Abstract:
A DNA sequence encoding the δ-amino levulinate type 2 gene, methods to detect the gene, diagnostic kits to detect the gene and recombinant vectors containing the type 2 gene sequence.

Description:
This invention was supported by National Institute of Health grants DK34045 and DK26824. The government may have certain rights in the invention. 
    
    
     This application is a division of Ser. No. 08/195,744 filed Feb. 14, 1994 which issued as U.S. Pat. No. 5,639,607 on Jun. 17, 1997 which is a continuation of U.S. Ser. No. 07/742,130 filed Aug. 7, 1991, abandoned. 
    
    
     SPECIFICATION 
     1. Field of the Invention 
     This invention relates to a method for determining susceptibility to lead poisoning by assaying for a polymorphism in the gene encoding 6-amino levulinate dehydratase (ALA-D), as well as a diagnostic kit for determining the polymorphism comprising a means for extracting a DNA sample and a means for detecting the presence of the ALA-D polymorphism in the DNA sample. 
     2. Background of the Invention 
     Lead is toxic to numerous organ systems, including the reticuloendothelial and nervous systems. The most important consequence of low-level lead toxicity is irreversible neurological damage. Although ambient lead levels are markedly below those of a decade ago as a result of the reduced use of leaded gasoline, there remain the problems of widespread detection of lead-paint poisoning of children, control of lead exposure in the workplace, increased lead absorption and low-level lead toxicity. 
     Recent neuroepidemiologic studies have demonstrated peripheral neurological abnormalities in lead-exposed adults at levels of 30-40 μg/dl and in children at blood lead levels as low as 20-30 μg/dl. Seppalainen et al. (1983) Neurotoxicology, 4:181-192; and Needleman et al. (1979) N. Eng. J. Med., 300:689-695. The Second National Health and Nutrition Examination Survey (NHANES-II) found that 1.5 million preschool children had blood lead levels of 25 μg/dl and above, indicating lead absorption. 
     Recent evidence indicates that the prevalence of central neurological symptoms is elevated and neurobehavioral performance is impaired in adults at blood lead levels of 40-60 μg/dl. Baker et al. (1985) Brit. J. Industr. Med., 41:507-516; Jeyarathnam et al. (1987) Brit. J. Industr. Med., 43:626-629; and Lilis et al. (1985) Arch. Env. Health, 40:38-47. Central nervous system dysfunction in children with elevated blood lead levels has been measured using verbal I.Q. test scores. In one U.S. study, children with blood lead levels of 25-45 μg/dl scored 4.5 points lower on the I.Q. tests after adjusting for parental education, childhood illnesses and socioeconomic status. Needleman et al. (1979). In two cross-sectional European studies, similar effects of low-level lead central nervous system toxicity were observed. Winneke et al. (1981) Internat. Conf. on Heavy Metals in the Environment, Geneva, World Health Organization, pp. 553-556; and Smith et al. (1983) Dev. Med. Child Neurol., 25(suppl 47):1-20. Furthermore, both decreases in intelligence and shortened attention span have been reported in young children who had moderately elevated umbilical cord blood lead levels at birth. Bellinger et al. (1987) N. Engl. J. Med., 316:1037-1043. By all measurements, children appear to be at significant risk from low-level lead exposure. Needleman et al., (1990) N. Engl. J. Med., 322:83-88. 
     In a rat model, lead has been shown to be mobilized from maternal stores during pregnancy and to cross the placenta. Moreover, lead has been shown to produce neural tube defects in three rodent species. Gerber et al. (1977) Mutat. Res., 76:115-141. In man, increased placental lead concentrations have been reported in stillborns and in infants with mental retardation and congenital anomalies. Wibberly et al. (1977) J. Med. Genet., 14:339-345. A study of over 5000 births with 3% congenital malformations demonstrated a significant dose-related correlation between placental lead concentration and congenital anomalies. Needleman et al. (1984) J. Amer. Med. Assoc., 251:2956-2959. The effects of other possible teratogenic variables were eliminated by multivariant analysis. 
     There is also evidence that lead affects the male gamete. Increased numbers of chromosomal aberrations in sperm have been found both in experimental animals exposed to lead and in lead workers. Deknudt et al. (1973) Environ. Physiol. Biochem., 3:132-138. Lead was one of only three substances included on the initial California &#34;short list&#34; of reproductive toxins. Baum. Chem. Eng. News, Mar. 16, 1987, p. 22. 
     ALA-D, the second enzyme in the heme biosynthetic pathway, catalyzes the asymmetric condensation of two molecules of 5-aminolevulinate (ALA) to form the monopyrrole, porphobilinogen (PBG), the precursor of heme, cytochromes and cobalamins. The mammalian enzyme has been purified to homogeneity from bovine liver and human erythrocytes. Wu et al. (1974) Proc. Natl. Acad. Sci. USA, 71:1767-1770; Gurne et al. (1977) Proc. Natl. Acad. Sci. USA, 74:1383-138; and Anderson and Desnick (1979) J. Biol. Chem., 254:6924-6930. ALA-D is a metalloenzyme composed of eight identical subunits and eight zinc atoms. Anderson and Desnick (1979); Bevan et al. (1980) J. Biol. Chem., 255:2030-2035; Tsukamoto et al. (1979) Biochem. Biophys. Acta, 570:167-178; Tsukamoto et al. (1980) Int. J. Biochem., 12:751-756; and Jaffe et al. (1984) J. Biol. Chem., 259:5032-5036. 
     ALA-D activity is inhibited by lead and various heavy metals as well as by the oxidation of critical thiol groups. Anderson &amp; Desnick (1979); and Jordan et al. (1985) Biochem. J., 222:1015-1020. Lead atoms replace the zinc atoms which are required to maintain ALA-D activity. Tsukamoto et al. (1979). The inhibition of erythrocyte ALA-D activity has been used as a sensitive diagnostic indicator of lead exposure. Morgan et al. (1972) Arch. Intern. Med., 130:335-341. The inhibition is stoichiometric; e.g., 15 and 30 μg of Pb per dl blood results in 50% and 75% ALA-D inhibition, respectively. More recently, the ratio of ALA-D present before and after reactivation with zinc and DTT has been shown to correlate best to blood lead levels. Chisholm et al. (1985), Clin. Chem., 31:662-668. The inhibition of ALA-D activity results in a proportionate accumulation of ALA blood and urine. The accumulation of ALA has been causally related to the neurological manifestations of lead poisoning. 
     Human ALA-D, has been shown to be a polymorphic enzyme. Petrucci et al. (1982) Hum. Genet., 60:289-290; and Battistuzzi et al. (1981) Ann. Hum. Genet., 45:223-229. The allelic polypetides are encoded by a gene located on chromosome 9 in the region 9q34. Potluri et al. (1987) Hum. Genet., 76:236-239. The ALA-D gene has two common alleles, ALA-D 1  and ALA-D 2 , which result in a polymorphic enzyme system with three distinct charge isozyme phenotypes, designated ALA-D 1-1, ALA-D 1-2 and ALA-D 2-2. The isozymes may be separated by starch gel electrophoresis. Battistuzzi (1981). In the Italian population, the frequencies of the isozyme phenotypes are 1-1 (81%), 1-2 (17%) and 2-2 (2%), consistent with gene frequencies of 0.90 and 0.10 for the ALA-D 1  and ALA-D 2  alleles, respectively. Similar results were obtained in other European populations, whereas expression of the ALA-D 2  allele was not observed in a large sample of Black individuals from Liberia. Benkmann et al. (1983) Hum. Hered., 33:62-64. A study of ALA-D isozyme phenotypes in erythrocytes of over 950 normal Caucasian individuals from New York showed the frequencies of the ALA-D 1-1, 1-2, and 1-2 isozyme phenotypes to be similar to those observed in the Italian population. 
     The occurrence of the ALA-D polymorphism is of interest, particularly with respect to the possible increased susceptibility of certain isozyme phenotypes to the detrimental effects of lead exposure. Polymorphisms at other genetic loci are known to be related to differential inherited responses to environmental challenges. For example, the response to Plasmodium (malaria) is affected by hemoglobin S, hemoglobin AS heterozygotes being more resistant to disease than individuals with normal hemoglobin AA. Pasval et al, (1978) Nature, 274:7801-7803. Similarly, Asian individuals are more susceptible to alcohol intoxication due to the presence of a particular alcohol dehydrogenase polymorphism. Propping (1978) J. Physiol. Biochem. Pharmacol., 83:124-173. 
