient of KCl will be used to elute rhPBGD-His. This should separate the different forms of rhPBGD-His with differing charge properties from each other. Separation of different charged forms of PBGD, by ion exchange chromatography, has been reported by others (Anderson P. M. and R. J. Desnick, 1979, The Journal of Biological Chemistry 255(5): 1993-99, Jordan P. M. et al. 1988, Biochhem.J. 254:427-435, Miyagi K. et al. 1979, Proc.Natl.Acad.Sci.USA 76(12):6172-76).  
     [0408] (2.3) The second chromatographic step planned is a column containing Talon fast flow immobilized cobalt metal affinity resin (Clontech). This makes use of the 6-residue histidine tract at the amino terminus of the recombinant protein. Initially, a metal chelating resin (Pharmacia) charged with nickel (Sigma) was tried for purification of rhPBGD-His but it was found to bind other proteins in the lysate as well which coeluted with rhPBGD-His. Although this cobalt resin has less binding affinity to His tagged proteins than nickel it retains the high binding capacity and is more discriminating which proteins to bind. This leads to elution from the metal with a lower concentration of imidizole or with higher pH and achieves a higher level of purity. The cobalt is also bound more tightly to the matrix by a tetradentate metal chelator, effectively eliminating the leaching of metal ions from the solid support during purification. The loss of reactive metal ions during elution is common problem with nickel based affinity columns (personal communications) which can lead to unwanted precipitation of purified proteins.  
     [0409] 3. rhPBGD-His will be characterized by the following methods:  
     [0410] (3.1) The first measure of protein purity will be by SDS-PAGE (polyacrylamide gel electrophoresis). This method will also give an indication of the molecular weight of the protein being produced.  
     [0411] (3.2) To determine the specific activity of rhPBGD-His in the preparation it is first necessary to accurately determine protein concentration in solution. Amino acid analysis will be used as an accurate method. The method also provides the amino acid composition of the protein. The concentration can be used to establish an extinction coefficient of rhPBGD-His.  
     [0412] (3.3) Activity of the enzyme is an important measure of correct structure of the enzyme. The proper structure, equivalent to that produced in humans, is essential for rhPBGD-His to be used as a therapeutic. Any deviation from the natural structure can cause activation of the patient&#39;s immune system. Historically, activity of porphobilinogen deaminase has been measured in one of two ways, either by the metabolism of porphobilinogen substrate or by the formation of preuroporphyrinogen product. In the reaction catalyzed by PBGD, porphobilinogen monomers are covalently attached one at a time starting from the free alpha position of the dipyrromethane cofactor. After four molecules are added the linear tetramer of PBG, preuroporphyrinogen, is spontaneously released by hydrolysis from the cofactor, regenerating the active holoenzyme with covalently attached cofactor for further reactions (See FIG. 18). After release the tetrapyrrole is circularized by the next enzyme of the heme pathway, uroporphyrinogen III synthase, forming uroporphyrinogen III, the central ring of heme and vitamin B12 in animals and chlorophyll in plants. The linear preuroporphyrinogen molecule can instead be oxidized to uroporphyrin with benzoquinone creating a molecule, which absorbs light at 405 nm. This is the basis for the activity assay used to measure PBGD activity  
     [0413] (3.4) The rhPBGD-His preparation will be further characterized by mass spectrometry, which will give an accurate measure of rhPBGD-His molecular weight and potentially identify molecular heterogeneity in the preparation. rhPBGD-His can exist with 1,2,3 and 4 substrate molecules bound to it. Each substrate molecule added to the holoenzyme will add roughly 209 daltons to the mass, which is detectable through mass spectrometry.  
     [0414] (3.5) Characterization by reversed phase HPLC will provide purity data.  
     [0415] (3.6) Amino terminal sequencing of rhPBGD-His will be used to ensure the correct amino terminus.  
     [0416] Materials and Methods  
     [0417] Induction and Lysis:  
     [0418] From a freshly streaked colony, a culture of pExp-2 in JM105 was grown for 13.5 hours in 100 ml LB (10 g/l bacto-tryptone, 5 g/l bacto-yeast extract, 10 g/l NaCl pH 7.0) +100 μg/ml ampicillin in a 500 ml baffled flask at 37° C. at 350 rpm. The optical density measured at 600 nm reached 1.6. This culture was used to inoculate 2 liters of terrific broth (12 g/l bacto-tryptone, 24 g/l bacto-yeast extract, 4ml/l glycerol, 2.31 g/l KH2PO4, 12.54 g/l K 2 HPO 4  (Maniatis T., E. F. Fritsch, J. Sambrook. Molecular Cloning (A laboratory Manual) Cold Spring Harbor Laboratory. 1982) with 100 μg/ml ampicillin and split into four 2 liter baffled flasks with 400 ml each and two 1 liter baffled flasks with 200 ml culture each. These were grown at 37° C. with 350 rpm in a New Brunswick Scientific Innova 4000 incubator. When reaching an optical density of 0.7 at 600 nm the Taq promoter was induced with 4 mM IPTG, causing rhPBGD-His protein to be made. Growth was followed by hourly readings of absorbance at 600 nm. After 9 hours the cultures were stopped by chilling to 0° C. after an absorbance of 1.93 was reached. The culture was centrifuged, 4×250 ml at a time, for 10 min at 4,000×g in a Beckman Avanti J251 centrifuge with a JLA-16.250 rotor. Supernatant was decanted and the remainder of the culture was added to the cell pellets and spun for an additional 10 min. The pellets were resuspended in 2 pools of 250 ml 50 mM Tris/HCl pH 8.5 (prechilled) each and stored for 8 hours on ice. Cells were centrifuged for 10 min at 4,000×g, liquid decanted and resulting pellets weighed in the bottles to determine the wet weights. Cells were then resuspended in 400 ml ice cold 50 mM Tris/HCl pH 8.5 and lysed by sonication with a Branson Sonifier 450 with ½ inch diameter stepped, tapped horn. Each round was for 30 seconds at maximal power with constant duty cycle in a Pyrex 150 ml glass beaker on ice. Lysate was mixed between cycles by either drawing into a 50 ml pipet a few times or by pouring between beakers on ice. Progress of lysis during sonication was ascertained by reading absorbance of the lysate at 600 nm. After six rounds of sonication for each of the 100 ml aliquots of cells, debris was removed by centrifuging at 16,000×g for 30 minutes at 4° C. Lysate was then pooled and vacuum filtered through a 0.22 μm Durapore membrane (Millipore) to remove any remaining particulate matter.  
     [0419] DEAE Sepharose Chromatography:  
     [0420] The first chromatographic step in purifying rhPBGD-His was by ion exchange chromatography on a DEAE Sepharose fast flow column (Pharmacia). A 2.5×50 cm Spectrum LC column with degassed resin was washed extensively with degassed 25 mM Tris/HCl pH 8.5 buffer. Filtered lysate (380 ml) was applied to the column at 5 ml/min. The column was then washed with 720 ml 25 mM Tris/HCl pH 8.5. Elution of bound rhPBGD-His was with a shallow step gradient of KCl from 50 to 120 mM in 10 mM increments in 25 mM Tris/HCl pH 8.5 and degassed. Volumes for each step varied from between 105 and 470 ml depending on the elution profile (see Table 12).  
                       TABLE 12                                      0 mM KCl                                                     50   60   70   80   90   100   110   120               720 ml   470   120   175   270   105   130   180   300                  
 
     [0421] Fractions were collected about every 50 ml. Absorbance at 280 nm was followed closely during elution. The next step was only applied after the absorbance had declined following a peak. BioRad&#39;s protein assay II in microtiter format was used per manufacturer&#39;s protocol to assay the amount of protein in each fraction. Coomassie stained 10% acrylamide Bis/Tris gels (Novex) were then prepared, with 5 μg protein in each lane, to characterize the purity of each peak.  
     [0422] Cobalt Affinity Chromatography:  
     [0423] The resin slurry was degassed prior to pouring into a 2.5×30 cm Spectrum LC column. It was then washed extensively with degassed 25 mM Tris/HCl pH 8.5/150 mM NaCl at a flow rate of 5 ml/min. The sodium chloride was included to decrease protein to protein ionic interactions and to reduce ion exchange effects with the column matrix itself. A relatively high pH of 8.5 was used to keep rhPBGD-His well above the pI, and therefore negatively charged, to maintain high solubility during the purification. Two consecutive rhPBGD-His affinity purifications were then run on the column. The first sample loaded was a sterile filtered pool of the entire first peak of eluate of activity from the DEAE sepharose column including fractions 9 through 12. The column was then washed with 2 liters of 25 mM Tris pH8.5/150 mM NaCl at 3 ml/min. To elute bound contaminants the column was then washed with 100 ml of 25 mM Tris pH8.5/150 mM NaCl/5 mM imidizole at 5 ml/min followed by 100 ml of 10 mM imidizole buffer solution. Elution of his tagged protein was with 25 mM Tris pH 8.5/150 mM NaCl/50 mM imidizole at 5 ml/min. A final elution with 100 mM imidizole was included to be certain all rhPBGD-His was eluted. To prepare the column for the second loading it was merely washed with ˜100 ml of 25 mM Tris pH8.5/150 mM NaCl. It was hoped that rhPBGD-His would displace the imidizole bound to the column (which turned out to be the case). The second loading of the column was with a sterile filtered pool with ˜900 ml of all remaining peaks of activity from the DEAE Sepharose column at a flow rate of 5 ml/min. The column was then washed with 2 liters of 25 mM Tris pH8.5/150 mM NaCl at 5 ml/min, followed by imidizole containing buffers as with the first run above.  
     [0424] Polyacrylamide Gel Electrophoresis: (SDS-PAGE)  
     [0425] Gel electrophoresis was with the Novex system with Nupage 10% Bis/Tris gels run at 125V for 2 hours with or without reducing agent. Staining was with 50% methanol/10% acetic acid/0.25% Coomassie brilliant blue R-250 for 2 to 4 hours. Destaining was in 30% methanol/10% acetic acid in a Bio-Rad gel destainer.  
     [0426] Amino Acid Analysis:  
     [0427] Amino acid analysis was performed by AAA Laboratory (6206 89 th  Avenue Southeast, Mercer Island, Wash. 98040). rhPBGD-His was hydrolyzed for 20 hours with 6N-HCl/0.05% mercaptoethanol/0.02% phenol at 11 5° C. Serine was increased by 10% and Threonine increased by 5% to compensate for destruction of the individual acids during hydrolysis. A Beckman 7300 Amino Acid Analyzer was used coupled with System Gold software. Analysis was performed by post-column derivitization with ninhydrin using the ion-exchange chromatographic methods developed by Moore and Stein.  
     [0428] PBGD Activity Assay:  
     [0429] We performed assays in 96 well microtiter format with validation in cuvets. Procedures were derived from published procedures (Awan S. J. et al. 1997, Biochemistry 36(30): 9273-82, Shoolingin-Jordan P. M. et al. 1997, Methods in Enzymology, 281:317-327). From 0.125 to 8 μg of purified rhPBGD-His protein per well have been used to determine enzymatic activity. Assay buffer is 50 mM Tris/HCl pH 8.2 with 1.0 mg/ml BSA (Sigma fraction 5) and 10 mM DTT. A Perkin Elmer 9700 PCR machine was used for thermal regulation, allowing for tight control of the temperature and reaction time. Assays have been started in two ways. One method was to start the reactions at 37° C. with prewarmed substrate in a PCR block. Strategic placement of pauses in a thermocycle program was used with beeping at defined intervals for both addition of the substrate and for stopping the reaction. An example cycle program is shown in Table 13 with reaction times varying from 10, 20, 40 and 60 minutes.  
     [0430] The reaction block is a 96 well block with tubes arranged in an 8×12 matrix. It is kept throughout at 37C. The reaction is initiated by adding PBG to eight tubes in the first row using an eight-channel pipettor. The addition is staggered so that each row receives PBG every 30 seconds. A ten second pause and beep interval is setup every 20 seconds to signal each addition at the end of the period. In this fashion all the 96 reactions are started which takes a total of six minutes. At the end of a further four-minute incubation, the first three rows are stopped in a staggered manner giving a total of a ten-minute incubation period. This procedure is repeated for the next three rows after an additional ten minutes amounting to a total of twenty-minute reaction time. This scheme is illustrated in Table 13.  
     [0431] The p@37 represents the 10-second beep period which is configured in the thermocyclor as a pause plus beep interval.  
                               TABLE 13                       start   stop   stop   stop   stop                  add   10   20   40   60       PBG   min   min   min   min                                                                      
 
