Abstract:
CD46 (membrane cofactor protein) is a family of human cell surface glycoprotein with cofactor activity for factor I mediated cleavage of complement components C3b and C4b. Disclosed are novel nucleic acid sequences arising from splice variants or derivatives thereof of the structural gene encoding the family of proteins. From these sequences recombinant derived proteins and antibodies thereto can be produced. The proteins can resemble native CD46 isoforms or comprise new permutations of exons within the structural gene. The nucleic acids, proteins and antibodies have utility as probes, diagnostic reagents and therapeutic agents.

Description:
This application is a continuation-in-part of application Ser. No. 07/961,686, filed Jan. 11, 1993, abandoned (which is the National Phase of PCT/AU91/00199 filed on May 10, 1991. 
    
    
     BACKGROUND OF THE INVENTION 
     This invention generally relates to the protein CD46, a molecule that exists on the surface of almost all human cells to protect them from destruction by the normal immune processes. The invention also relates to nucleic acid encoding CD46, and vectors and cells containing such nucleic acid. 
     SUMMARY OF THE INVENTION 
     The human immune system operates on several levels of specificity and efficiency to identify and eliminate foreign organisms and substances without damaging or destroying normal (or autologous) cells. The complement proteins in serum form a relatively non-specific arm of immunity that plays a leading role in the initial detection, destruction and removal of foreign substances, and in triggering the specific arms of the immune response; formation of antibody and cell-mediated immunity and inflammation mediated responses. The complement proteins also play an important role in the later phases of an immune response by facilitating the phagocytosis of debris and the transport of immune-complexes and macromolecular debris to the liver or spleen for further processing and destruction. The central molecule in the complement system is C3b which aggregates in increasing amounts on foreign substances or organisms tagging them for removal. The complement precursor proteins are activated to form C3b in two ways: (i) by interacting with antibody bound to the foreign target (the classical pathway) or (ii) non-specifically, by progressive and rapidly increasing accumulation on foreign surfaces (the alternative pathway). In order to control this process of complement activation and protect normal cells and tissues from indiscriminate destruction, a family of cell-surface molecules have evolved that interact with C3b molecules; these are: 
     (i) CD46 (also known as membrane cofactor protein  MCP!) which exists on all normal human cells, except red blood cells, and binds to C3b and activates molecules that cleave C3b into inactive fragments before it can accumulate sufficiently to destroy the cell. 
     (ii) CD55 (also known as decay accelerating factor  DAF!) which exists on all cells, including red blood cells, and prevents C3b from reacting with other complement components preventing the destructive processes, however, unlike CD46, this does not destroy C3b. 
     (iii) CD35 (or complement receptor 1  CR1!) which exists on a select group of leukocytes and causes the degradation of C3b molecules adhering to neighbouring cells. 
     CD46 and CD55 (MCP and DAF) are the predominant molecules protecting normal autologous tissues from complement-mediated destruction. The absence of these C3b receptors on foreign cells or substances labels them as foreign and promotes their destruction. 
     Leukaemia cells and other malignant tumour cells express a greatly elevated level of CD46 at their surface which is biochemically and structurally different (but still related to CD46) on the corresponding non-malignant cell. The surface molecules of primate retroviruses that cause leukaemia and AIDS, the gibbon ape leukaemia (GaLV) and Mason-Pfizer monkey (MPMV) viruses, have a structural-protein component that resembles CD46 as demonstrated by the binding of the monoclonal antibody E4.3 (the benchmark reagent defining CD46) to these viral molecules. The existence of these altered (or mimicked) versions of CD46 in high levels on tumour cells and viruses is likely to enhance their evasion of complement-mediated immunity. 
     CD46 also appears to play an important role in human reproduction as human spermatozoa express high levels of a novel form of CD46 at the surface after the acrosome reaction. This occurs prior to fusion of sperm with the oocyte. CD46 molecules are also secreted extracellularly from the spermatozoa after the acrosome reaction. These findings suggest that CD46 plays an important role in the process of fertilization and recombinant (synthetic) CD46 may facilitate the process of fertilization. 
     The layer of syncytiotrophoblast cells in the placenta, the interface between the mother and the antigenically different fetus, expresses higher levels of CD46 than any other tissue. CD46 is the same as the TLX molecule identified by reproductive immunologists as a crucial molecule protecting the non-identical fetus tissues from immune-rejection by the mother. It is possible that in addition to the ability to regulate the activation of complement, CD46 dampens the specific immune responses, even the strong response to genetically different cells. 
     CD46 is thus an important molecule regulating the immune response and may have a role in preventing complement-mediated tissue damage, to enhance immunity to tumours and viruses, to control the process of fertilization, to prevent recurrent spontaneous abortion of the fetus during pregnancy, and to facilitate the engrafting of transplanted tissues. 
     The CD46 polypeptide has been identified by gel electrophoresis as a heterogenous group of glycoproteins resolving in two diffuse bands known as the α and β chains, having molecular weight of 56,000 and 60,000 daltons respectively, which are not linked by disulphide bonds. The α and β chains of CD46 have been shown to have the same N-terminal amino acid sequence. It has previously been thought that the differences between the α and β chain may be due to glycosylation differences. 
     This invention arises from the surprising discovery that there are at least fourteen RNA splice variants encoding CD46 molecules. As will be hereinafter described, the various CD46 splice variants have a conserved N-terminus but different protein sequences at the carboxyl-terminal end. 