     The existence of this common ALA-D polymorphism and the fact that ALA-D is markedly inhibited by lead suggests that there is a physiologic relationship between the frequency of the ALA-D 2  allele and lead poisoning. For instance, individuals with the ALA-D 2  allele may be more susceptible to the detrimental effects of lead exposure if the ALA-D 2  subunit bound lead more tightly than the ALA-D 1  subunit. They would have higher blood and bone lead concentrations as well as higher total body lead stores, making them even more likely to express subclinical and clinical manifestations of chronic low level or acute lead exposure. Alternatively, the tight binding of blood lead by erythrocyte ALA-D 2  may prevent the distribution of lead to the neurologic system, thereby preventing or minimizing the neurotoxic effects of lead. 
     A study of blood lead levels and ALA-D isozyme types in 1277 blood samples obtained from the New York City Lead Screening Program was performed in a double-blind fashion. That is, the blood lead levels were provided by the Toxicology Laboratory only after the blind determination of the ALA-D isozyme phenotype. Table I is a compilation of the number of individuals with the ALA-D 1-1, ALA-D 1-2, ALA-D 2-2 phenotypes having blood lead levels above or below either 25 or 30 μg/dl. These results demonstrate that a high proportion of these individuals with high blood lead levels had the ALA-D 2  allele. Astrin et al. (1987) Ann. N. Y. Acad. Sci., 514:23-29. The presence of the ALA-D 2  allele apparently leads to approximately a two-fold increase in lead retention at blood levels of 25 or 30 μg/dl. In some cases, the ethnic group was known. The incidence of the ALA-D 2  allele among lead poisoned Black children was high even though the incidence of the ALA-D 2  allele among Blacks in general is low. The results obtained support a relationship between the ALA-D 2  allele and the accumulation of lead in the blood. Similar data support the identical conclusion. Ziemsen et al. (1986) Int. Arch. Occup. Environ. Health, 58:245-247. 
     
                       TABLE 1______________________________________HUMAN ALA-D POLYMORPHISM: ASSOCIATION WITHLEAD POISONING Blood Lead     ALA-D Isozyme PhenotypeSample Level    (Number and Percent in Sample Set)Set   (μg/dl)          Total   1-1    (%)   1-2 or 2-2______________________________________Total: &lt;25      870     803    (71)  67     (47) ≧25          408     333    (29)  75     (53)          1278    1136   (100) 142    (100) &gt;30      1000    919    (81)  81     (57) ≧30          278     217    (19)  60     (43)          1278    1136   (100) 142    (100)Blacks: &gt;30      292     282    (88)  10     (38) ≧30           53      37    (12)  16     (62)          345     319    (100) 26     (100)______________________________________ 
    
     It has previously been found that the frequency of the ALA-D 2  allele to be 10-11% in Italian and German populations. Battistuzzi et al. (1981) &#34;δ-aminolevulinate Dehydratase: A new Genetic Polymorphism in Man&#34;, Ann. Hum. Genet., 45:223-229; and Benkmann et al., (1983) &#34;Polymorphism of Delta-aminolevulinic Acid Dehydratase in Various Populations&#34;, Hum. Hered., 33:62-64. A study indicated an ALA-D 2  allele frequency of 20% in Eastern European Ashkenazi Jews living in Israel. Ben-Ezzer et al., (1987) &#34;Genetic Polymorphism of Delta-aminolevulinate Dehydratase in Several Population Groups in Israel&#34;, Hum. Hered., 37:229-232. The blood samples used for this study came from a Tay-Sachs screening program, which would be biased toward an Ashkenazi Jewish population. In this experiment the observed ALA-D 2  allele frequency of 12% was thus somewhat higher than the average frequency of 10-11% in European populations. 
     It would be useful to have a rapid, inexpensive diagnostic method to detect the human ALA-D polymorphism. Such a method is useful in screening for persons susceptible to lead poisoning so that they could be given jobs with less exposure to lead. Also, screening may identify children who are more susceptible to lead poisoning and therefore dictate a more rigorous prevention program, monitoring and/or detoxification therapy in such children. 
     SUMMARY OF THE INVENTION 
     A diagnostic method for determining susceptibility to lead poisoning by obtaining a biological sample from a patient and analyzing the sample for the presence of a polymorphism of the δ-amino levulinate dehydratase gene. Suitable analysis methods include but are not limited to digesting the DNA with a restriction endonuclease that recognizes the DNA sequence at the site of the polymorphism being able to cleave at the site in the ALA-D 2  but not the ALA-D 1  allele, and determining whether the DNA sample has been cleaved by the restriction endonuclease. The DNA encoding ALA-D may be amplified prior to restriction endonuclease cleavage. 
     The invention is useful for screening biological samples with a high degree of reliability and specificity. Samples include but are not limited to body fluids such as blood, sera, and tissue samples. A diagnostic kit is provided to perform the method of the present invention. The kit provides a means for extracting DNA from the sample, means for digesting the DNA and a means for analyzing the digestion products. A means for amplifying the DNA encoding ALA-D or a portion thereof may also be provided. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 shows a schematic for the PCR analysis of the ALA-D polymorphism. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     The molecular nature of the ALA-D polymorphism has now been determined to be based upon the single nucleotide difference found between the sequences of the ALA-D 1  and ALA-D 2  cDNA clones. Codon 59 is AAG (lysine) in ALA-D 1  and AAC (asparagine) in ALA-D 2 . This transversion results in a new restriction endonuclease site CCGG in ALA-D 2  cDNA and in ALA-D 2  genomic DNA thus allowing differential restriction endonuclease digestion. A particularly suitable restriction endonuclease for use in the present invention is Msp I, however, any restriction endonuclease capable of recognizing the nucleotides CCGG or a DNA sequence containing the nucleotides CCGG so as to cleave the DNA at the CCGG site or any other detectable site upon recognition of CCGG is suitable for use in the present invention. The segment of DNA encoding ALA-D or a segment thereof may be amplified prior to restriction by the endonuclease. In the preferred embodiment of the present invention, the pertinent DNA sequence is amplified prior to restriction endonuclease digestion. 
     The amplification may be carried out by synthesizing DNA fragments using a polymerase chain based reaction such as that shown in FIG. 1. Any other method of DNA amplification is suitable for use in the present invention provided it is reasonably accurate and maintains reasonable fidelity of the DNA sequence. Preferably, primers are prepared based on the DNA sequence in the introns surrounding exon 4, the site of the transversion. Preferably the primers are chosen so as to span other CCGG restriction endonuclease sites, as an internal control, so that unique cleavage products result for both the ALA-D 1  and ALA-D 2  allele. For instance sets of DNA primers for the 5&#39; intron having the nucleotide sequence ##STR1## and for the 3&#39; intron ##STR2## are preferred. 
     After amplification, the DNA is digested by the restriction endonuclease recognizing the CCGG DNA sequence. The resultant DNA segments are analyzed for example by electrophoresis on an agarose gel and subsequent fluorographic visualization by staining the DNA with intercalating agents such as ethidium bromide. 
     Also included in the present invention are any other suitable methods for detecting the polymorphism. Such methods include but are not limited to allele-specific oligonucleotide hybridization, oligonucleotide ligation, ligation amplification and competitive PCR. Conner et al. (1983) Proc. Natl. Acad. Sci. USA, 80:278-282; Saiki et al. (1985) Nature, 324:163-166; Chehab et al. (1987) Nature, 329:293-294; Lungren et al. (1988) Science, 241:1077-1080; Wu et al. (1989) Proc. Natl. Acad. Sci. USA, 86:2757-2760; and Wu et al. (1989) Genomics, 4:560-569. 
     The present invention also provides a kit for determining a polymorphism in the ALA-D gene comprising a means for extracting DNA from a sample obtained from humans, and means for detecting the presence or absence of ALA-D 2  allele in the DNA sample. In addition, the kit may further comprise a means for amplifying the gene encoding ALA-D or a part thereof. 
     Also included in the present invention are recombinant DNA molecules encoding ALA-D 1  and ALA-D 2  and any portion of the ALA-D 1  and ALA-D 2  sequence. Thus, the invention includes any sequence of human ALA-D, including the use of primers that involve intronic sequences. For example, ALA-D 1  or ALA-D 2  sequences involving any domains such as the active site, or any part thereof, the zinc binding site, etc. The complete cDNA sequence of human ALA-D 2  is shown in Table 2. The ALA-D 1  sequence differs only by the presence of a G in the third position of codon 59, thereby encoding a lysine residue in position 59 of the ALA-D 1  polypeptide. The invention also includes a recombinant vector containing some or all of the genomic DNA encoding ALA-D 2 . The nucleotide sequence of the genomic DNA containing all coding exons of ALA-D 2  is shown in Table 3. In Table 3, all the coding exons are shown in upper case letters whereas the introns are shown in lower case letter. 