     [0432] Reactions were stopped by acidification with HCl/p-benzoquinone solution. The final concentration of HCl used was 1 molar. Benzoquinone, which oxidizes the uroporphyrinogen to uroporphyrin, was used at a final concentration of 0.002% w/v (from 0.2% stock solution in methanol). At defined intervals the 150 μl samples were removed from the reaction tubes and added to 850 μl HCl/p-benzoquinone solution in wells of a 96 well×2 ml plate on ice. The second method of initiating the assay was to set up the reactions complete with substrate on ice then to transfer to the PCR block for incubation at 37° C. Following the reaction the block was brought to 4° C. to stop the reaction after which samples were removed and added to HCl/p-benzoquinone solution. For both methods the incubation was allowed to proceed for 20 minutes on ice and in the dark after the last addition of reaction solutions. Then the plate was centrifuged for 10 min at 3750 rpm in a swing out rotor in a GS-6KR centrifuge to pellet precipitated protein (mostly BSA). 250 μl was removed to a Corning 96 well assay plate. Absorbance was measured at 405 nm with a 605 nm reference wavelength in a BioTek FL-600 plate reader. Selected samples (normally the standard curve) were diluted 10× with 1 M HCl and read in a quartz cuvet in a Beckman DU640B spectrophotometer at 405.5 nm. A 605 nm reference wavelength was used to subtract out background absorbance. These measurements in cuvets produced a conversion factor from 1 cm pathlength reads to the plate data. Analysis was performed using the KC4 software included with the plate reader and with excel spreadsheets. An extinction coefficient of 548 M −1 cm −1  was used to quantitate the oxidized reaction product (Shoolingin-Jordan P. M. et al. 1997, Methods in Enzymology, 281:317-327).  
     [0433] HPLC:  
     [0434] HPLC analysis was performed at the University of Washington Mass Spectrometry Analysis Facility for HPLC. Samples were prepared free of salts for mass spectrometry analysis by HPLC on a C4 column and eluted with an increasing gradient of acetonitrile. The instrument used was an Applied Biosystems (ABI) 140A Solvent Delivery System with an ABI 785A Programmable Absorbance Detector.  
     [0435] Mass Spectrometry:  
     [0436] Mass spectrometric analysis was performed at the University of Washington Mass Spectrometry Analysis Facility. One tenth of the HPLC run within the main elution peak was diverted prior to the absorbance detector to a Perkin Elmer SCIEX API3 Biomolecular Mass Analyzer for elecro-spray mass spectrometry. Analysis was by HyperMass method on an average of 16 peaks (for Cobalt run #1 eluate).  
     [0437] Amino Terminal Sequencing  
     [0438] Amino terminal sequence analysis was performed at the University of Washington Mass Spectrometry Analysis Facility. An ABI 477A Protein Sequencer was used with an ABI 120A PTH Analyzer.  
     [0439] Results  
     [0440] Purification:  
     [0441] Induction and Lysis:  
     [0442] Growth of the 2-liter culture of bacteria slowed down after the first hour but growth still continued to 9 hrs (see Table 14).  
                       TABLE 14                                      start                                                         1 hr   2 hr   3 hr   4 hr   5 hr   6 hr   7 hr   8 hr   9 hr                                                                 0.699   1.300   1.521   1.607   1.660   1.732   1.797   1.841   1.890   1.927                  
 
     [0443] After about 3 hrs of induction cells tended to clump together with most turbidity settling out of the broth by gravity in about an hour. Final density of cells stayed low for growth in a rich media such as terrific broth but final weight of pellets was adequate. The total wet weight was 35.3 g, corresponding to 17.7 g/liter culture. Interestingly the cells were orange/pink probably due to various intermediates in the heme biosynthetic pathway. It is clear from the low growth rate and final densities achieved that cultures were limited by the amount of oxygen available.  
     [0444] Lysis by sonication was essentially complete after 5 cycles as seen by following absorbance readings (Table 15).  
                       TABLE 15                                      # rounds                                                     0   1   2   3   4   5   6   7                                                             OD600   30.33   20.15   12.90   9.43   6.14   3.86   3.31   2.99       % down   —   34   36   27   35   37   14   9.7                  
 
     [0445] It appears from the % decrease of optical density that for each of the first 5 rounds of sonication, about the same percentage of cells were lysed. After this the percentage of newly lysed cells dropped rapidly. For each of the first 4 rounds viscosity of the lysate was relatively high due to the presence of unfragmented genomic DNA but this decreased significantly after further rounds from shearing of the DNA into smaller fragments.  
     [0446] DEAE Sepharose:  
     [0447] Elution of proteins from the DEAE ion exchange column occurred in 4 distinct peaks as seen in the elution profile in FIG. 19 and by protein assay in Table 16. SDS-PAGE analysis of the eluted fractions shows that these peaks contain four separate peaks of rhPBGD-His eluted with the step gradient of KCl (FIG. 20). The first and major peak was eluted in fractions 9 through 13 with 50 to 70 mM KCl. As seen by gel analysis (see FIG. 20) purity was fairly good for a first step of the purification, especially in fractions 10 through 13. The second peak eluted in fractions 15 through 18 with 80 mM KCl. The major contaminant in this peak, in about equal molar proportions to desired product, was a protein running at about 5 kDa smaller than rhPBGD-His. The third peak in fractions 20 through 23 eluted with 90 to 100 mM KCl and had less visible contaminants than the second peak. The fourth and final peak eluted in fractions 26 through 29+ with 110 to 120 mM KCl. The fractions were split into 2 pools for further purification. The first pool, comprising the major peak of rhPBGD-His elution contained fractions 9 through 12. The second pool contained fractions 13 through 29 along with the next 50 ml of 120 mM KCl elution buffer. These two pools eluted by ion exchange contained 877 mg protein out of 3253 mg loaded, corresponding to a 3.7 fold decrease in total protein (See Table 16).  
     [0448] Cobalt Affinity:  
     [0449] From the first cobalt run the majority of rhPBGD-His eluted in a sharp peak with a volume of 30 ml upon addition of 50 mM imidizole (see Table 17 for protein assay and FIG. 22 for SDS-PAGE results). A final elution with 100 mM imidizole released no detectable protein absorbing at 280 nm. In the second cobalt run (FIG. 21) surprisingly, the first imidizole wash of 5 mM eluted a small uncolored peak of absorbance with a volume of about 50 ml. The second wash with 10 mM imidizole then eluted a larger and broader orange/pink colored peak of about 150 ml. Further elution with 50 mM imidizole yielded a large sharp uncolored peak of 23 ml.  
     [0450] Characterization:  
     [0451] Amino Acid Analysis:  
     [0452] Amino acid analysis of 3 of the fractions (Cobalt run #1 50 mM imidizole eluate (in duplicate,) Cobalt run #2 10 and 50 mM imidizole eluates) yielded conclusive data that rhPBGD-His was being purified. Results from the analysis allowed for a very accurate measure of protein concentration calculated from the concentration of individual amino acids (see Table 18).  
     [0453] Specific Activity:  
     [0454] Specific activity of the first 50 mM imidizole eluate of rhPBGD-His from the cobalt column turns out to be high at approximately 24 U/mg (Units are in μmol PBG consumed per mg protein in one hour). Activity of rhPBGD-His was found to be strongly dependent on pH with a sharp rise from 7.0 to 8.0 where it approached a plateau. The optimum was around pH 8.2. The optimum PBG substrate concentration was found to be around 1 mM. rhPBGD-His had activity with all concentrations of PBG, however with amounts less than 1 mM the reaction was limited by available substrate, decreasing both the Vmax and the linearity over time as substrate was depleted. It was not found to be necessary to decolorize remaining benzoquinone with sodium metabisulfite as used in a published assay (Shoolingin-Jordan P. M. et al. 1997, Methods in Enzymology, 281:317-327). Strangely enough if acidification and oxidation were done in a smaller total volume (240 μl vs 1 ml) as done by this research group then a highly colored product develops during the incubation on ice. This product must be decolorized with a saturated solution of sodium metabisulfite to obtain accurate reaction absorbances. There was no significant difference in enzymatic activity found as measured by these two variations of the method.  
     [0455] Generally assays have been set up with both time and enzyme concentration as variables. This allows for a more detailed analysis of the results with a built in validation. If activity is fairly linear from different timepoints at any enzyme concentration then it can be inferred that substrate is not limiting and that reaction measurements are valid over that range. If a measurement is taken at only one timepoint then there is no indication of whether the enzyme is still functioning at V-max.  
     [0456] Reaction volumes in 96 well format have been limited by the size of PCR tubes to 150 μ. Volumes from between 50 and 150 μl have been tried with a noticeable increase in linearity over time and with increasing enzyme amounts seen with the larger volumes. Additional increases in volume would make even more substrate available and dilute the protein further, thereby increasing the linearity over time and enzyme concentrations. However the increase in cost of the assay from PBG substrate would be substantial.  
     [0457] For routine analysis of similar protein preparations at similar concentrations it should be possible to standardize the assay and use far fewer data points and still obtain an accurate measure of PBGD activity. Optimally a standard curve of rhPBGD-His of known activity would be included to validate the results and to simplify analysis. Basically multiple variables including time would be internally controlled. With a four-parameter logistic curve of the standards one could use any time point and a wide range of sample concentrations to obtain accurate activity measurements. Single use aliquots of highly pure rhPBGD-His could be stored frozen for use as standards.  
     [0458] Mass Spectrometry:  
     [0459] Mass spectrometry of the 50 mM imidizole elution peaks from the two cobalt runs yielded molecular weights of:  
     [0460] 1 st  cobalt run eluate: 38,816.8, standard deviation=3.68  
     [0461] 2 nd  cobalt run eluate: 38,814.6, standard deviation=4.70  
     [0462] 1 st  cobalt eluate dialyzed for antibodies: 38,817.1, STD deviation=3.33  
     [0463] These weights correspond to the holoenzyme without any additional substrate molecules attached.  
     [0464] Evaluation and Conclusions  
     [0465] We found that with a simple two step purification process involving ion exchange and cobalt affinity chromatography we could achieve a yield of 173 mg/l rhPBGD-His with a purity of greater than 98% starting from a bacterial crude lysate. Each one of the enzyme intermediate complexes is stable and can be independently isolated (Anderson P. M. and R. J. Desnick, 1979, The Journal of Biological Chemistry 255(5): 1993-99, Jordan P. M. et al. 1988, Biochhem.J. 254:427-435, Miyagi K. et al. 1979, Proc.Natl.Acad.Sci.USA 76(12):6172-76). This may be a major contributing factor to the differential binding of different enzyme fractions to the DEAE ion exchange matrix. Due to the negative charges contributed by acetate and propionate side groups on the growing chain of porphobilinogen molecules it could be theorized that binding affinity to the ion exchange resin would be in the order; E&lt;ES&lt;ES2&lt;ES3. That would imply that the first peak could be the holoenzyme followed by the others in the same order of the reaction progression. The cobalt column also eluted rhPBGD-His in different fractions during the second run. It is strange that the elution profile from the second run was different from the first. It would be expected that all closely related proteins with a his-tag would bind to cobalt with the same affinity. This implies that either the His-tag is partially digested away or partially obscured due to protein conformational changes or charge interactions. The difference in elution characteristics may also be due to differences between the various enzyme-substrate intermediate complexes as hinted by the color difference in the 10 mM elution peak. From a report in the literature by Jordan P. M. 1994, Wiley, Chichester (Ciba Found Symp 180), p70-96, the ES2 intermediate complex has a pink colored chromophore. The 10 mM imidizole fraction from the second cobalt column run has a pink color while the other fractions do not. This implies a separation of different enzyme substrate intermediates in different fractions. If the colored protein peak is predominantly composed of the ES2 intermediate then it could be extrapolated that the peak at 5 mM would be ES3. Whatever would be decreasing the binding of ES2 to cobalt whether conformational or charge related as compared to ES would likely be enhanced with the ES3 intermediate. The peak released with 50 mM imidizole and with stronger binding to DEAE could then be the ES form. Holoenzyme by itself may be the remaining form, purified during the first cobalt run, binding less tightly to DEAE due to a higher μl and elute from nickel with 50 mM imidizole. When the mass of the two 50 mM cobalt eluates were compared however there was no significant difference detected. Both corresponded to the weight expected for holoenzyme alone. Unfortunately no reliable mass measurement of the 10 mM eluate was obtained due possibly to precipitation problems with a lower rhPBGD-His protein concentration. If a difference of elution characteristics between the different enzyme substrate intermediates is occurring then a likely explanation would be due to the large conformational changes that take place during the course of the reactions From E to ES4 (Jordan P. M. 1994, Wiley, Chichester (Ciba Found Symp 180), p70-96, Louie G. V. et al. 1996, Proteins 25(1): 48-78). The C-terminal His-tag on the third domain of the protein could become partially hidden and rendered sterically less accessible when the reaction proceeds past the ES1 form. A direct interaction between the his-tag and the growing substrate chain would be less likely. At a pH of 8.5 histidines should be in an electron rich unprotonated state and the substrate complex should also be in an electron rich state even though acidic side chains are neutralized by basic amino acids in the catalytic cleft (Jordan P. M. 1994, Wiley, Chichester (Ciba Found Symp 180), p70-96, Louie G. V. et al. 1996, Proteins 25(1): 48-78). Conformational changes in rhPBGD-His occurring during the reaction could conceivably make accessible other charge groups for interaction with the his-tag either on the surface or perhaps the same ones meant for dampening charges from the growing substrate polymer in the cleft.  
     [0466] Equipment and supplies lists are shown in appendix 4 and 5, respectively.  
               TABLE 16                          Protein assay results on DEAE fractions (with BioRad&#39;s Protein assay II kit):                                     protein   rhPBGD-His       protein                                                     sample   vol(ml)   mM KCl   mg/ml   mg/ml   mg prot   gel #   well #   pool   mg pool                                                             DEAE Load   380   0   8.56       3253   1   2               DEAE FT   380   0   1.33       505   1   3       DEAE #1   16   0   0.26   0.00   4   1   4        2   60   0   0.23   0.00   14   1   5        3   100   0   0.044   0.00   4   1   6        4   215   0   0.002   0.00   0   1   7        5   320   0   0.005   0.00   2   1   8        6   75   50   0.11   0.00   8   1   9        7   100   50   0.19   0.00   19   1   10        8   100   50   0.14   0.00   14   1   11        9   94   50   0.61   0.31   57   1   12   1   334       10   100   50   1.44   1.15   144   2   1   1   I       11   38   60   1.05   0.84   40   2   2   1   I       12   135   60-70   0.69   0.48   93   2   3   1   V       13   100   70   0.4   0.10   40   2   4   2   543       14   50   80   0.43   0.09   22   2   5   2   I       15   50   80   0.96   0.34   48   2   6   2   I       16   50   80   0.98   0.49   49   2   7   2   I       17   50   80   0.57   0.29   29   2   8   2   I       18   50   80-90   0.48   0.14   24   2   9   2   I       19   50   90   0.42   0.13   21   2   10   2   I       20   50   90   0.61   0.24   31   3   1   2   I       21   50    90-100   0.93   0.70   47   3   2   2   I       22   50   100   1.08   0.86   54   3   3   2   I       23   50   100   0.57   0.34   29   3   4   2   I       24   50   110   0.41   0.08   21   3   5   2   I       25   50   110   0.61   0.09   31   3   6   2   I       26   50   110   0.69   0.17   35   3   7   2   I       27   50   110-120   0.73   0.44   37   3   8   2   I       28   28   120   1.07   0.86   30   3   9   2   I       29   50   120   1.08   0.76   54   3   10   2   V                  
 
     [0467]               TABLE 17                          Second cobalt run fractions with other samples in FIG. 20 gel                                         Sample   Imidizole   volume   Conc.   Total   Gel   Ico-pure       description   mM   ml   mg/ml   mg   lane   mg                                                 Co-1 load   0   367   0.78   286.3   2           Co-1 FT   0   367   0.22   80.7   3       Co-1 Eluate   50   30   6.46   193.8   4   193.8       MI #1 Nickel   500 ?       9.65       5       PBGD-1 Lys   0       1.73       6       Ab prep #1   0   3.3   4.00   13.2   7       Cobalt-2 FT   0   900   0.23   207.0   8       FT tail   0   30   0.02   0.6   —       Cobalt-2 w1   5   100   0.01   1.0   —       Cobalt-2 w2   5   50   0.14   7.0   —       Cobalt-2 w3   5   52   0.02   1.0   —       Cobalt-2 w4   5   100   0.04   4.0   —       Cobalt-2 w5   10   50   0.07   3.5   —       Cobalt-2 w6   10   50   0.81   40.5   9   101.5       Cobalt-2 w7   10   50   0.81   40.5   10       Cobalt-2 w8   10   50   0.41   20.5   11       Cobalt-2 w9   10   130   0.20   26.0   —       Cobalt-2 E1   50   22.5   2.29   51.5   12   51.5       Cobalt-2 E2   50   30   0.11   3.3   —                         Total mg highly pure rhPBGD-His (by amino acid analysis) =   346.8                    
     [0468]               TABLE 18                       rhPBGD-His amino acid analysis:                                            Cobalt eluates                                     #1   #2   #3   #4                         umol/ml                                                         aa   #aa   % whole   aa   [PBGD]   aa   [PBGD]   aa   [PBGD]   aa   [PBGD]               Ala   29   8.31   4.8220   0.166   0.5920   0.020   1.6950   0.058   4.5406   0.157       Arg   21   6.02   3.7279   0.178   0.4550   0.022   1.3050   0.062   3.5129   0.167       Asn   10   2.87       Asp   19   5.44   4.7157   0.163   0.5755   0.020   1.6510   0.056   4.4442   0.153       Cys   4   1.15       Gln   19   5.44       Glu   21   6.02   6.7648   0.169   0.8152   0.020   2.3592   0.059   6.3524   0.159       Gly   27   7.74   4.3933   0.163   0.6120   0.023   1.5595   0.058   4.1137   0.152       His   18   5.16   2.5664   0.143   0.2539   0.014   0.7947   0.044   2.4518   0.136       Ile   20   5.73   3.0511   0.153   0.3661   0.018   1.0561   0.053   2.8381   0.142       Leu   43   12.32   7.0235   0.163   0.8565   0.020   2.4506   0.057   6.6020   0.154       Lys   18   5.16   2.9241   0.162   0.3538   0.020   1.0427   0.058   2.7135   0.151       Met   6   1.72   0.8691   0.145   0.0996   0.017   0.3072   0.051   0.8252   0.138       Phe   9   2.58   1.4713   0.163   0.1825   0.020   0.5216   0.058   1.4045   0.156       Pro   16   4.58   2.7268   0.170   0.3708   0.023   1.1194   0.070   2.8441   0.178       Ser   18   5.16   2.8356   0.158   0.3570   0.020   1.0121   0.056   2.8680   0.159       Thr   20   5.73   3.4426   0.172   0.4272   0.021   1.2154   0.061   3.2746   0.164       Trp   2   0.57       Tyr   3   0.86   0.5150   0.172   0.0626   0.021   0.1734   0.058   0.4823   0.161       Val   26   7.45   4.0526   0.156   0.4920   0.019   1.4292   0.055   3.7740   0.145                                             Avg μmol/mol rhPBGD-His:   0.167       0.021       0.059       0.159       (w/o bold values)       Avg mg/ml rhPBGD-His:   6.46   0.81   2.29   6.17       (MW = 38759.4)       Volume (ml):   30   100   22.5   5       amount in fraction (mg):   193.7   80.8   51.6   30.8                                     sample   run #   imidazole   Notes               #1   1   50 mM   Major peak of cobalt eluate (from 50-&gt;60 mM                   KCl elution from DEAE)       #2   2   10 mM   70-&gt;120 mM KCl elution from DEAE; cobalt fractions W-6,7       #3   2   50 mM   70-&gt;120 mM KCl elution from DEAE; fraction E-1       #4   1   —   #1 dialyzed-&gt;PBS + 5 mM Tris/Cl pH 8.0 (used for 2nd round                   Antibodies)                                     Analysis done at:   AAA Laboratory           By:   Lowell Ericsson, Nancy Ericsson           Address:   6206 89th Ave SE, Mercer Island, Washington 98040-4599                        
     [0469] Combination Therapy  
     [0470] Combination Therapy of rhALAD AND rhPBGD  
     [0471] The etiology behind AIP is not fully understood. However, the accumulation of the two heme-precursors delta-aminolevulinic acid (ALA) and porphobilinogen (PBG) are likely to be involved. ALA and PBG have been suggested to be toxic to the central and peripheral nervous system causing the well known symptoms such as abdominal pain, muscle weakness, loss of sensory functions as well as epileptic seizures, respiratory paralysis, hallucinations and psychosis, observed during acute attacks.  
     [0472] The rationale for the enzyme substitution therapy in AIP patients is based on the administration of rhPBGD by sc. injections to lower serum and intracellular PBG levels. PBG will be metabolized to preurophorphyrinogen. Preuroporphyrinogen will subsequently enter the normal heme biosynthetic pathway and be metabolized to heme. Hence, rhPBGD enzyme replacement therapy will have a dual action, i) reduce circulating levels of toxic PBG and ii) restore heme production.  
     [0473] In the etiology of the disease it has always been suggested that ALA might have an even more toxic effect that PBG. Hence, a reduction of both ALA and PBG is important to achieve. Treatment of AIP patients with rhPBGD will i) reduce circulating levels of PBG as well as ALA, since ALA and PBG are in equilibrium with each other through coupled enzyme reactions e.g. deta-aminolevulinic acid dehydratase (ALAD) and porphobilinogen deaminase PBGD and ii) restore heme production. A block in the PBGD enzyme will result in the accumulation of both PBG and ALA. Administration of rhPBGD will quickly metabolise PBG and lower ALA levels as well, through changes in the equilibrium of the ALAD enzyme reaction.  
     [0474] An accelerated reduction of ALA might be beneficial to AIP patients. Hence, a coadministration of both rhPBGD and rhALAD will rapidly reduce both heme precursors. The mixing and administration of rhALAD and rhPBGD could be done in two ways, either: i) a product containing both enzymes at fixed proportions or ii) administration of rhPBGD and rhALAD by two separate subcutaneous injections. In the latter case the dose of the two enzymes could be adjusted to obtain optimal individual therapy. Administration of separate enzymes provides also a possibility for optimal temporal order of administration to obtain the best individual therapeutic effect.  
     [0475] Combination Therapy of rhPBGD and rhuroporphyrinogen III cosynthetase  
     [0476] Coadministration of rhPBGD and rhuroporphyrinogen III cosynthetase to some AIP patients are likely to be beneficial, by improving conversion of preuroporphyrinogen to its uroporphyrinogen III isomer rather than the I isomer. The I isomer forms spontaneously from preuroporphyrinogen and can not be further metabolised into heme. Hence, a coadministration of rhPBGD and Uroporphyrinogen III cosynthetase will ensure a better restoration of normal heme synthesis in that less amount of the uroporphyrinogen I isomer will be formed.  
     [0477] Combination Therapy of rhALAD, rhPBGD and rhUroporphyrinoqenIIIcosynthetase  
     [0478] rhPBGDcosynthetase can be coadminstered with both rhPBGD and rhALAD to specific patients to obtain beneficial heme synthesis restoration.  
     [0479] It is within the scope of the present invention to extend a combination therapy to other enzymes mentioned herein and to treatment of the other porphyias.  
     [0480] Treatment of other Porphyrias  
     [0481] In analogy with the new treatment of AIP patients with (recombinant) PBGD, hepatic Porphyrias such as ALA deficiency Porphyria (ADP),  Porphyria cutanea  tarda (PCT), Hereditary Coproporphyria (HCP) and  Variegata Porphyria  (VP) can benefit from substitution therapy by rhALA dehydratase, rhUroporphyrinogen decarboxylase, rhCoproporphyrinogen oxidase and rhProtoporphyrinogen oxidase, respectively.  
     [0482] Patients having  Erythropoetic Porphyrias  such as Congenital  erythropoietic  Porphyria (CEP) or  Erythropoietic protoporphyria  (EPP) will benefit from substitution therapy with rhUroporphyrinogen III synthetase and rhFerrochelatase, respectively.  
     [0483] Hepatoerythropoietic Porphyrias e.g.  Hepatoerythropoietic Porphyrias  (HEP) can be treated with rhUroporphyrinogen decarboxylase.  
     [0484] All  porphyrias  can be treated by the administration of the enzymatic activity lacking or being reduced (normally 50%) in any of the eight steps in the heme biosynthetic pathway as described above.  
     [0485] The substitution of the enzymatic activity can be achieved by adding the corresponding recombinant enzyme or other molecules that will provide the missing enzymatic activity. In situations where a combination of enzymes are beneficial, such therapy may be applied in a manner similar as disclosed above.  
     [0486] References:  
     [0487] Anderson P. M. and R. J. Desnick. 1979, Purification and Properties of Uroporphyrinogen I Synthase from Human Erythrocytes: Identification of Stable Enzyme-Substrate Intermediates The Journal of Biological Chemistry 255(5) :1993-99  
     [0488] Andersson, Christer, Thesis, 1997, ISBN 91/7191/280/0, pp. 22-23  
     [0489] Amann, E., Brosius, J., and Ptashne, M. 1983, Vectors bearing a hybrid trp-lac promoter useful for regulated expression of cloned genes in  Escherichia coli. Gene  25(2-3):167-178  
     [0490] Awan S. J. et al. 1997, Reconstitution of the Holoenzyme Form of  E. coli  Porphobilinogen Deaminase from Apoenzyme with Porphobilinogen and Preuroporphyrinogen: A Study Using Circular Dichroism Spectroscopy Biochemistry 36 (30) :9273-82  
     [0491] Gold, L. and Stormo, G. D. 1990, High-level translation initiation.  Methods Enzymol.  185:89-93:89-93  
     [0492] Grandchamp B. et al. 1987, Tissue-specific expression of porphobilinogen deaminase. Two isoenzymes from a single gene. Eur J Biochem. Jan;162(1):105-10  
     [0493] Grandschamp B. et al. 1996, J. of Gastroenerology and Hepatology 11,1046-1052  
     [0494] Herrick A. L. et al. 1989, Lancet 1,1295-1297  
     [0495] Jeans J. et al. 1996, American J. of Medical Genetics, 65, 269-273  
     [0496] Jordan P. M., S. D. Thomas and M. J. Warren. 1988, Purification, crystallization and properties of porphobilinogen deaminase from a recombinant strain of  Escherichia coli  K12. Biochem. J. 254: 427-435  
     [0497] Jordan, P. M. The biosynthesis of uroporphyrinogen III: mechanism of action of porphobilinogen deaminase. In: The biosynthesis of the tetrapyrrole pigments 1994 Wiley, Chister (Ciba Found Symp 180), p70-96  
     [0498] Lambert R. et al. 1994, Structural studies on porphobilinogen deaminase. In: The biosynthesis of the tetrapyrrole pigments. Wiley, Chichester (Ciba Found Symp 180), p97-110  
     [0499] Lewis, L. A., Li, K. B., Gousse, A., Pereira, F., Pacheco, N., Pierre, S., Kodaman, P., and Lawson, S. 1991, Genetic and molecular analysis of spontaneous respiratory deficient (res-) mutants of  Escherichia coli  K-12.  MicrobioLlmmunol.  35(4):289-301  
     [0500] Lithner F. et al. 1984, Acta.Med.Scand. 215, 271-274  
     [0501] Louie, G. V. et al. 1996, The three-dimensional structure of  Escherichia coli  porphobilinogen deaminase at 1.76-A resolution Proteins 25(1):48-78  
     [0502] Makrides, S. C. 1996, Strategies for achieving high-level expression of genes in  Escherichia coli. Microbiol.Rev.  60(3):512-538  
     [0503] Maniatis T., E. F. Fritsch, J. Sambrook. Molecular Cloning (A laboratory Manual) Cold Spring Harbor Laboratory. 1982  
     [0504] Miller et al. 1989, BioTechniques 7, 980-990  
     [0505] Miyagi K. et al. 1979, Uroporphyrinogen I synthase from human erythrocytes: Separation, purification, and properties of isoenzymes. Proc. Natl. Acad. Sci. 76:12 6172-76  
     [0506] Morrison D. A. 1979, Transformation and preservation of competent bacterial cells by freezing.  Methods Enzymol.  68, 326-331.  
     [0507] Mustajoki et al. 1989, Sem. Hematol. 26, 1-9  
     [0508] Raich N. et al. 1986, Molecular cloning and complete primary sequence of erythrocyte porphobilinogen deaminase. Nucleic Acids Research 14(15): 5955-67  
     [0509] Raich N. et al. 1986, Nucleic. Acid. Res, 14, 5955-5968  
     [0510] Saiki R. K. et al. 1985, Enzymatic amplification of beta-globin genomic sequences and restriction site analysis for diagnosis of sickle cell anemia. Science, 20;230(4732):1350-4.  
     [0511] Sassa S. 1996, Blood Review, 10, 53-58  
     [0512] Shoolingin-Jordan P. M., M. J. Warren and S. J. Awan, 1997, Dipyrromethane Cofactor Assembly of Porphobilinogen Deaminase: Formation of Apoenzyme and Preparation of Holoenzyme. Methods in Enzymology 281: 317-327  
     [0513] Stephens P. E. et. al. Biochem J. 248,1-11,1987  
     [0514] Strand et al. 1970, Proc. NatI. Acad. Sci. 67,1315-1320  
     [0515] Tishler P. V. et al. 1985, Am.J.Psychiatry 142,1430-1436  
     [0516] Waldenstrom J. 1937, Acta.Med. Scand. Suppl.82  
     [0517] Welland F. H. et al. 1964, Metabolism, 13, 232  
     [0518] Wetterberg L. 1967, Svenska bökforlaget Nordstedt, Stockholm  
     [0519] Wetterberg L. 1976, In Doss M. Nowrocki P. eds.  Porphyrias  in Human Disease. Reports of the discussion. Matgurg an der Lahn, 191-202  
     [0520] Yeung L. et al. 1983, Q J. Med 52, 92-98  
     [0521] Yoo H. W. et al. 1993, Hydroxymethylbilane synthase: complete genomic sequence and amplifiable polymorphisms in the human gene. Genomics Jan; 15(1):21-9 
 