     The invention further encompasses DNA vectors into which the gene has been cloned and expression systems into which the recombinant vectors have been transferred. Suitable vectors include but are not limited to plasmids, viruses and retroviruses. Suitable expression systems include but are not limited to bacteria, fungi, mamalian cell lines, plant cell lines, insect cell lines and transgenic non-human mammals. 
     Preferably, the recombinant vectors contain an oligonucleotide having some or all of the sequences as shown in Tables 2 and 3. 
     
                                           TABLE 2__________________________________________________________________________THE COMPLETE CDNA SEOUENCE OF HUMAN ALA-D2SEQ ID NO: 3__________________________________________________________________________GAGACCGGAG CGGGAGACAG CGGTGACAGG AGCAGCGGCC GGGAGCCCTT                                 50AGGGAGGCAG ACAGAGCCTG CAGCCAATGC CCCAGGAGCC CTCGGTTCCA                                100ACCAACTGAT GCCCCTGTGC CCACTGGCCC ACGCC ATG CAG CCC CAG                                147TCC GTT CTG CAC AGC GGC TAC TTC CAC CCA CTA CTT CGG GCC                                189TGG CAG ACA GCC ACC ACC ACC CTC AAT GCC TCC AAC CTC ATC                                231TAC CCC ATC TTT GTC ACG GAT GTT CCT GAT GAC ATA CAG CCT                                273ATC ACC AGC CTC CCA GGA GTG GCC AGG TAT GGT GTG AAC CGG                                315CTG GAA GAG ATG CTG AGG CCC TTG GTG GAA GAG GGC CTA CGC                                357TGT GTC TTG ATC TTT GGC GTC CCC AGC AGA GTT CCC AAG GAC                                399GAG CGG GGT TCC GCA GCT GAC TCC GAG GAG TCC CCA GCT ATT                                441GAG GCA ATC CAT CTG TTG AGG AAG ACC TTC CCC AAC CTC CTG                                483GTG GCC TGT GAT GTC TGC CTG TGT CCC TAC ACC TCC CAT GGT                                525CAC TGC GGG CTC CTG AGT GAA AAC GGA GCA TTC CGG GCT GAG                                567GAG AGC CGC CAG CGG CTG GCT GAG GTG GCA TTG GCG TAT GCC                                609AAG GCA GGA TGT CAG GTG GTA GCC CCG TCG GAC ATG ATG GAT                                651GGA CGC GTG GAA GCC ATC AAA GAG GCC CTG ATG GCA CAT GGA                                693CTT GGC AAC AGG GTA TCG GTG ATG AGC TAC AGT GCC AAA TTT                                735GCT TCC TGT TTC TAT GGC CCT TTC CGG GAT GCA GCT AAG TCA                                777AGC CCA GCT TTT GGG GAC CGC CGC TGC TAC CAG CTG CCC CCT                                819GGA GCA CGA GGC CTG GCT CTC CGA GCT GTG GAC CGG GAT GTA                                861CGG GAA GGA GCT GAC ATG CTC ATG GTG AAG CCG GGA ATG CCC                                813TAC CTG GAC ATC GTG CGG GAG GTA AAG GAC AAG CAC CCT GAC                                945CTC CCT CTC GCC GTG TAC CAC GTC TCT GGA GAG TTT GCC ATG                                987CTG TGG CAT GGA GCC CAG GCC GGG GCA TTT GAT CTC AAG GCT                                1029GCC GTA CTG GAG GCC ATG ACT GCC TTC CGC AGA GCA GGT GCT                                1071GAC ATC ATC ATC ACC TAC TAC ACA CCG CAG CTG CTG CAG TGG                                1113CTG AAG GAG GAA TGA TGGAGACAGT GCCAGGCCCA AGAACTAGAA                                1158CTTTAAAACG TTCCCGGGGC CTCAGACAAG TGAAAACCAA AGTAAATGCT                                1208GCTTTTAGAA CTGT                      1222__________________________________________________________________________ 
    
     
                                           TABLE 3__________________________________________________________________________THE COMPLETE GENOMIC DNA SEQUENCE OF ALA-D2SEQ ID NO: 4__________________________________________________________________________-600   gagaccatcc tgggaagcat ggcaagacct ccatctctac aaaaaattcg-550   aaaattagct ggatgttgtg gtgcacacct gcagtcccag ctacttggga-500   ggctgagttg ggagaaacag ttgagcccgg gaggtcaagg ctgcagtgag-450   tcgagattgc accactgcac tccagcctgg gcgacagaga ccctgtgtga-400   aaaaaaaaaa aagaagagaa ttttttttaa acagtcattg cttgctcaga-350   tgtttacttt aaaagataat aatgaacaag aagcagtcac ataaaataca-300   agcccaaatt ttatatcatt agattctgat tgtcatgaaa gtttctaaag-250   acttactttc atttctcaac ttaccttgtt gaccagcagg gattggtgaa-200   ccaggctgtg agtagcattg ggctagagag aggggaggca ggaatctaga-150   agagctgttt tccagatgtg accatctcct gaggacaggg accatgtcct-100   atgtgccacc catcaccccc cacagACAGA GCCTGCAGCC AATGCCCCAG-50   GAGCCCTCGG TTCCAACCAA CTGATGCCCC TGTGCCCACT GGCCCACGCC1  ATGCAGCCCC AGTCCGTTCT GCACAGCGGC TACTTCCACC CACTACTTCG51 GGCCTGGCAG ACAGCCACCA CCACCCTCAA TGCCTCCAAC CTCATCTACC101   CCATCTTTGT CACgtgagtc tccaagaatg ggccaggcct ctgctctgct151   ggttggggtt ggggttgggg agggagtgtt gactggagcg ggcatcagta201   tggctggggg tggcaaagtg agctgtcagc ttgaaattca aggcactgga251   agcaggctac ttggattaag gacaggaatc ttaggaacaa aacaaacttt301   gaaagaactc attcatccca tttggaaaat tagaagaata acccttgcct351   gccatcctga gctcttgcag taagacagaa gctgagaagg tgctctgtac401   attgtaaagt gctatgtacc tgtaagagat ggcagtcatt gaggctgggc451   acggtggctc acgcctgtaa tcccagcact ttgggaggct gaggcaggcg501   gatcacgagg tcaggagatc gagaccatcc tggctaatat ggtgaaaccc551   tgtctctact aaaaacacaa agaaattagc caggcgtggt ggcgggtgcc601   tgtagtccca gctacttggg aggctgaggc aggagaatgg cgtgaacccg651   ggaggcggag cttgcagtga gccgagattg caccacttca ctccagcctg701   ggcgacagag ccagactcca tctcaaaaaa aaaaaaaaaa aaaagagatg751   gcaatcgtga ttgttaataa taatgcagac atttactgag tacttactat801   ctaccaggta ctatgctaag cacctacaca cattatctca ttcaattctg851   agagcatttg tatgaagaag gagtagctat cctctagaac atcagctcca901   tgagggcagg gatgtttgtc tattttgttc actgttgtat catcagggcc951   tagaacagta cttggcacat aataagtact caataaatat ttgttgaatg1001   aatgaattaa ccacgcatga tatagatgaa ggcctaaggc tcaaagagat1051   gatagaactt ggccacggtc acccaggcag taagtggctg ggatagaaag1101   caaggacctg ccaaattcag agtccaagtt cttaaccact taattccttc1151   ctgtaattac cgttctttta gtacagttgc tagtgttgtc actgttattc1201   ttgttgttcc tattattatt tcaggccctg ggcttggcca ggcagggaag1251   ccagacactg gatcccatcc tcctcccacc atctccactt ccatatttct1301   ttcctgcttc ccaaccatcc ctctcagtcg cccccgcacc actggccctt1351   cccacagcta ccaatccata tcccaccccc gctcttgcag GGATGTTCCT1401   GATGACATAC AGCCTATCAC CAGCCTCCCA GGAGTGGCCA Ggtaggagac1451   gtggagttgg ggggccagcg ggtggtggag ggagagattc cacaggtgga1501   agtgctggga ggcagaagca gacctaggaa gtagaagatg cggacagaca1551   gacattagct