 
 
 
 
 
 
 
 
    
     
       
         1 
         
           
             40  
           
           
             1  
             5446  
             DNA  
             Artificial Sequence  
             
               Sequence of the expression plasmid pExp1-M2-BB  
             
           
            1 

gaattctaac ataagttaag gaggaaaaaa aaatgagagt tattcgtgtc ggtacccgca     60 

agagccagct tgctcgcata cagacggaca gtgtggtggc aacattgaaa gcctcgtacc    120 

ctggcctgca gtttgaaatc attgctatgt ccaccacagg ggacaagatt cttgatactg    180 

cactctctaa gattggagag aaaagcctgt ttaccaagga gcttgaacat gccctggaga    240 

agaatgaagt ggacctggtt gttcactcct tgaaggacct gcccactgtg cttcctcctg    300 

gcttcaccat cggagccatc tgcaagcggg aaaaccctca tgatgctgtt gtctttcacc    360 

caaaatttgt tgggaagacc ctagaaaccc tgccagagaa gagtgtggtg ggaaccagct    420 

ccctgcgaag agcagcccag ctgcagagaa agttcccgca tctggagttc aggagtattc    480 

ggggaaacct caacacccgg cttcggaagc tggacgagca gcaggagttc agtgccatca    540 

tcctggcaac agctggcctg cagcgcatgg gctggcacaa ccgggttggg cagatcctgc    600 

accctgagga atgcatgtat gctgtgggcc agggggcctt gggcgtggaa gtgcgagcca    660 

aggaccagga catcttggat ctggtgggtg tgctgcacga tcccgagact ctgcttcgct    720 

gcatcgctga aagggccttc ctgaggcacc tggaaggagg ctgcagtgtg ccagtagccg    780 

tgcatacagc tatgaaggat gggcaactgt acctgactgg aggagtctgg agtctagacg    840 

gctcagatag catacaagag accatgcagg ctaccatcca tgtccctgcc cagcatgaag    900 

atggccctga ggatgaccca cagttggtag gcatcactgc tcgtaacatt ccacgagggc    960 

cccagttggc tgcccagaac ttgggcatca gcctggccaa cttgttgctg agcaaaggag   1020 

ccaaaaacat cctggatgtt gcacggcaat tgaacgatgc ccattaataa gcttggctgt   1080 

tttggcggat gagagaagat tttcagcctg atacagatta aatcagaacg cagaagcggt   1140 

ctgataaaac agaatttgcc tggcggcagt agcgcggtgg tcccacctga ccccatgccg   1200 

aactcagaag tgaaacgccg tagcgccgat ggtagtgtgg ggtctcccca tgcgagagta   1260 

gggaactgcc aggcatcaaa taaaacgaaa ggctcagtcg aaagactggg cctttcgttt   1320 

tatctgttgt ttgtcggtga acgctctcct gagtaggaca aatccgccgg gagcggattt   1380 

gaacgttgcg aagcaacggc ccggagggtg gcgggcagga cgcccgccat aaactgccag   1440 

gcatcaaatt aagcagaagg ccatcctgac ggatggcctt tttgcgtttc tacaaactct   1500 

tttgtttatt tttctaaata cattcaaata tgtatccgct catgagacaa taaccctgat   1560 

aaatgcttca ataatattga aaaaggaaga gtatgagtat tcaacatttc cgtgtcgccc   1620 

ttattccctt ttttgcggca ttttgccttc ctgtttttgc tcacccagaa acgctggtga   1680 

aagtaaaaga tgctgaagat cagttgggtg cacgagtggg ttacatcgaa ctggatctca   1740 

acagcggtaa gatccttgag agttttcgcc ccgaagaacg ttttccaatg atgagcactt   1800 

ttaaagttct gctatgtggc gcggtattat cccgtgttga cgccgggcaa gagcaactcg   1860 

gtcgccgcat acactattct cagaatgact tggttgagta ctcaccagtc acagaaaagc   1920 

atcttacgga tggcatgaca gtaagagaat tatgcagtgc tgccataacc atgagtgata   1980 

acactgcggc caacttactt ctgacaacga tcggaggacc gaaggagcta accgcttttt   2040 

tgcacaacat gggggatcat gtaactcgcc ttgatcgttg ggaaccggag ctgaatgaag   2100 

ccataccaaa cgacgagcgt gacaccacga tgcctgtagc aatggcaaca acgttgcgca   2160 

aactattaac tggcgaacta cttactctag cttcccggca acaattaata gactggatgg   2220 

aggcggataa agttgcagga ccacttctgc gctcggccct tccggctggc tggtttattg   2280 

ctgataaatc tggagccggt gagcgtgggt ctcgcggtat cattgcagca ctggggccag   2340 

atggtaagcc ctcccgtatc gtagttatct acacgacggg gagtcaggca actatggatg   2400 

aacgaaatag acagatcgct gagataggtg cctcactgat taagcattgg taactgtcag   2460 

accaagttta ctcatatata ctttagattg atttaaaact tcatttttaa tttaaaagga   2520 

tctaggtgaa gatccttttt gataatctca tgaccaaaat cccttaacgt gagttttcgt   2580 

tccactgagc gtcagacccc gtagaaaaga tcaaaggatc ttcttgagat cctttttttc   2640 

tgcgcgtaat ctgctgcttg caaacaaaaa aaccaccgct accagcggtg gtttgtttgc   2700 

cggatcaaga gctaccaact ctttttccga aggtaactgg cttcagcaga gcgcagatac   2760 

caaatactgt ccttctagtg tagccgtagt taggccacca cttcaagaac tctgtagcac   2820 

cgcctacata cctcgctctg ctaatcctgt taccagtggc tgctgccagt ggcgataagt   2880 

cgtgtcttac cgggttggac tcaagacgat agttaccgga taaggcgcag cggtcgggct   2940 

gaacgggggg ttcgtgcaca cagcccagct tggagcgaac gacctacacc gaactgagat   3000 

acctacagcg tgagctatga gaaagcgcca cgcttcccga agggagaaag gcggacaggt   3060 

atccggtaag cggcagggtc ggaacaggag agcgcacgag ggagcttcca gggggaaacg   3120 

cctggtatct ttatagtcct gtcgggtttc gccacctctg acttgagcgt cgatttttgt   3180 

gatgctcgtc aggggggcgg agcctatgga aaaacgccag caacgcggcc tttttacggt   3240 

tcctggcctt ttgctggcct tttgctcaca tgttctttcc tgcgttatcc cctgattctg   3300 

tggataaccg tattaccgcc tttgagtgag ctgataccgc tcgccgcagc cgaacgaccg   3360 

agcgcagcga gtcagtgagc gaggaagcgg aagagcgcct gatgcggtat tttctcctta   3420 

cgcatctgtg cggtatttca caccgcatat ggtgcactct cagtacaatc tgctctgatg   3480 

ccgcatagtt aagccagtat acactccgct atcgctacag atccggaaca taatggtgca   3540 

gggcgctgac ttccgcgttt ccagacttta cgaaacacgg aaaccgaaga ccattcatgt   3600 

tgttgctcag gtcgcagacg ttttgcagca gcagtcgctt cacgttcgct cgcgtatcgg   3660 

tgattcattc tgctaaccag taaggcaacc ccgccagcct agccgggtcc tcaacgacag   3720 

gagcacgatc atgcgcaccc gtggccagga cccaacgctg cccgagatgc gccgcgtgcg   3780 

gctgctggag atggcggacg cgatggatat gttctgccaa gggttggttt gcgcattcac   3840 

agttctccgc aagaattgat tggctccaat tcttggagtg gtgaatccgt tagcgaggtg   3900 

ccgccggctt ccattcaggt cgaggtggcc cggctccatg caccgcgacg caacgcgggg   3960 

aggcagacaa ggtatagggc ggcgcctaca atccatgcca acccgttcca tgtgctcgcc   4020 

gaggcggcat aaatcgccgt gacgatcagc ggtccagtga tcgaagttag gctggtaaga   4080 

gccgcgagcg atccttgaag ctgtccctga tggtcgtcat ctacctgcct ggacagcatg   4140 

gcctgcaacg cgggcatccc gatgccgccg gaagcgagaa gaatcataat ggggaaggcc   4200 

atccagcctc gcgtcgcgaa cgccagcaag acgtagccca gcgcgtcggc cgccatgccg   4260 

gcgataatgg cctgcttctc gccgaaacgt ttggtggcgg gaccagtgac gaaggcttga   4320 

gcgagggcgt gcaagattcc gaataccgca agcgacaggc cgatcatcgt cgcgctccag   4380 

cgaaagcggt cctcgccgaa aatgacccag agcgctgccg gcacctgtcc tacgagttgc   4440 

atgataaaga agacagtcat aagtgcggcg acgatagtca tgccccgcgc ccaccggaag   4500 

gagctgactg ggttgaaggc tctcaagggc atcggtcgac gctctccctt atgcgactcc   4560 

tgcattagga agcagcccag tagtaggttg aggccgttga gcaccgccgc cgcaaggaat   4620 

ggtgcatgca aggagatggc gcccaacagt cccccggcca cggggcctgc caccataccc   4680 

acgccgaaac aagcgctcat gagcccgaag tggcgagccc gatcttcccc atcggtgatg   4740 

tcggcgatat aggcgccagc aaccgcacct gtggcgccgg tgatgccggc cacgatgcgt   4800 

ccggcgtaga ggatccacag gacgggtgtg gtcgccatga tcgcgtagtc gatagtggct   4860 

ccaagtagcg aagcgagcag gactgggcgg cggccaaagc ggtcggacag tgctccgaga   4920 

acgggtgcgc atagaaattg catcaacgca tatagcgcta gcagcacgcc atagtgactg   4980 

gcgatgctgt cggaatggac gatatcccgc aagaggcccg gcagtaccgg cataaccaag   5040 

cctatgccta cagcatccag ggtgacggtg ccgaggatga cgatgagcgc attgttagat   5100 

ttcatacacg gtgcctgact gcgttagcaa tttaactgtg ataaactacc gcattaaagc   5160 

taatcgatga taagctgtca aacatgagtg atccgggctt atcgactgca cggtgcacca   5220 

atgcttctgg cgtcaggcag ccatcggaag ctgtggtatg gctgtgcagg tcgtaaatca   5280 

ctgcataatt cgtgtcgctc aaggcgcact cccgttctgg ataatgtttt ttgcgccgac   5340 

atcataacgg ttctggcaaa tattctgaaa tgagctgttg acaattaatc atcggctcgt   5400 

ataatgtgtg gaattgtgag cggataacaa tttcacacag gaaaca                  5446 

 
           
             2  
             3225  
             DNA  
             Artificial Sequence  
             
               Sequence of the EcoR I - Hind III linear 
      fragment used for transformation in the hemC disruption 
      strategy  
             
           
            2 

aattcgtcaa gcagcagtat atgctgggtg gagccacaat cttcgccccc caggctgccg     60 

ctttcattat gacggaagcg gttttcatca atcaggaaga agctgacttc cacacccagc    120 

gaggcggccc agttttccag caggctacat ttacgttgta gcaattggcg ctcttcgcta    180 

tcgagccagg attgatgaca gacccagata tccaggtcag aggaacaact ttgccctacg    240 

gacgaggtgc tgcccatggt gtatacacca gtaattggaa gctcaccttt cggcggatcc    300 

tgtactgaca ttccacgata cagttcaagc tcgttcaggt agtggcgttg agtttcatca    360 

ggcgtgtaaa ggcaaatgcc tttgggaacg ttaccatcaa ggtagcccgg cattagcgga    420 

tggtgatagt gcaacaatgt cggcagtaga ctgtagacct gttggaatgc aggccccata    480 

gcagcaagcg cgcgatccac acgcaattga tttatggcat ccagtctctg tttcagagtc    540 

tcaatataga ggtacaagac gtatcgcctg atttgctacc cgtcatgact gtgattccgc    600 

caacatcaac ggtaacacgc ggcattcggg atatttcgta tgtcaaaggt aaccgttacc    660 

acttttcgcg cctggttttt ttagtttcac gacgaaaaaa tggtctaaaa cgtgatcaat    720 

ttaacacctt gctgattgac cgtaaagaaa gatgcgctac atacaagtgt agcaccgttt    780 

attctctgta aattccttat tacaacggcg tgaaacgcct gtcaggatcc actgccagac    840 

ctcattttac ggtttgcgca ggcgtctacg tttcaccaca acactgacat cactctggca    900 

aggatgttag gatggaccac ggatgataat gacggtaaca agcatgttag acaatgtttt    960 

aagaattgcc acacgccaaa gcccacttgc actctggcag gcacactatg tcaaagacaa   1020 

gttgatggcg agccatccgg gcctggtcgt tgaactggta ccgatggtga cctcgagcgg   1080 

cacgtaagag gttccaactt tcaccataat gaaataagat cactaccggg cgtatttttt   1140 

gagttgtcga gattttcagg agctaaggaa gctaaaatgg agaaaaaaat cactggatat   1200 

accaccgttg atatatccca atggcatcgt aaagaacatt ttgaggcatt tcagtcagtt   1260 

gctcaatgta cctataacca gaccgttcag ctggatatta cggccttttt aaagaccgta   1320 

aagaaaaata agcacaagtt ttatccggcc tttattcaca ttcttgcccg cctgatgaat   1380 

gctcatccgg aattacgtat ggcaatgaaa gacggtgagc tggtgatatg ggatagtgtt   1440 

cacccttgtt acaccgtttt ccatgagcaa actgaaacgt tttcatcgct ctggagtgaa   1500 

taccacgacg atttccggca gtttctacac atatattcgc aagatgtggc gtgttacggt   1560 

gaaaacctgg cctatttccc taaagggttt attgagaata tgtttttcgt ctcagccaat   1620 

ccctgggtga gtttcaccag ttttgattta aacgtggcca atatggacaa cttcttcgcc   1680 

cccgttttca ccatgggcaa atattatacg caaggcgaca aggtgctgat gccgctggcg   1740 

attcaggttc atcatgccgt ttgtgatggc ttccatgtcg gcagaatgct taatgaatta   1800 

caacagtact gcgatgagtg gcagggcggg gcgtaattct cgagaccggc atgagtatcc   1860 

ttgtcacccg cccgtctccc gctggagaag agttagtgag ccgtctgcgc acactggggc   1920 

aggtggcctg gcattttccg ctgattgagt tttctccggg tcaacaatta ccgcaacttg   1980 

ctgatcaact ggcagcgctg ggggagagcg atctgttgtt tgccctctcg caacacgcgg   2040 

ttgcttttgc ccaatcacag ctgcatcagc aagatcgtaa atggccccga ctacctgatt   2100 

atttcgccat tggacgcacc accgcactgg cactacatac cgtaagtgga cagaagattc   2160 

tctacccgca ggatcgggaa atcagcgaag tcttgctaca attacctgaa ttacaaaata   2220 

ttgcgggcaa acgtgcgctg atattacgtg gcaatggtgg tcgtgagcta attggggata   2280 

ccctgacggc gcgcggtgct gaggtcactt tttgtgaatg ttatcaacga tgcgcaatcc   2340 

attacgatgg tgcagaagaa gcgatgcgct ggcaagcccg cgaggtgacg atggtcgttg   2400 

ttaccagcgg tgaaatgttg cagcaactct ggtcgctgat cccacaatgg tatcgtgagc   2460 

actggttact acactgtcga ctattggtcg tcagtgagcg tttggcgaaa ctcgcccggg   2520 

aactgggctg gcaagacatt aaggtcgccg ataacgctga caacgatgcg cttttacggg   2580 

cattacaata actctcataa caggaagcca taatgacgga acaagaaaaa acctccgccg   2640 

tggttgaaga gaccagggag gccgtggaca ccacgtcaca acctgtcgca acagaaaaaa   2700 

agagtaagaa caataccgca ttgattctca gcgcggtggc tatcgctatt gctctggcgg   2760 

cgggcatcgg tttgtatggc tggggtaaac aacaggccgt caatcagacc gccaccagcg   2820 

atgccctggc taaccaactg acggcattgc aaaaagccca ggagagccaa aaagccgagc   2880 

tggaaggcat tattaagcaa caagctgcac aacttaagca ggcgaatcgt cagcaagaaa   2940 

cgctggcaaa acagttggat gaagtccaac aaaaggtcgc caccatttcc ggcagcgatg   3000 

ctaaaacctg gctgctggct caggccgatt ttctggtgaa actcgccgga cggaagctgt   3060 

ggagcgatca ggacgtcacg accgctgcag cgttgctgaa aagtgcagac gccagcctgg   3120 

cggatatgaa tgacccgagt ctgattaccg ttcgtcgggc aattaccgat gatatcgcca   3180 

gcctttctgc agtatcgcag gtggattatg acggcatcat cctta                   3225 

 
           
             3  
             1035  
             DNA  
             Human tissue  
           
            3 

atgagagtga ttcgcgtggg tacccgcaag agccagcttg ctcgcataca gacggacagt     60 

gtggtggcaa cattgaaagc ctcgtaccct ggcctgcagt ttgaaatcat tgctatgtcc    120 

accacagggg acaagattct tgatactgca ctctctaaga ttggagagaa aagcctgttt    180 

accaaggagc ttgaacatgc cctggagaag aatgaagtgg acctggttgt tcactccttg    240 

aaggacctgc ccactgtgct tcctcctggc ttcaccatcg gagccatctg caagcgggaa    300 

aaccctcatg atgctgttgt ctttcaccca aaatttgttg ggaagaccct agaaaccctg    360 

ccagagaaga gtgtggtggg aaccagctcc ctgcgaagag cagcccagct gcagagaaag    420 

ttcccgcatc tggagttcag gagtattcgg ggaaacctca acacccggct tcggaagctg    480 

gacgagcagc aggagttcag tgccatcatc ctggcaacag ctggcctgca gcgcatgggc    540 

tggcacaacc gggttgggca gatcctgcac cctgaggaat gcatgtatgc tgtgggccag    600 

ggggccttgg gcgtggaagt gcgagccaag gaccaggaca tcttggatct ggtgggtgtg    660 

ctgcacgatc ccgagactct gcttcgctgc atcgctgaaa gggccttcct gaggcacctg    720 

gaaggaggct gcagtgtgcc agtagccgtg catacagcta tgaaggatgg gcaactgtac    780 

ctgactggag gagtctggag tctagacggc tcagatagca tacaagagac catgcaggct    840 

accatccatg tccctgccca gcatgaagat ggccctgagg atgacccaca gttggtaggc    900 

atcactgctc gtaacattcc acgagggccc cagttggctg cccagaactt gggcatcagc    960 

ctggccaact tgttgctgag caaaggagcc aaaaacatcc tggatgttgc acggcaattg   1020 

aacgatgccc attaa                                                    1035 

 
           
             4  
             1113  
             DNA  
             Human tissue  
           
            4 

cacacagcct actttccaag cggagccatg tctggtaacg gcaatgcggc tgcaacggcg     60 