cagtagagga aagggtttcc ccggggccag agctgttcca1601   cagtggaagg ggcagcccca taaagtaaag agctacccat cacccgagac1651   gtcgtggcag aggctgttgc agaagggagc tgaactgcag atgggagttc1701   aaaaagaggg cctcgaagga gccttccaca gccgaattcc ggagctctgc1751   tactcagggc ctcagtcttc cctcctattt agtggatgca tccctgcccc1801   ttctgtcctg ggggcttgag ccctcctggt gccatatgca gcttggtttc1851   taacagaggc acacagtgtg gtggggtccg gaggaccgtt gcctgggacc1901   tgccttcctt caacccctct acccacaccc acacagGTAC GGTGTGAACC1951   GGCTGGAAGA GATGCTGAGG CCCTTGGTGG AAGAGGGCCT ACGCTGTGTC2001   TTGATCTTTG GCGTCCCCAG CAGAGTTCCC AAGgtgaaga atcaaaggaa2051   gggctaagaa gggaggttgc ctcacgcccg taatcccagc actttgggag2101   gccaaagtgg gtggatcact tgagcccagg attttgagac cagcctggac2151   aacatggcaa aacccatctc tacaaaaaat acaaaagtta .gctgggtgtg2201   ggggtatgtg cctgtagtcc cagctactcg ggaggtggag aggtgggagg2251   attgcttgag cccagaaagt cgaggctgca gtgagccaaa atcgcgccag2301   tgcactctag cctgggtgac agagcaagac cctgtctcca atacaaacag2351   aaaaaggaag ggaggttggg caaaggtgga ctgagggtcc acactgactg2401   caccctcact cccacattgt gctggccctg gggccacagg tgaatggacg2451   tggtctttgc ccttaagtca gcacccatgt agggtcggtc ctctgtgctt2501   ccttatccag gggctgtgat gatgaaggaa ggagaaggcc agggctatgc2551   tctgtgatgg ctgtcatcct gccttccaaa gctacatgta.atagacacac2601   tgctttgtcc ctcccctgcc cctagGACGA GCGGGGTTCC GCAGCTGACT2651   CCGAGGAGTC CCCAGCTATT GAGGCAATCC ATCTGTTGAG GAAGACCTTC2701   CCCAACCTCC TGGTGGCCTG TGATGTCTGC CTGTGTCCCT ACACCTCCCA2751   TGGTCACTGC Ggtgagttcc ctccctccca ccagccctgc tgccacccac2801   actcctactg cccacttctc aacagggtgg ggacagccag ggcccaaggt2851   gctccccaaa acccagtcat ctgtcctgaa gGGCTCCTGA GTGAAAACGG2901   AGCATTCCGG GCTGAGGAGA GCCGCCAGCG GCTGGCTGAG GTGGCATTGG2951   CGTATGCCAA GGCAGgtgag tgaaccacca gcagggatgg gcacctctgg3000   gtcaggaggt ggcagagtgg ctaggagggc cccagagttc tgaaggccac3051   cctctgcccc ccagGATGTC AGGTGGTAGC CCCGTCGGAC ATGATGGATG3101   GACGCGTGGA AGCCATCAAA GAGGCCCTGA TGGCACATGG ACTTGGCAAC3151   AGGgtaaggg cagggaatgc agcacagggc tggcaggaga tagtctgcac3201   cagccctgcc cccgtgtctg ctaagaatca cagaactgcc gggcgtgttg3251   gctcacacct gtagtcccag cactttggga ggctgaggca ggtagatcac3301   ttgaggtcag gggttcaaga ccagcctggc caacatggtg aaaccccatc3351   tctactaaaa acacaaaaat tagctgggcg tggtggcagg cgcctgcaat3401   cccagctact ggggaggctg aggcaggaga atcgcttgaa cccacgaggc3451   agtgagctga gatcatgcca ctgcacttca gcctggatga cagagctaga3501   ctccatctca aaaaaaaaaa gaatcacaga actgaagaca gtgctggatg3551   aggctttggg gaaccattta aacctctggg cctctgcagg gaaatcaagc3601   ccagcactcc aacaggacca gaacacaggc agtctccttc ccagcctagg3651   ttctttctct ccctgccaca tcaccctggg atacctggca agggccgaat3701   aagccaagac ctccattgtc tccccatagG TATCGGTGAT GAGCTACAGT3751   GCCAAATTTG CTTCCTGTTT CTATGGCCCT TTccGgtgag caggggtggg3801   caggggtctg ctgtgaatcc ctgccctttg gcccaaagct ggagcccacc3851   ctgatgactc tgctttgcag GGATGCAGCT AAGTCAAGCC CAGCTTTTGG3901   GGACCGCCGC TGCTACCAGC TGCCCCCTGG AGCACGAGGC CTGGCTCTCC3951   GAGCTGTGgt gagtgactag gacttgagcc ccaccctcag ccccctccta4001   ggcaccaccc acattatacc ctcatccctt agGACCGGGA TGTACGGGAA4051   GGAGCTGACA TGCTCATGGT GAAGCCGGGA ATGCCCTACC TGGACATCGT4101   GCGGGAGGTA AAGGACAAGg tgagcacagg tacgaggcaa agggggctca4151   gggggctggg acagagtttt ccacagactc tggaatctca gagttggaag4201   cagtttgccc ttaagcatgc atcctctcct ccccttccct gcccaggaac4251   catcgtggcc ttctatgtcg gggcttgcac gagcctcaaa cagccctgct4301   ttaacagttcaagagtgggc caggctgcca gccgcagtaa cccaggacac4351   ggggctcaag atggtcacag attgagcagg ggggaaggga cgcttccaga4401   gccacatcca ccctccattt cagcctgtct ccctgtctgc ttccctgcag4451   CACCCTGACC TCCCTCTCGC CGTGTACCAC GTCTCTGGAG AGTTTGCCAT4501   GCTGTGGCAT GGAGCCCAGG CCGGGGCATT TGATCTCAAG GCTGCCGTAC4551   TGGAGGCCAT GACTGCCTTC CGCAGAGCAG gtaggcaggc aagggtgggg4601   tgttttgacc tgcgccacag ggactgataa gcactctgcc tagatcgggg4651   aacgacgtcc tgagagcttg ggatcttatt ccgggaatta ctagtgatct4701   aaacagacac acactgagga agagatatgg aactgcagca tagaacacgg4751   cccggtgaag caagcagagc ccttcatttt tggttgtgag aacgtggcaa4801   gccacttctc tgaacctcag tgtcctcacc cataactgga taactgggga4851   taagatacct ggtgcgtggt tgtcctgagg attaaatgaa gtaatatcac4901   tccataaagg ggactcattt tgttagaatt gcacaccagc atgggaagga4951   acttgcctct tatatttcct tcactgtgca ttttattctt tggtaaactg5001   aggccccaaa agaggaaatg acttgcccaa gaaatagagt ttcccaaagc5os1   tgggctccgt ctcatgtggt gtgcccacag gctgtgcttc ttcatggtag5101   ccttcttccc cgcctggcct tcccatcgca gaaggtgtgc tcagagctga5151   tcagcgtccc cccagcaact ttctgcatct ctcccaacac agGTGCTGAC5201   ATCATCATCA CCTACTACAC ACCGCAGCTG CTGCAGTGGC TGAAGGAGGA5251   ATGATGGAGA CAGTGCCAGG CCCAAGAACT AGAACTTTAA AACGTTCCCG5301   GGGCCTCAGA CAAGTGAAAA CCAAAGTAAA TGCTGCTTTT AGAACTGTgc5351   cctcatgccc tcttcctgct cacatgctag cggggcccag cagccctggg5401   tggttttgcc agcatgctaa ctcttgtaac tcgcagctgc atcctatgag5451   ctctcccaag ctt__________________________________________________________________________ 
    
     Methods of cloning genes in the proper orientation and with the proper flanking sequences, transforming the genes into a suitable host cell and expressing and purifying the proteins are known in the art and examples are provided below. Detailed DNA cloning methods are provided in a variety of sources. See e.g. Sambrook et al., Molecular Cloning A Laboratory Manual, Cold Spring Harbor Laboratory Press, NY, (1989). 
     Gene transfer into an expression system can be accomplished by any of the well known means in the art. For example, methods of gene transfer include but are not limited to CaCl 2  mediated transfection and electroporation in the case of bacteria, and in the case of eukaryotic cells, CaPO 4  mediated transfection, viral infection including retroviral latent infection, electroporation, liposome mediated DNA transfer and microinjection among others. 
     A transgenic non-human mammal, for instance a mouse, carrying either the human ALA-D 1  or ALA-D 2  allele can be used as a model system to determine and compare the contribution of the ALA-D polymorphism to the pathophysiology of lead poisoning, for example, extent of lead uptake, tissue-specific distribution of lead, and tissue-specific inhibition of ALA-D by lead. 
     In an embodiment of this invention a transgenic mammal in which a substantial portion of its germ and somatic cells contain a recombinant activated human ALA-D 1  or ALA-D 2  sequence can be produced as follows. 