gaagaaaaca gcccaaagat gagagtgatt cgcgtgggta cccgcaagag ccagcttgct    120 

cgcatacaga cggacagtgt ggtggcaaca ttgaaagcct cgtaccctgg cctgcagttt    180 

gaaatcattg ctatgtccac cacaggggac aagattcttg atactgcact ctctaagatt    240 

ggagagaaaa gcctgtttac caaggagctt gaacatgccc tggagaagaa tgaagtggac    300 

ctggttgttc actccttgaa ggacctgccc actgtgcttc ctcctggctt caccatcgga    360 

gccatctgca agcgggaaaa ccctcatgat gctgttgtct ttcacccaaa atttgttggg    420 

aagaccctag aaaccctgcc agagaagagt gtggtgggaa ccagctccct gcgaagagca    480 

gcccagctgc agagaaagtt cccgcatctg gagttcagga gtattcgggg aaacctcaac    540 

acccggcttc ggaagctgga cgagcagcag gagttcagtg ccatcatcct ggcaacagct    600 

ggcctgcagc gcatgggctg gcacaaccgg gttgggcaga tcctgcaccc tgaggaatgc    660 

atgtatgctg tgggccaggg ggccttgggc gtggaagtgc gagccaagga ccaggacatc    720 

ttggatctgg tgggtgtgct gcacgatccc gagactctgc ttcgctgcat cgctgaaagg    780 

gccttcctga ggcacctgga aggaggctgc agtgtgccag tagccgtgca tacagctatg    840 

aaggatgggc aactgtacct gactggagga gtctggagtc tagacggctc agatagcata    900 

caagagacca tgcaggctac catccatgtc cctgcccagc atgaagatgg ccctgaggat    960 

gacccacagt tggtaggcat cactgctcgt aacattccac gagggcccca gttggctgcc   1020 

cagaacttgg gcatcagcct ggccaacttg ttgctgagca aaggagccaa aaacatcctg   1080 

gatgttgcac ggcaattgaa cgatgcccat taa                                1113 

 
           
             5  
             1035  
             DNA  
             Human tissue  
           
            5 

atgagagtga ttcgcgtggg tacccgcaag agccagcttg ctcgcataca gacggacagt     60 

gtggtggcaa cattgaaagc ctcgtaccct ggcctgcagt ttgaaatcat tgctatgtcc    120 

accacagggg acaagattct tgatactgca ctctctaaga ttggagagaa aagcctgttt    180 

accaaggagc ttgaacatgc cctggagaag aatgaagtgg acctggttgt tcactccttg    240 

aaggacctgc ccactgtgct tcctcctggc ttcaccatcg gagccatctg caagcgggaa    300 

aaccctcatg atgctgttgt ctttcaccca aaatttgttg ggaagaccct agaaaccctg    360 

ccagagaaga gtgtggtggg aaccagctcc ctgcgaagag cagcccagct gcagagaaag    420 

ttcccgcatc tggagttcag gagtattcgg ggaaacctca acacccggct tcggaagctg    480 

gacgagcagc aggagttcag tgccatcatc ctggcaacag ctggcctgca gcgcatgggc    540 

tggcacaacc gggtggggca gatcctgcac cctgaggaat gcatgtatgc tgtgggccag    600 

ggggccttgg gcgtggaagt gcgagccaag gaccaggaca tcttggatct ggtgggtgtg    660 

ctgcacgatc ccgagactct gcttcgctgc atcgctgaaa gggccttcct gaggcacctg    720 

gaaggaggct gcagtgtgcc agtagccgtg catacagcta tgaaggatgg gcaactgtac    780 

ctgactggag gagtctggag tctagacggc tcagatagca tacaagagac catgcaggct    840 

accatccatg tccctgccca gcatgaagat ggccctgagg atgacccaca gttggtaggc    900 

atcactgctc gtaacattcc acgagggccc cagttggctg cccagaactt gggcatcagc    960 

ctggccaact tgttgctgag caaaggagcc aaaaacatcc tggatgttgc acggcaattg   1020 

aacgatgccc attaa                                                    1035 

 
           
             6  
             1035  
             DNA  
             Human tissue  
           
            6 

atgagagtga ttcgcgtggg tacccgcaag agccagcttg ctcgcataca gacggacagt     60 

gtggtggcaa cattgaaagc ctcgtaccct ggcctgcagt ttgaaatcat tgctatgtcc    120 

accacagggg acaagattct tgatactgca ctctctaaga ttggagagaa aagcctgttt    180 

accaaggagc ttgaacatgc cctggagaag aatgaagtgg acctggttgt tcactccttg    240 

aaggacctgc ccactgtgct tcctcctggc ttcaccatcg gagccatctg caagcgggaa    300 

aaccctcatg atgctgttgt ctttcaccca aaatttgttg ggaagaccct agaaaccctg    360 

ccagagaaga gtgtggtggg aaccagctcc ctgcgaagag cagcccagct gcagagaaag    420 

ttcccgcatc tggagttcag gagtattcgg ggaaacctca acacccggct tcggaagctg    480 

gacgagcagc aggagttcag tgccatcatc ctggcaacag ctggcctgca gcgcatgggc    540 

tggcacaacc gggtggggca gatcctgcac cctgaggaat gcatgtatgc tgtgggccag    600 

ggggccttgg gcgtggaagt gcgagccaag gaccaggaca tcttggatct ggtgggtgtg    660 

ctgcacgatc ccgagactct gcttcgctgc atcgctgaaa gggccttcct gaggcacctg    720 

gaaggaggct gcagtgtgcc agtagccgtg catacagcta tgaaggatgg gcaactgtac    780 

ctgactggag gagtctggag tctagacggc tcagatagca tacaagagac catgcaggct    840 

accatccatg tccctgccca gcatgaagat ggccctgagg atgacccaca gttggtaggc    900 

atcactgctc gtaacattcc acgagggccc cagttggctg cccagaactt gggcatcagc    960 

ctggccaact tgttgctgag caaaggagcc aaaaacatcc tggatgttgc acggcaattg   1020 

aacgatgccc attaa                                                    1035 

 
           
             7  
             1034  
             DNA  
             Human tissue  
           
            7 

atgagagtga ttcgcgtggg tacccgcaag agccagcttg ctcgcataca gacggacagt     60 

gtggtggcaa cattgaaagc ctcgtaccct ggcctgcagt ttgaaatcat tgctatgtcc    120 

accacagggg acaagattct tgatactgca ctctctaaga ttggagagaa aagcctgttt    180 

accaaggagc ttgaacatgc cctggagaag aatgaagtgg acctggttgt tcactccttg    240 

aaggacctgc ccactgtgct tcctcctggc ttcaccatcg gagccatctg caagcgggaa    300 

aaccctcatg atgctgttgt cttcacccaa aatttgttgg gaagacccta gaaaccctgc    360 

cagagaagag tgtggtggga accagctccc tgcgaagagc agcccagctg cagagaaagt    420 

tcccgcatct ggagttcagg agtattcggg gaaacctcaa cacccggctt cggaagctgg    480 

acgagcagca ggagttcagt gccatcatcc tggcaacagc tggcctgcag cgcatgggct    540 

ggcacaaccg ggtggggcag atcctgcacc ctgaggaatg catgtatgct gtgggccagg    600 

gggccttggg cgtggaagtg cgagccaagg accaggacat cttggatctg gtgggtgtgc    660 

tgcacgatcc cgagactctg cttcgctgca tcgctgaaag ggccttcctg aggcacctgg    720 

aaggaggctg cagtgtgcca gtagccgtgc atacagctat gaaggatggg caactgtacc    780 

tgactggagg agtctggagt ctagacggct cagatagcat acaagagacc atgcaggcta    840 

ccatccatgt ccctgcccag catgaagatg gccctgagga tgacccacag ttggtaggca    900 

tcactgctcg taacattcca cgagggcccc agttggctgc ccagaacttg ggcatcagcc    960 

tggccaactt gttgctgagc aaaggagcca aaaacatcct ggatgttgca cggcaattga   1020 

acgatgccca ttaa                                                     1034 

 
           