     For the purposes of gene transfer experiments, the complete ALA-D 1  and ALA-D 2  genomic sequence including 2.1 kilobase pair (kb) of 5&#39; untranslated sequence should be used. C57BL/6 mice, whose haploid genome contains only one copy of the mouse ALA-D gene, can be used as sources of eggs and sperm for in vitro fertilization, as described by Gordon et al. (1983) Methods Enzymol. 101:411-432 although any suitable method of making transgenic animals is acceptable. Briefly, the 10-14 week old females are superovulated by intraperitoneal injection of 5 I.U. of pregnant mare&#39;s serum followed 48 hours later by 2.5 I.U. of human chorionic gonadotropin. These mice are then sacrificed and the eggs removed. The 10-14 week old males are also sacrificed and the mature sperm harvested from the vas deferens and caudal epididymis. The eggs and sperm are frozen prior to in vitro fertilization. To increase fertilization, zona drilling of each egg is performed using micropuncture techniques. Following in vitro fertilization, the zygotes with prominent pronuclei are selected and loaded into culture dishes containing microdrops of culture medium under mineral oil. Next, the embryos are placed on the stage of a phase contrast microscope and, while being held in place by a suction needle, the human ALA-D genomic DNA is microinjected until swelling of the pronuclei is noticeable. 
     After microinjection of about 100-200 copies of one of the ALA-D alleles, the embryos are returned to the incubator and examined after 1 hour. Survivors are selected and implanted into the oviducts of pseudopregnant females obtained by mating with vasectomized males. After the pups are born, tail clips are used as a source of DNA for Southern hybridization (or PCR amplification) with a unique portion of the first human ALA-D intron which has no homology with the mouse intron. Positive animals are used for breeding. Second generation animals carrying the human ALA-D allele must carry the gene in the germ line. 
     EXAMPLE 1 
     Screening for ALA-D polymorohisms 
     In order to screen for the ALA-D restriction fragment length polymorphisms (RFLP), an 1170 base pair (bp) cDNA isolated from an adult liver cDNA library according to the method described by Wetmur et al., &#34;Human Delta-aminolevulinate Dehydratase: Nucleotide Sequence of a Full-length cDNA Clone&#34;, Proc. Natl. Acad. Sci. USA, 83:7703-7707 (1986), was used as a probe for restriction endonuclease analysis of human lymphoblastoid cell genomic DNA isolated as described in Sambrook et al. (1989) and analyzed using the electrophoresis, transfer and hybridization methods of Southern, &#34;Detection of Specific Sequences Among DNA Fragments Separated by Gel Electrophoresis&#34;, J. Mol. Biol., 98:503-517 (1975). DNA was obtained from over 30 unrelated individuals, digested with more than 20 restriction endonucleases and fragments greater than 1 kb were analyzed by Southern blot analysis. 
     No polymorphism was detected by Southern blot hybridization using a battery of restriction endonucleases with six base recognition sequences. One polymorphism was detected using restriction endonucleases with four base recognition sequences. With RsaI, the presence or absence of the polymorphic site resulted in 2.2 or 3.0 kb fragments respectively. 
     Based on the distribution of Rsa I sites in the ALA-D gene, the RsaI polymorphism was located in Exon 4 (the third coding exon in Table 3), 3.4 kb 5&#39; of the polyadenylation signal and 2.0 kb 3&#39; of the initiation codon. The polymorphism is a single base pair change from T to C at nucleotide 168 of the cDNA coding sequence. This transition does not affect the amino acid sequence of ALA-D). 
     EXAMPLE 2 
     Cloning the ALA-D 2  gene 
     In order to clone the ALA-D 2  gene a cDNA sequence encoding ALA-D 2  was obtained by the following method. RNA was extracted from lymphoblastoid cells of an individual who had been shown to be homozygous for the ALA-D 2  allele by starch gel electrophoresis. The method of Chirgwin et al., (1979) &#34;Isolation of Biologically Active Ribonucleic Acid From Sources Enriched in Ribonuclease&#34;, Biochem., 18:5294-5299 was used with the following modifications: the guanidinium thiocyanate solution contained 25 mM sodium thiocyanate and 0.03% instead of 0.1% Antifoam A; the CsCl solution contained 0.02% instead of 0.2% diethylpyrocarbonate. CDNA synthesis was carried out using the cDNA Synthesis System of BRL, Inc. according to the manufacturer&#39;s instructions. Briefly, 10 mg of total RNA was reverse transcribed into cDNA using oligo-dT as the primer. All oligodeoxynucleotides were synthesized on an Applied Biosystems Model 380B oligonucleotide synthesizer using standard phosphoramidite chemistry according to the manufacturer&#39;s instructions. ALA-D-specific primers for the 5&#39; and 3&#39; untranslated regions of the gene ##STR3## respectively) were synthesized to include 5&#39; EcoRI or HindIII sites, respectively. Amplification of ALA-D cDNA was carried out using the polymerase chain reaction (PCR) according to the method of Saiki et al. (1988) &#34;Primer-directed Enzymatic Amplification of DNA With a Thermostable DNA Polymerase&#34;, Science, 239:487-491. Ten to 12.5 μl of first strand mixture, without prior precipitation, was mixed with ALA-D-specific primers. The cDNA-RNA hybrid was denatured by heating at 100° C. for 5 minutes, then quenching on ice for 5 minutes. 45 cycles of amplification were executed using denaturation at 94° C. for 1 minute, annealing at 53° C. for 1 minute and extension at 72° C. for 3 minutes with the final cycle extended to 10 minutes. PCR was performed using either the GeneAmp DNA Amplification Reagent Kit according to the manufacturer&#39;s instructions (Perkin-Elmer Cetus) or using Taq DNA Polymerase according to the manufacturer&#39;s instructions (Promega) with 1.0 to 2.2 μM primers and 20 μg/ml genomic DNA or 4 ng/ml plasmid DNA template. 
     Following the appropriate methods of Sambrook et al. (1989), the cDNA PCR product was extracted once with phenol:chloroform:isoamyl alcohol (25:24:1), twice with chloroform:isoamyl alcohol (24:1), ethanol precipitated, and digested with EcoRI and HindIII. The digest was heated to 65° C. for 20 minutes, ethanol precipitated, redissolved, ligated into EcoRI and HindIII digested pUC19 (25 μg/ml) and transformed into E. coli DHS using the protocol of Kushner, &#34;Genetic Engineering&#34;, Boyer, Nicosia, eds. Elsevier/North-Holland Biomedical Press, Amsterdam, pp. 17-23 (1978) without dimethylsulfoxide. Colonies not expressing β-galactosidase were propagated, and plasmid DNAs were prepared. T4 DNA ligase, T4 polynucleotide kinase and all restriction endonucleases were purchased from New England Biolabs, Inc. or Promega, Inc. and used according to the manufacturer&#39;s instructions. 
     Double-stranded DNA sequencing of supercoiled plasmid templates was performed according to the instructions in the Sequenase DNA Sequencing Kit of United States Biochemical Corporation, Inc., at least 2 μg of DNA was used in each reaction. The cDNA sequence obtained is presented in Table 2. 
     The ALA-D 2  cDNA sequence obtained showed that a single base pair change of a G to C at position 177 compared to the ALA-D 1  sequence. Wetmur et al. (1986). The transversion results in a change of amino acid 59 from positively charged lysine to neutral asparagine and in the creation of an MspI (CCGG) restriction endonuclease site. In the genomic DNA, the MspI polymorphism is located in exon 4 (the third coding exon in Table 3), only 9 base pairs away from the RsaI polymorphic site described in Example 1 As a result, the same PCR method as described in example 3 can be used to amplify DNA for the determination of the RsaI polymorphism and the presence or absence of the MspI restriction endonuclease site. 
     The only nucleotide sequence difference found between the sequences of the ALA-D 1  and ALA-D 2  alleles corresponds to a change in one predicted amino acid from a positive lysine to a neutral asparagine, which accounts for the difference in the electrophoretic mobilities of the ALA-D 1-1, ALA-D 1-2 and ALA-D 2-2 charge isozymes. 
     EXAMPLE 3 
     Correlation of ALA-D genotype and ALA-D charge isozyme phenotype 
     In order to correlate ALA-D genotype and charge isozyme phenotype, aliquots of residual blood collected with informed consent from patients &amp;&amp;&amp;KEPundergoing Tay-Sachs screening at Mount Sinai and Beth Israel Hospitals in New York City were used for either gel electrophoresis or PCR analysis, or both. Blood samples for analysis by electrophoresis were centrifuged at 1600 rpm in a Sorvall RT6000 for 30 minutes and the plasma and buffy coat were removed. The remaining red blood cells were mixed several times by inverting with one half volume of saline and centrifuged at 1600 rpm for 10 minutes. This erythrocyte washing procedure was repeated. A 0.5 ml sample of packed erythrocytes was mixed with an equal volume of lysis buffer (1 mM KH 2  PO 4  +KOH, pH 6.8, 1 mM MgCl 2 , 1 mM dithiothreitol (DTT) and 0.05% Triton X-100) and centrifuged for 1 minute at 12,000 rpm in a Fisher Model 235C microcentrifuge. Lysed red blood cell samples were frozen until used. 