             8  
             1035  
             DNA  
             Human tissue  
           
            8 

atgagagtga ttcgcgtggg tacccgcaag agccagcttg ctcgcataca gacgggcagt     60 

gtggtggcaa cattgaaagc ctcgtaccct ggcctgcagt ttgaaatcat tgctatgtcc    120 

accacagggg acaagattct tgatactgca ctctctaaga ttggagagaa aagcctgttt    180 

accaaggagc ttgaacatgc cctggagaag aatgaagtgg acctggttgt tcactccttg    240 

aaggacctgc ccactgtgct tcctcctggc ttcaccatcg gagccatctg caagcgggaa    300 

aaccctcatg atgctgttgt ctttcaccca aaatttgttg ggaagaccct agaaaccctg    360 

ccagagaaga gtgtggtggg aaccagctcc ctgcgaagag cagcccagct gcagagaagg    420 

ttcccgcatc tggagttcag gagtattcgg ggaaacctca acacccggct tcggaagctg    480 

gacgagcagc aggagttcag tgtcatcatc ctggcaacag ctggcctgca gcgcatgggc    540 

tggcacaacc gggttgggca gatcctgcac cctgaggaat gcatgtatgc tgtgggccag    600 

ggggccttgg gcgtggaagt gcgagccaag gaccaggaca tcttggatct ggtgggtgtg    660 

ctgcacgatc ccgagactct gcttcgctgc atcgctgaaa gggccttcct gaggcacctg    720 

gaaggaggct gcagtgtgcc agtagccgtg catacagcta tgaaggatgg gcaactgtac    780 

ctgactggag gagtctggag tctagacggc tcagatagca tacaagagac catgcaggct    840 

accatccatg tccctgccca gcatgaagat ggccctgagg atgacccaca gttggtaggc    900 

atcactgctc gtaacattcc acgagggccc cagttggctg cccagaactt gggcatcagc    960 

ctggccaact tgttgctgag caagggagcc aaaaacatcc tggatgttgc acggcaattg   1020 

aacgatgccc attaa                                                    1035 

 
           
             9  
             1035  
             DNA  
             Human tissue  
           
            9 

atgagagtga ttcgcgtggg tacccgcaag agccagcttg ctcgcataca gacggacagt     60 

gtggtggcaa cattgaaagc ctcgtaccct ggcctgcagt ttgaaatcat tgctatgtcc    120 

accacagggg acaagattct tgatactgca ctctctaaga ttggagagaa aagcctgttt    180 

accaaggagc ttgaacatgc cctggagaag aatgaagtgg acctggttgt tcactccttg    240 

aaggacctgc ccactgtgct tcctcctggc ttcaccatcg gagccatctg caagcgggaa    300 

aaccctcatg atgctgttgt ctttcaccca aaatttgttg ggaagaccct agaaaccctg    360 

ccagagaaga gtgtggtggg aaccagctcc ctgcgaagag cagcccagct gcagagaaag    420 

ttcccgcatc tggagttcag gagtattcgg ggaaacctca acacccggct tcggaagctg    480 

gacgagcagc aggagttcag tgccatcatc ctggcaacag ctggcctgca gcgcatgggc    540 

tggcacaacc gggtggggca gatcctgcac cctgaggaat gcatgtatgc tgtgggccag    600 

ggggccttgg gcgtggaagt gcgagccaag gaccaggaca tcttggatct ggtgggtgtg    660 

ctgcacgatc ccgagactct gcttcgctgc atcgctgaaa gggccttcct gaggcacctg    720 

gaaggaggtt gcagtgtgcc agtagccgtg catacagcta tgaaggatgg gcaactgtac    780 

ctgactggag gagtctggag tctagacggc tcagatagca tacaagagac catgcaggct    840 

accatccatg tccctgccca gcatgaagat ggccctgagg atgacccaca gttggtaggc    900 

atcactgctc gtaacattcc acgagggccc cagttggctg cccagaactt gggcatcagc    960 

ctggccaact tgttgctgag caaaggagcc aaaaacatcc tggatgttgc acggcaattg   1020 

aacgatgccc attaa                                                    1035 

 
           
             10  
             1034  
             DNA  
             Human tissue  
           
            10 

atgagagtga ttcgcgtggg tacccgcaag agccagcttg ctcgcataca gacggacagt     60 

gtggtggcaa cattgaaagc ctcgtaccct ggcctgcagt ttgaaatcat tgctatgtcc    120 

accacagggg acaagattct tgatactgca ctctctaaga ttggagagaa aagcctgttt    180 

accaaggagc ttgaacatgc cctggagaag aatgaagtgg acctggttgt tcactccttg    240 

aaggacctgc ccactgtgct tcctcctggc ttcaccatcg gagccatctg caagcgggaa    300 

aaccctcatg atgctgttgt ctttcaccca aaatttgttg ggaagaccct agaaaccctg    360 

ccagagaaga gtgtggtggg aaccagctcc ctgcgaagag cagcccagct gcagagaaag    420 

ttcccgcatc tggagttcag gagtattcgg ggaaacctca acacccggct tcggaagctg    480 

gacgagcagc aggagttcag tgccatcatc ctggcaacag ctggcctgca gcgcatgggc    540 

tggcacaacc gggtggggca gatcctgcac cctgaggaat gcatgtatgc tgtgggccag    600 

ggggccttgg gcgtggaagt gcgagccaag gaccaggaca tcttggatct ggtgggtgtg    660 

ctgcacgatc ccgagactct gcttcgctgc atcgctgaaa gggccttcct gaggcacctg    720 

gaaggaggct gcagtgtgcc agtagccgtg catacagcta tgaaggatgg gcaactgtac    780 

ctgactggag gagtctggag tctagacggc tcagatagca tacaagagac catgcaggct    840 

accatccatg tccctgccca gcatgaagat ggccctgagg atgacccaca gttggtaggc    900 

atcactgctc gtaacattcc acgagggccc cagttggctg cccagaactt gggcatcagc    960 

ctggccaact tgttgctgag caaaggagcc aaaaacatcc tggatgttgc acggcaatta   1020 

acgatgccca ttaa                                                     1034 

 
           
             11  
             1035  
             DNA  
             Human tissue  
           
            11 

atgagagtga ttcgcgtggg tacccgcaag agccagcttg ctcgcataca gacggacagt     60 

gtggtggcaa cattgaaagc ctcgtaccct ggcctgcagt ttgaaatcat tgctatgtcc    120 

accacagggg acaagattct tgatactgca ctctctaaga ttggagagaa aagcctgttt    180 

accaaggagc ttgaacatgc cctggagaag aatgaagtgg acctggttgt tcactccttg    240 

aaggacctgc ccactgtgct tcctcctggc ttcaccatcg gagccatctg caagcgggaa    300 

aaccctcatg atgctgttgt ctttcaccca aaatttgttg ggaagaccct agaaaccctg    360 

ccagagaaga gtgtggtggg aaccagctcc ctgcgaagag cagcccagct gcagagaaag    420 

ttcccgcatc tggagttcag gagtattcgg ggaaacctca acacccggct tcggaagctg    480 

gacgagcagc aggagttcag tgccatcatc ctggcaacag ctggcctgca gcgcatgggc    540 

tggcacaacc gggtggggca gatcctgcac cctgaggaat gcatgtatgc tgtgggccag    600 

ggggccttgg gcgtggaagt gcgagccaag gaccaggaca tcttggatct ggtgggtgtg    660 

ctgcacgatc ccgagactct gcttcgctgc atcgctgaaa gggccttcct gaggcacctg    720 

gaaggaggct gcagtgtgcc agtagccgtg catacagcta tgaaggatgg gcaactgtac    780 

ctgactggag gagtctggag tctagacggc tcagatagca tacaagagac catgcaggcc    840 

accatccatg tccctaccca gcatgaagat ggccctgagg atgacccaca gttggtaggc    900 

atcactgctc gtaacattcc acgagggccc cagttggctg cccagaactt gggcatcagc    960 

ctggccaact tgttgctgag caaaggagcc aaaaacatcc tggatgttgc acggcaattg   1020 

aacgatgccc attaa                                                    1035 

 
           