     The ALA-D isozyme phenotypes were determined following cellulose acetate gel electrophoresis (Cellogel). Lysates (7.5 ml) were diluted into 0.01M phosphate buffer, applied to the gel and separated by electrophoresis for 2 hr at 200 V at 4° C. in 0.1M sodium phosphate, pH 6.8. The cellogel was first incubated in PBS with rabbit polyclonal anti-human ALA-D antibody directed at human ALA-D purified by the method of Anderson and Desnick, &#34;Purification and Properties of delta-aminolevulinate Dehydratase from Human Erythrocytes&#34;, J. Biol. Chem., 254:6924-6930 (1979), then with biotinylated goat anti-rabbit IgG and finally with a preformed avidin and biotinylated horseradish peroxidase complex as described in the Vectastain ABC kit (Vector Laboratories). 
     In order to determine the ALA-D genotype, samples for PCR analysis were prepared by the whole blood protocol as described by Perkin-Elmer, Cetus. Oligodeoxynucleotides were synthesized 5&#39; and 3&#39; to the exon with the ALA-D polymorphisms. The 5&#39; and 3&#39; oligodeoxynucleotide sequences were ##STR4## respectively. The amplification program was the same as described in Example 2 except the annealing temperature was 55° C. 
     PCR products were cleaved with RsaI and/or MspI and analyzed by fluorography following agarose gel electro phoresis with ethidium bromide. The 916 bp PCR product was unaffected by RsaI digestion if the allele was RsaI, but was cleaved into 523 and 393 bp fragments if the allele was RsaI + . The Bluescript SK (Stratagene, Inc.) vector, which contains two RsaI cleavage sites, was added to RsaI-only digestion reactions as a control for incomplete digestion. 
     All blood samples that were determined to be either ALA-D 1-2 or ALA-D 2-2 and eighty seven blood samples that were determined to be ALA-D 1-1 by cellulose acetate gel analysis were further analyzed for ALA-D 1  and ALA-D 2  alleles by MspI cleavage of the PCR products. The 916 bp PCR product was cleaved by MspI digestion into a 582 bp fragment if the allele was ALA-D 1  and into a 511 bp fragment if the allele was ALA-D 2 . The products were analyzed by agarose gel electrophoresis. In all cases of ALA-D 1-2 individuals the expected heterozygote agarose gel pattern was observed. Likewise, MspI cleavage of PCR products from all samples with the ALA-D 2-2 phenotype resulted in a single 511 bp band. Haplotype assignments of RsaI and MspI heterozygotes were made by double-digestion. 
     Analysis of a random population of 428 normal Caucasian individuals revealed that the ALAD 1  (MspI - ) and ALAD 2  (MspI + ) allele frequencies were 0.88 and 0.12, respectively. The allele frequencies for the RsaI -  and RsaI +  alleles in the same population were 0.75 and 0.25, respectively. Individually, the MspI and RsaI RFLPs were in Hardy-Weinberg equilibrium (χ 2  MspI=3.5, df=2, p&gt;0.10; χ 2  RsaI=1.88, df=2, p&gt;0.25). Based on the above frequencies, the expected MspI/RsaI haplotypes would be ALAD 1  (Mspl - )/RsaI + , 0.66; ALAD 1  /RsaI + , 0.22; ALAD 2  /RsaI - , 0.09 and ALAD 2  /RsaI + , 0.03. However, the two RFLPs were in linkage disequilibrium (χ 2  =22, df=1, p&lt;0.001). Of the 259 ALAD 1  alleles studied, 27.4% were RsaI + , whereas only 5% of 101 ALAD 2  alleles were RsaI + . The expected number of ALAD 1  /RsaI+ and ALAD 2  /RsaI+ were each 25%, thus the ALAD 2  /RsaI+ allele was highly underrepresented. 
     The polymorphism information content (PIC) for these haplotypes is 0.45, a reasonably informative (0.5&gt;PIC&gt;0.25) value. Botstein et al., (1980) &#34;Construction and Genetic Linkage Map in Man Using Restriction Fragment Length Polymorphism&#34;, Am. J. Hum. Genet., 32:314-31. 
     Of the samples where ALA-D electrophoretic phenotypes were determined by Cellogel electrophoresis and MspI genotypes all were determined by RFLP analysis, all phenotypes correlated with genotypes. In another unrelated study, one individual was identified by starch gel electrophoresis as having the ALA-D 2-2 isozyme phenotype, but genotype analysis revealed that this individual had one ALA-D 2  allele and one ALA-D 1  allele. Thus, there may be another (other) rare mutation(s) which lead to the same charge isozyme phenotype or, alternatively, this ALA-D 1  allele which does not have the MspI site may not have been expressed. Nevertheless, the observed nucleotide substitution results in both the MspI RFLP and the polymorphic ALA-D charge isozymes in the vast majority of individuals. 
     
         __________________________________________________________________________SEQUENCE LISTING(1) GENERAL INFORMATION:(iii) NUMBER OF SEQUENCES: 6(2) INFORMATION FOR SEQ ID NO: 1:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 20 BASES(B) TYPE: NUCLEIC ACID(C) STRANDEDNESS: SINGLE(D) TOPOLOGY: LINEAR(ii) MOLECULE TYPE:(A) DESCRIPTION: OTHER NUCLEIC ACID, SYNTHETIC(iii) HYPOTHETICAL: NO(iv) ANTI-SENSE: NO(vii) IMMEDIATE SOURCE:(A) LIBRARY: SYNTHETIC(x) PUBLICATION INFORMATION: NONE(xi) SEQUENCE DESCRIPTION: SEQ ID NO:1:AGACAGACATTAGCTCAGTA20(2) INFORMATION FOR SEQ ID NO: 2:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 20 BASES(B) TYPE: NUCLEIC ACID(C) STRANDEDNESS: SINGLE(D) TOPOLOGY: LINEAR(ii) MOLECULE TYPE:(A) DESCRIPTION: OTHER NUCLEIC ACID/SYNTHETIC(iii) HYPOTHETICAL: NO(iv) ANTI-SENSE: NO(vii) IMMEDIATE SOURCE:(A) LIBRARY: SYNTHETIC(x) PUBLICATION INFORMATION: NONE(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 2:GGCAAAGACCACGTCCATTC20(2) INFORMATION FOR SEQ ID NO: 3:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 1222 BASE PAIRS(B) TYPE: NUCLEIC ACID(C) STRANDEDNESS: DOUBLE(D) TOPOLOGY: LINEAR(ii) MOLECULE TYPE:(A) DESCRIPTION: cDNA TO mRNA(iii) HYPOTHETICAL: NO(iv) ANTI-SENSE: NO(vi) ORIGINAL SOURCE:(A) ORGANISM: HUMAN(F) TISSUE TYPE: LYMPHOBLASTOID CELLS(vii) IMMEDIATE SOURCE:(A) LIBRARY: cDNA(ix) FEATURE:(D) OTHER INFORMATION: GENE PRODUCT IS k-AMINO LEVULINATEDEHYDRATASE(x) PUBLICATION INFORMATION: NONE(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 3:GAGACCGGAGCGGGAGACAGCGGTGACAGGAGCAGCGGCCGGGAGCCCTT50AGGGAGGCAGACAGAGCCTGCAGCCAATGCCCCAGGAGCCCTCGGTTCCA100ACCAACTGATGCCCCTGTGCCCACTGGCCCACGCCATGCAGCCCCAG147TCCGTTCTGCACAGCGGCTACTTCCACCCACTACTTCGGGCC189TGGCAGACAGCCACCACCACCCTCAATGCCTCCAACCTCATC231TACCCCATCTTTGTCACGGATGTTCCTGATGACATACAGCCT273ATCACCAGCCTCCCAGGAGTGGCCAGGTATGGTGTGAACCGG315CTGGAAGAGATGCTGAGGCCCTTGGTGGAAGAGGGCCTACGC357TGTGTCTTGATCTTTGGCGTCCCCAGCAGAGTTCCCAAGGAC399GAGCGGGGTTCCGCAGCTGACTCCGAGGAGTCCCCAGCTATT441GAGGCAATCCATCTGTTGAGGAAGACCTTCCCCAACCTCCTG483GTGGCCTGTGATGTCTGCCTGTGTCCCTACACCTCCCATGGT525CACTGCGGGCTCCTGAGTGAAAACGGAGCATTCCGGGCTGAG567GAGAGCCGCCAGCGGCTGGCTGAGGTGGCATTGGCGTATGCC609AAGGCAGGATGTCAGGTGGTAGCCCCGTCGGACATGATGGAT651GGACGCGTGGAAGCCATCAAAGAGGCCCTGATGGCACATGGA693CTTGGCAACAGGGTATCGGTGATGAGCTACAGTGCCAAATTT735GCTTCCTGTTTCTATGGCCCTTTCCGGGATGCAGCTAAGTCA777AGCCCAGCTTTTGGGGACCGCCGCTGCTACCAGCTGCCCCCT819GGAGCACGAGGCCTGGCTCTCCGAGCTGTGGACCGGGATGTA861CGGGAAGGAGCTGACATGCTCATGGTGAAGCCGGGAATGCCC903TACCTGGACATCGTGCGGGAGGTAAAGGACAAGCACCCTGAC945CTCCCTCTCGCCGTGTACCACGTCTCTGGAGAGTTTGCCATG987CTGTGGCATGGAGCCCAGGCCGGGGCATTTGATCTCAAGGCT1029GCCGTACTGGAGGCCATGACTGCCTTCCGCAGAGCAGGTGCT1071GACATCATCATCACCTACTACACACCGCAGCTGCTGCAGTGG1113CTGAAGGAGGAATGATGGAGACAGTGCCAGGCCCAAGAACTAGAA1158CTTTAAAACGTTCCCGGGGCCTCAGACAAGTGAAAACCAAAGTAAATGCT1208GCTTTTAGAACTGT1222(2) INFORMATION FOR SEQ ID NO: 4:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 6063(B) TYPE: NUCLEIC ACID(C) STRANDEDNESS: DOUBLE(D) TOPOLOGY: LINEAR(ii) MOLECULE TYPE:(A) DESCRIPTION: GENOMIC DNA(iii) HYPOTHETICAL: YES(iv) ANTI-SENSE: NO(ix) FEATURE:(D) OTHER INFORMATION: GENE PRODUCT IS k-AMINO LEVULINATEDEHYDRATASE(x) PUBLICATION INFORMATION: NONE(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 4:GAGACCATCCTGGGAAGCATGGCAAGACCTCCATCTCTACAAAAAATTCG50AAAATTAGCTGGATGTTGTGGTGCACACCTGCAGTCCCAGCTACTTGGGA100GGCTGAGTTGGGAGAAACAGTTGAGCCCGGGAGGTCAAGGCTGCAGTGAG150TCGAGATTGCACCACTGCACTCCAGCCTGGGCGACAGAGACCCTGTGTGA200AAAAAAAAAAAAGAAGAGAATTTTTTTTAAACAGTCATTGCTTGCTCAGA250TGTTTACTTTAAAAGATAATAATGAACAAGAAGCAGTCACATAAAATACA300AGCCCAAATTTTATATCATTAGATTCTGATTGTCATGAAAGTTTCTAAAG350ACTTACTTTCATTTCTCAACTTACCTTGTTGACCAGCAGGGATTGGTGAA400CCAGGCTGTGAGTAGCATTGGGCTAGAGAGAGGGGAGGCAGGAATCTAGA450AGAGCTGTTTTCCAGATGTGACCATCTCCTGAGGACAGGGACCATGTCCT500ATGTGCCACCCATCACCCCCCACAGACAGAGCCTGCAGCCAATGCCCCAG550GAGCCCTCGGTTCCAACCAACTGATGCCCCTGTGCCCACTGGCCCACGCC600ATGCAGCCCCAGTCCGTTCTGCACAGCGGCTACTTCCACCCA642CTACTTCGGGCCTGGCAGACAGCCACCACCACCCTCAATGCC684TCCAACCTCATCTACCCCATCTTTGTCACGTGAGTCTCC723AAGAATGGGCCAGGCCTCTGCTCTGCTGGTTGGGGTTGGGGTTGGGGAGG773GAGTGTTGACTGGAGCGGGCATCAGTATGGCTGGGGGTGGCAAAGTGAGC823TGTCAGCTTGAAATTCAAGGCACTGGAAGCAGGCTACTTGGATTAAGGAC873AGGAATCTTAGGAACAAAACAAACTTTGAAAGAACTCATTCATCCCATTT923GGAAAATTAGAAGAATAACCCTTGCCTGCCATCCTGAGCTCTTGCAGTAA973GACAGAAGCTGAGAAGGTGCTCTGTACATTGTAAAGTGCTATGTACCTGT1023AAGAGATGGCAGTCATTGAGGCTGGGCACGGTGGCTCACGCCTGTAATCC1073CAGCACTTTGGGAGGCTGAGGCAGGCGGATCACGAGGTCAGGAGATCGAG1123ACCATCCTGGCTAATATGGTGAAACCCTGTCTCTACTAAAAACACAAAGA1173AATTAGCCAGGCGTGGTGGCGGGTGCCTGTAGTCCCAGCTACTTGGGAGG1223CTGAGGCAGGAGAATGGCGTGAACCCGGGAGGCGGAGCTTGCAGTGAGCC1273GAGATTGCACCACTTCACTCCAGCCTGGGCGACAGAGCCAGACTCCATCT1323CAAAAAAAAAAAAAAAAAAAAGAGATGGCAATCGTGATTGTTAATAATAA1373TGCAGACATTTACTGAGTACTTACTATCTACCAGGTACTATGCTAAGCAC1423CTACACACATTATCTCATTCAATTCTGAGAGCATTTGTATGAAGAAGGAG1473TAGCTATCCTCTAGAACATCAGCTCCATGAGGGCAGGGATGTTTGTCTAT1523TTTGTTCACTGTTGTATCATCAGGGCCTAGAACAGTACTTGGCACATAAT1573AAGTACTCAATAAATATTTGTTGAATGAATGAATTAACCACGCATGATAT1623AGATGAAGGCCTAAGGCTCAAAGAGATGATAGAACTTGGCCACGGTCACC1673CAGGCAGTAAGTGGCTGGGATAGAAAGCAAGGACCTGCCAAATTCAGAGT1723CCAAGTTCTTAACCACTTAATTCCTTCCTGTAATTACCGTTCTTTTAGTA1773CAGTTGCTAGTGTTGTCACTGTTATTCTTGTTGTTCCTATTATTATTTCA1823GGCCCTGGGCTTGGCCAGGCAGGGAAGCCAGACACTGGATCCCATCCTCC1873TCCCACCATCTCCACTTCCATATTTCTTTCCTGCTTCCCAACCATCCCTC1923TCAGTCGCCCCCGCACCACTGGCCCTTCCCACAGCTACCAATCCATATCC1973CACCCCCGCTCTTGCAGGGATGTTCCTGATGACATACAGCCTA2016TCACCAGCCTCCCAGGAGTGGCCAGGTAGGAGACGTGGAGTTGGG2061GGGCCAGCGGGTGGTGGAGGGAGAGATTCCACAGGTGGAAGTGCTGGGAG2111GCAGAAGCAGACCTAGGAAGTAGAAGATGCGGACAGACAGACATTAGCTC2161AGTAGAGGAAAGGGTTTCCCCGGGGCCAGAGCTGTTCCACAGTGGAAGGG2211GCAGCCCCATAAAGTAAAGAGCTACCCATCACCCGAGACGTCGTGGCAGA2261GGCTGTTGCAGAAGGGAGCTGAACTGCAGATGGGAGTTCAAAAAGAGGGC2311CTCGAAGGAGCCTTCCACAGCCGAATTCCGGAGCTCTGCTACTCAGGGCC2361TCAGTCTTCCCTCCTATTTAGTGGATGCATCCCTGCCCCTTCTGTCCTGG2411GGGCTTGAGCCCTCCTGGTGCCATATGCAGCTTGGTTTCTAACAGAGGCA2461CACAGTGTGGTGGGGTCCGGAGGACCGTTGCCTGGGACCTGCCTTCCTTC2511AACCCCTCTACCCACACCCACACAGGTACGGTGTGAACCGGCTGG2556AAGAGATGCTGAGGCCCTTGGTGGAAGAGGGCCTACGCTGTG2598TCTTGATCTTTGGCGTCCCCAGCAGAGTTCCCAAG2633GTGAAGAATCAAAGGAAGGGCTAAGAAGGGAGGTTGCCTCACGCCCGTAA2683TCCCAGCACTTTGGGAGGCCAAAGTGGGTGGATCACTTGAGCCCAGGATT2733TTGAGACCAGCCTGGACAACATGGCAAAACCCATCTCTACAAAAAATACA2783AAAGTTAGCTGGGTGTGGGGGTATGTGCCTGTAGTCCCAGCTACTCGGGA2833GGTGGAGAGGTGGGAGGATTGCTTGAGCCCAGAAAGTCGAGGCTGCAGTG2883AGCCAAAATCGCGCCAGTGCACTCTAGCCTGGGTGACAGAGCAAGACCCT2933GTCTCCAATACAAACAGAAAAAGGAAGGGAGGTTGGGCAAAGGTGGACTG2983AGGGTCCACACTGACTGCACCCTCACTCCCACATTGTGCTGGCCCTGGGG3033CCACAGGTGAATGGACGTGGTCTTTGCCCTTAAGTCAGCACCCATGTAGG3083GTCGGTCCTCTGTGCTTCCTTATCCAGGGGCTGTGATGATGAAGGAAGGA3133GAAGGCCAGGGCTATGCTCTGTGATGGCTGTCATCCTGCCTTCCAAAGCT3183ACATGTAATAGACACACTGCTTTGTCCCTCCCCTGCCCCTAGGACG3229AGCGGGGTTCCGCAGCTGACTCCGAGGAGTCCCCAGCTATTG3271AGGCAATCCATCTGTTGAGGAAGACCTTCCCCAACCTCCTGG3313TGGCCTGTGATGTCTGCCTGTGTCCCTACACCTCCCATGGTC3355ACTGCGGTGAGTTCCCTCCCTCCCACCAGCCCTGCTGCCACCCACA3401CTCCTACTGCCCACTTCTCAACAGGGTGGGGACAGCCAGGGCCCAAGGTG3451CTCCCCAAAACCCAGTCATCTGTCCTGAAGGGCTCCTGAGTGAAA3496ACGGAGCATTCCGGGCTGAGGAGAGCCGCCAGCGGCTGGCTG3538AGGTGGCATTGGCGTATGCCAAGGCAGGTGAGTGAAC3575CACCAGCAGGGATGGGCACCTCTGGGTCAGGAGGTGGCAGAGTGGCTAG3624GAGGGCCCCAGAGTTCTGAAGGCCACCCTCTGCCCCCCAGGATGTCAGG3673TGGTAGCCCCGTCGGACATGATGGATGGACGCGTGGAAGCCA3715TCAAAGAGGCCCTGATGGCACATGGACTTGGCAACAGG3753GTAAGGGCAGGGAATGCAGCACAGGGCTGGCAGGAGATAGTCTGCACCAG3803CCCTGCCCCCGTGTCTGCTAAGAATCACAGAACTGCCGGGCGTGTTGGCT3853CACACCTGTAGTCCCAGCACTTTGGGAGGCTGAGGCAGGTAGATCACTTG3903AGGTCAGGGGTTCAAGACCAGCCTGGCCAACATGGTGAAACCCCATCTCT3953ACTAAAAACACAAAAATTAGCTGGGCGTGGTGGCAGGCGCCTGCAATCCC4003AGCTACTGGGGAGGCTGAGGCAGGAGAATCGCTTGAACCCACGAGGCAGT4053GAGCTGAGATCATGCCACTGCACTTCAGCCTGGATGACAGAGCTAGACTC4103CATCTCAAAAAAAAAAAGAATCACAGAACTGAAGACAGTGCTGGATGAGG4153CTTTGGGGAACCATTTAAACCTCTGGGCCTCTGCAGGGAAATCAAGCCCA4203GCACTCCAACAGGACCAGAACACAGGCAGTCTCCTTCCCAGCCTAGGTTC4253TTTCTCTCCCTGCCACATCACCCTGGGATACCTGGCAAGGGCCGAATAAG4303CCAAGACCTCCATTGTCTCCCCATAGGTATCGGTGATGAGCT4345ACAGTGCCAAATTTGCTTCCTGTTTCTATGGCCCTTTCCG4385GTGAGCAGGGGTGGGCAGGGGTCTGCTGTGAATCCCTGCCCTTTGGCCCA4435AAGCTGGAGCCCACCCTGATGACTCTGCTTTGCAGGGATGCAGCTA4481AGTCAAGCCCAGCTTTTGGGGACCGCCGCTGCTACCAGCTGC4523CCCCTGGAGCACGAGGCCTGGCTCTCCGAGCTGTG4558GTGAGTGACTAGGACTTGAGCCCCACCCTCAGCCCCCTCCTAGGCACCAC4608CCACATTATACCCTCATCCCTTAGGACCGGGATGTACGGGAAG4651GAGCTGACATGCTCATGGTGAAGCCGGGAATGCCCTACCTGG4693ACATCGTGCGGGAGGTAAAGGACAAGGTGAGCACAG4729GTACGAGGCAAAGGGGGCTCAGGGGGCTGGGACAGAGTTTTCCACAGACT4779CTGGAATCTCAGAGTTGGAAGCAGTTTGCCCTTAAGCATGCATCCTCTCC4829TCCCCTTCCCTGCCCAGGAACCATCGTGGCCTTCTATGTCGGGGCTTGCA4879CGAGCCTCAAACAGCCCTGCTTTAACAGTTCAAGAGTGGGCCAGGCTGCC4929AGCCGCAGTAACCCAGGACACGGGGCTCAAGATGGTCACAGATTGAGCAG4979GGGGGAAGGGACGCTTCCAGAGCCACATCCACCCTCCATTTCAGCCTGTC5029TCCCTGTCTGCTTCCCTGCAGCACCCTGACCTCCCTCTCGCCG5072TGTACCACGTCTCTGGAGAGTTTGCCATGCTGTGGCATG5111GAGCCCAGGCCGGGGCATTTGATCTCAAGGCTGCCGTAC5150TGGAGGCCATGACTGCCTTCCGCAGAGCAGGTAGGCAGGC5190AAGGGTGGGGTGTTTTGACCTGCGCCACAGGGACTGATAAGCACTCTGCC5240TAGATCGGGGAACGACGTCCTGAGAGCTTGGGATCTTATTCCGGGAATTA5290CTAGTGATCTAAACAGACACACACTGAGGAAGAGATATGGAACTGCAGCA5340TAGAACACGGCCCGGTGAAGCAAGCAGAGCCCTTCATTTTTGGTTGTGAG5390AACGTGGCAAGCCACTTCTCTGAACCTCAGTGTCCTCACCCATAACTGGA5440TAACTGGGGATAAGATACCTGGTGCGTGGTTGTCCTGAGGATTAAATGAA5490GTAATATCACTCCATAAAGGGGACTCATTTTGTTAGAATTGCACACCAGC5540ATGGGAAGGAACTTGCCTCTTATATTTCCTTCACTGTGCATTTTATTCTT5590TGGTAAACTGAGGCCCCAAAAGAGGAAATGACTTGCCCAAGAAATAGAGT5640TTCCCAAAGCTGGGCTCCGTCTCATGTGGTGTGCCCACAGGCTGTGCTTC5690TTCATGGTAGCCTTCTTCCCCGCCTGGCCTTCCCATCGCAGAAGGTGTGC5740TCAGAGCTGATCAGCGTCCCCCCAGCAACTTTCTGCATCTCTCCCAACAC5790AGGTGCTGACATCATCATCACCTACTACACACCGCAGCTGC5831TGCAGTGGCTGAAGGAGGAATGATGGAGACAGTGCCAGGCCC5873AAGAACTAGAACTTTAAAACGTTCCCGGGGCCTCAGACAAGT5915GAAAACCAAAGTAAATGCTGCTTTTAGAACTGTGCCCTCATGC5958CCTCTTCCTGCTCACATGCTAGCGGGGCCCAGCAGCCCTGGGTGGTTTTG6008CCAGCATGCTAACTCTTGTAACTCGCAGCTGCATCCTATGAGCTCTCCCA6058AGCTT6063(2) INFORMATION FOR SEQ ID NO: 5:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 20(B) TYPE: NUCLEIC ACID(C) STRANDEDNESS: SINGLE(D) TOPOLOGY: LINEAR(ii) MOLECULE TYPE:(A) DESCRIPTION: OTHER/SYNTHETIC(iii) HYPOTHETICAL: NO(iv) ANTI-SENSE: NO(x) PUBLICATION INFORMATION: NONE(xi) SEQUENCE DESCRIPTION: SEQ ID NO:5:AGACAGACATTAGCTCAGTA20(2) INFORMATION FOR SEQ ID NO: 6:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 20(B) TYPE: NUCLEIC ACID(C) STRANDEDNESS: SINGLE(D) TOPOLOGY: LINEAR(ii) MOLECULE TYPE:(A) DESCRIPTION: OTHER/SYNTHETIC(iii) HYPOTHETICAL: NO(iv) ANTI-SENSE: NO(x) PUBLICATION INFORMATION: NONE(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 6:GGCAAAGACCACGTCCATTC20__________________________________________________________________________