             12  
             3988  
             DNA  
             Human tissue  
           
            12 

cacctgacgc gccctgtagc ggcgcattaa gcgcggcggg tgtggtggtt acgcgcagcg     60 

tgaccgctac acttgccagc gccctagcgc ccgctccttt cgctttcttc ccttcctttc    120 

tcgccacgtt cgccggcttt ccccgtcaag ctctaaatcg ggggctccct ttagggttcc    180 

gatttagtgc tttacggcac ctcgacccca aaaaacttga ttagggtgat ggttcacgta    240 

gtgggccatc gccctgatag acggtttttc gccctttgac gttggagtcc acgttcttta    300 

atagtggact cttgttccaa actggaacaa cactcaaccc tatctcggtc tattcttttg    360 

atttataagg gattttgccg atttcggcct attggttaaa aaatgagctg atttaacaaa    420 

aatttaacgc gaattttaac aaaatattaa cgcttacaat ttccattcgc cattcaggct    480 

gcgcaactgt tgggaagggc gatcggtgcg ggcctcttcg ctattacgcc agctggcgaa    540 

agggggatgt gctgcaaggc gattaagttg ggtaacgcca gggttttccc agtcacgacg    600 

ttgtaaaacg acggccagtg aattgtaata cgactcacta tagggcgaat tgggtaccgg    660 

gccccccctc gaggtcgacg gtatcgataa gcttattaat gggcatcgtt caattgccgt    720 

gcaacatcca ggatgttttt ggctcctttg ctcagcaaca agttggccag gctgatgccc    780 

aagttctggg cagccaactg gggccctcgt ggaatgttac gagcagtgat gcctaccaac    840 

tgtgggtcat cctcagggcc atcttcatgc tgggcaggga catggatggt agcctgcatg    900 

gtctcttgta tgctatctga gccgtctaga ctccagactc ctccagtcag gtacagttgc    960 

ccatccttca tagctgtatg cacggctact ggcacactgc agcctccttc caggtgcctc   1020 

aggaaggccc tttcagcgat gcagcgaagc agagtctcgg gatcgtgcag cacacccacc   1080 

agatccaaga tgtcctggtc cttggctcgc acttccacgc ccaaggcccc ctggcccaca   1140 

gcatacatgc attcctcagg gtgcaggatc tgcccaaccc ggttgtgcca gcccatgcgc   1200 

tgcaggccag ctgttgccag gatgatggca ctgaactcct gctgctcgtc cagcttccga   1260 

agccgggtgt tgaggtttcc ccgaatactc ctgaactcca gatgcgggaa ctttctctgc   1320 

agctgggctg ctcttcgcag ggagctggtt cccaccacac tcttctctgg cagggtttct   1380 

agggtcttcc caacaaattt tgggtgaaag acaacagcat catgagggtt ttcccgcttg   1440 

cagatggctc cgatggtgaa gccaggagga agcacagtgg gcaggtcctt caaggagtga   1500 

acaaccaggt ccacttcatt cttctccagg gcatgttcaa gctccttggt aaacaggctt   1560 

ttctctccaa tcttagagag tgcagtatca agaatcttgt cccctgtggt ggacatagca   1620 

atgatttcaa actgcaggcc agggtacgag gctttcaatg ttgccaccac actgtccgtc   1680 

tgtatgcgag caagctggct cttgcgggta cccacgcgaa tcactctcat gaattcctgc   1740 

agcccggggg atccactagt tctagagcgg ccgccaccgc ggtggagctc cagcttttgt   1800 

tccctttagt gagggttaat ttcgagcttg gcgtaatcat ggtcatagct gtttcctgtg   1860 

tgaaattgtt atccgctcac aattccacac aacatacgag ccggaagcat aaagtgtaaa   1920 

gcctggggtg cctaatgagt gagctaactc acattaattg cgttgcgctc actgcccgct   1980 

ttccagtcgg gaaacctgtc gtgccagctg cattaatgaa tcggccaacg cgcggggaga   2040 

ggcggtttgc gtattgggcg ctcttccgct tcctcgctca ctgactcgct gcgctcggtc   2100 

gttcggctgc ggcgagcggt atcagctcac tcaaaggcgg taatacggtt atccacagaa   2160 

tcaggggata acgcaggaaa gaacatgtga gcaaaaggcc agcaaaaggc caggaaccgt   2220 

aaaaaggccg cgttgctggc gtttttccat aggctccgcc cccctgacga gcatcacaaa   2280 

aatcgacgct caagtcagag gtggcgaaac ccgacaggac tataaagata ccaggcgttt   2340 

ccccctggaa gctccctcgt gcgctctcct gttccgaccc tgccgcttac cggatacctg   2400 

tccgcctttc tcccttcggg aagcgtggcg ctttctcata gctcacgctg taggtatctc   2460 

agttcggtgt aggtcgttcg ctccaagctg ggctgtgtgc acgaaccccc cgttcagccc   2520 

gaccgctgcg ccttatccgg taactatcgt cttgagtcca acccggtaag acacgactta   2580 

tcgccactgg cagcagccac tggtaacagg attagcagag cgaggtatgt aggcggtgct   2640 

acagagttct tgaagtggtg gcctaactac ggctacacta gaaggacagt atttggtatc   2700 

tgcgctctgc tgaagccagt taccttcgga aaaagagttg gtagctcttg atccggcaaa   2760 

caaaccaccg ctggtagcgg tggttttttt gtttgcaagc agcagattac gcgcagaaaa   2820 

aaaggatctc aagaagatcc tttgatcttt tctacggggt ctgacgctca gtggaacgaa   2880 

aactcacgtt aagggatttt ggtcatgaga ttatcaaaaa ggatcttcac ctagatcctt   2940 

ttaaattaaa aatgaagttt taaatcaatc taaagtatat atgagtaaac ttggtctgac   3000 

agttaccaat gcttaatcag tgaggcacct atctcagcga tctgtctatt tcgttcatcc   3060 

atagttgcct gactccccgt cgtgtagata actacgatac gggagggctt accatctggc   3120 

cccagtgctg caatgatacc gcgagaccca cgctcaccgg ctccagattt atcagcaata   3180 

aaccagccag ccggaagggc cgagcgcaga agtggtcctg caactttatc cgcctccatc   3240 

cagtctatta attgttgccg ggaagctaga gtaagtagtt cgccagttaa tagtttgcgc   3300 

aacgttgttg ccattgctac aggcatcgtg gtgtcacgct cgtcgtttgg tatggcttca   3360 

ttcagctccg gttcccaacg atcaaggcga gttacatgat cccccatgtt gtgcaaaaaa   3420 

gcggttagct ccttcggtcc tccgatcgtt gtcagaagta agttggccgc agtgttatca   3480 

ctcatggtta tggcagcact gcataattct cttactgtca tgccatccgt aagatgcttt   3540 

tctgtgactg gtgagtactc aaccaagtca ttctgagaat agtgtatgcg gcgaccgagt   3600 

tgctcttgcc cggcgtcaat acgggataat accgcgccac atagcagaac tttaaaagtg   3660 

ctcatcattg gaaaacgttc ttcggggcga aaactctcaa ggatcttacc gctgttgaga   3720 

tccagttcga tgtaacccac tcgtgcaccc aactgatctt cagcatcttt tactttcacc   3780 

agcgtttctg ggtgagcaaa aacaggaagg caaaatgccg caaaaaaggg aataagggcg   3840 

acacggaaat gttgaatact catactcttc ctttttcaat attattgaag catttatcag   3900 

ggttattgtc tcatgagcgg atacatattt gaatgtattt agaaaaataa acaaataggg   3960 

gttccgcgca catttccccg aaaagtgc                                      3988 

 
           
             13  
             1260  
             DNA  
             Human tissue  
           
            13 

cacaggaaac agctatgacc atgattacgc caagctcgaa attaaccctc actaaaggga     60 

acaaaagctg gagctccacc gcggtggcgg ccgctctaga actagtggat cccccgggct    120 

gcaggaattc atgagagtga ttcgcgtggg tacccgcaag agccagcttg ctcgcataca    180 

gacggacagt gtggtggcaa cattgaaagc ctcgtaccct ggcctgcagt ttgaaatcat    240 

tgctatgtcc accacagggg acaagattct tgatactgca ctctctaaga ttggagagaa    300 

aagcctgttt accaaggagc ttgaacatgc cctggagaag aatgaagtgg acctggttgt    360 

tcactccttg aaggacctgc ccactgtgct tcctcctggc ttcaccatcg gagccatctg    420 

caagcgggaa aaccctcatg atgctgttgt ctttcaccca aaatttgttg ggaagaccct    480 

agaaaccctg ccagagaaga gtgtggtggg aaccagctcc ctgcgaagag cagcccagct    540 

gcagagaaag ttcccgcatc tggagttcag gagtattcgg ggaaacctca acacccggct    600 

tcggaagctg gacgagcagc aggagttcag tgccatcatc ctggcaacag ctggcctgca    660 

gcgcatgggc tggcacaacc gggttgggca gatcctgcac cctgaggaat gcatgtatgc    720 

tgtgggccag ggggccttgg gcgtggaagt gcgagccaag gaccaggaca tcttggatct    780 

ggtgggtgtg ctgcacgatc ccgagactct gcttcgctgc atcgctgaaa gggccttcct    840 

gaggcacctg gaaggaggct gcagtgtgcc agtagccgtg catacagcta tgaaggatgg    900 

gcaactgtac ctgactggag gagtctggag tctagacggc tcagatagca tacaagagac    960 

catgcaggct accatccatg tccctgccca gcatgaagat ggccctgagg atgacccaca   1020 

gttggtaggc atcactgctc gtaacattcc acgagggccc cagttggctg cccagaactt   1080 

gggcatcagc ctggccaact tgttgctgag caaaggagcc aaaaacatcc tggatgttgc   1140 

acggcaattg aacgatgccc attaataagc ttatcgatac cgtcgacctc gagggggggc   1200 

ccggtaccca attcgcccta tagtgagtcg tattacaatt cactggccgt cgttttacaa   1260  
           
             14  
             32  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            14 

cgtggaattc atgagagtga ttcgcgtggg ta                                   32 

 
           
             15  
             47  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            15 

ggagaagctt attaatgggc atcgttcaat tgccgtgcaa catccag                   47 

 
           
             16  
             20  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            16 

tcgcctccct ctagtctctg                                                 20 

 
           
             17  
             21  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            17 

cagcaggagt tcagtgccat c                                               21 

 
           
             18  
             21  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            18 

gatggcactg aactcctgct g                                               21 

 
           
             19  
             20  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            19 

cagcaaccca ggcatctgtg                                                 20 

 
           
             20  
             22  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            20 

gtaatacgac tcactatagg gc                                              22 

 
           
             21  
             22  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            21 

ctaaagggaa caaaagctgg ag                                              22 

 
           
             22  
             21  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            22 

cagctatgac catgattacg c                                               21 

 
           
             23  
             54  
             DNA  
             Artificial Sequence  
             
               CDS  
               (32)..(52)  
               Description of Artificial Sequence Modified 5′
      untranslated region of plasmid pExp1 (P 27, L 17-25)  
             
           
            23 

aattctaaca taagttaagg aggaaaaaaa a atg aga gtt att cgt gtc ggt ac     54 
                                   Met Arg Val Ile Arg Val Gly 
                                     1               5 

 
           
             24  
             7  
             PRT  
             Artificial Sequence  
             
               Description of Artificial Sequence N-terminal 
      of peptide encoded by ID 23; related to N-terminal of PBGD 
      (P 27, L 23-27)  
             
           
            24 

Met Arg Val Ile Arg Val Gly 
                5 

 
           
             25  
             54  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            25 

aattctaaca taagttaagg aggaaaaaaa aatgagagtt attcgtgtcg gtac           54 

 
           
             26  
             46  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            26 

cgacacgaat aactctcatt tttttttcct ccttaactta tgttag                    46 

 
           
             27  
             32  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            27 

gatcactcat gtttgacagc ttatcatcga tt                                   32 

 
           
             28  
             30  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            28 

agctaatcga tgataagcgt caaacatgag                                      30 

 
           
             29  
             32  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            29 

agtcagaatt cagacgcacg gcggtacgat aa                                   32 

 
           
             30  
             32  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            30 

attcactcga ggtcaccatc ggtaccagtt ca                                   32 

 
           
             31  
             32  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            31 

agatcaagct tcggccagac gcaggttatc ta                                   32 

 
           
             32  
             34  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            32 

atacactcga gaccggcatg agtatccttg tcac                                 34 

 
           
             33  
             30  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            33 

actgacctcg agcggcacgt aagaggttcc                                      30 

 
           
             34  
             29  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            34 

actgaactcg agaattacgc cccgccctg                                       29 

 
           
             35  
             60  
             DNA  
             Artificial Sequence  
             
               CDS  
               (1)..(60)  
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            35 

atg tct ggt aac ggc att gcg gct gca acg gcg gaa gaa aac agc cca       48 
Met Ser Gly Asn Gly Ile Ala Ala Ala Thr Ala Glu Glu Asn Ser Pro 
  1               5                  10                  15 

aag atg aga gtg                                                       60 
Lys Met Arg Val 
             20 

 
           
             36  
             20  
             PRT  
             Artificial Sequence  
             
               Description of Artificial Sequence Primer for 
      PCR amplification  
             
           
            36 

Met Ser Gly Asn Gly Ile Ala Ala Ala Thr Ala Glu Glu Asn Ser Pro 
  1               5                  10                  15 

Lys Met Arg Val 
             20 

 
           
             37  
             25  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Fragment 
      of normal chromosomal sequence  
             
           
            37 

agcgcatggg ctggcacaac cgggt                                           25 

 
           
             38  
             9  
             PRT  
             Artificial Sequence  
             
               Description of Artificial Sequence encoded by 
      SEQ ID NO37  
             
           
            38 

Gln Arg Met Gly Trp His Asn Arg Val 
  1               5 

 
           
             39  
             25  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence Fragment 
      of AIP chromosomal sequence  
             
           
            39 

agcgcatggg ctagcacaac cgggt                                           25 

 
           
             40  
             68  
             DNA  
             Artificial Sequence  
             
               Description of Artificial Sequence linear 
      single-stranded chimeric (RNA/DNA) oligonucleotide with hairpin 
      secondary structure  
             
           
            40 

agcgcatggg ctggcacaac cgggttttta cccggttgtg ccagcccatg cgctccgggt     60 

tttcccgg                                                              68