     Broadly speaking, the invention encompasses a recombinant nucleic acid encoding a CD46 isoform, the nucleic acid comprising a splice variant of the structural gene encoding the CD46 family of proteins with the proviso that the splice variant does not consist of exons 1 to 6, 8 to 12 and 14 (as herein defined) of the structural gene. The invention thus excludes the published sequence of MCP appearing in Lublin et al. (1988) J. Exp. Med., 168, 181-184. 
     In accordance with one aspect of this invention there is provided a recombinant nucleic acid encoding a CD46 isoform or derivative, wherein the nucleic acid; 
     (a) comprises a portion of the sequence depicted in FIGS. 1a-1d (SEQ ID NO:1), including addition, substitution and deletion derivatives of the sequence not deleteriously affecting the CD46 character of the sequence; 
     (b) comprises at least one exon or a substantial portion of at least one exon from amongst exon numbers 7 to 14 of FIG. 1; with the proviso that 
     (c) the nucleic acid does not consist of the combination of exons 1 to 6, 8 to 12 and 14. 
     The exon structure and assignment of the sequence of FIGS. 1a-1d is discussed in more detail in Examples 4 to 7 which follow. Briefly, the sequence depicted in FIGS. 1a-1d (SEQ ID NO:1) corresponds to a leader peptide encoded by a single exon (exon 1), four extracellular short consensus repeat (SCR) domains (characteristic of the family of complement regulating proteins as described by Lublin et al. (1988) J. Exp. Med. 168, 181-194) encoded by exons 2-6, an extracellular region rich in Ser Thr and Pro residues (STP) encoded by exons 7 to 9, a short region of unknown significance (exon 10), a hydrophobic membrane spanning region (TM) encoded by exons 11 and 12 and a short cytoplasmic tail (CYT) encoded either by exon 13 or exon 14, each of which contain a stop codon. 
     Some embodiments of nucleic acid in accordance with this invention correspond to spliced variants of mRNA encoded by the structural gene-encoding CD46. The term &#34;nucleic acid&#34; as used herein generally refers to DNA, such as cDNA. However, this term also embraces mRNA. Nucleic acid encoding CD46 isoforms or derivatives specifically excludes the known nucleotide sequence encoding the protein known as MCP, which we have now found corresponds to nucleic acid encoding a specific CD46 variant referred to herein as pm5.10 (see FIG. 3, SEQ ID NO:7). Nucleic acid encoding CD46 may refer only to those sequences which encode amino-acids of a CD46 isoform or derivative, or may refer to a nucleic acid containing both coding and non-coding sequences, such as 3&#39; and 5&#39; untranslated sequences. 
     The nucleic acid of the invention is however not limited to sequences which are alternatively spliced to encode whole native CD46 proteins. Smaller nucleic acid sequences produced by deletion of further exons during RNA splicing or by alternative truncating techniques within exons (such as with stop codons introduced by site directed mutagenesis or with restriction endonucleases) will also be useful as will variants in which native splicing boundaries are overrun allowing expression of intron sequences to be appended to the CD46 isoform. Generally, however, at least a substantial portion (i.e. 50% of the bases) of one or more of exons 7 to 14 is present. 
     In particular a sequence coding for one or more of the SCR regions but not including, or with much truncated, transmembrane or cytoplasmic domains may produce a soluble CD46, analogous to the soluble CR1 proteins described in Weisman et al, Science 249 146-151 (1990). It should be noted that soluble CD46 variants have been observed in seminal fluid, saliva and serum and these isoforms appear to have a role in fertilization at least, perhaps by mopping up free complement thereby preventing sperm lysis. Relatively short CD46 derivatives, even those having the SCR regions deleted, may be useful to raise antibodies against particular native CD46 variants, thus creating the basis for tissue specific &#34;magic bullets&#34;. 
     Alternatively a nucleic acid somewhat shorter than those encoding native CD46 variants will find utility as probes or as antisense therapeutic agents to disrupt expression of particular CD46 variants. Useful nucleic acid fragments of the sequence of FIG. 1 will generally contain 10 or more nucleotides but will be longer depending on the degree of homology and stringency conditions desired. A probe will typically comprise a segment of the nucleic acid sequence of FIGS. 1a-1d (SEQ ID NO:1) (including variants not deleteriously affecting the CD46 character of the relevant segment) and a detectable marker such as a fluorophore, radioisotope, gold, biotin etc. A representative use for such a probe is the diagnosis of leukaemia. As can be seen in the following examples we have shown that exon 7 may be uniquely expressed in leukaemia and Epstein Barr virus transformed cells, providing a distinctive target for diagnosis or therapy. 
     For example, antibodies whose specificity was directed to exon 7 gene products would react preferentially with leukaemic cells rather than normal tissues which have a lower expression of this site. In a similar way reagents could diagnose the presence of either the cells or secreted products from these cells which could be used in diagnostic procedures. This unique sequence could be used for both diagnosis and therapy. In addition, antisense oligonucleotides directed selectively to this exon could inhibit the production not only of this exon but of the whole molecule. Such cells would then not express CD46 and could be susceptible to lysis by complement and lead to selective destruction of tumours. 
     The polynucleotides, including DNA and RNA, and polypeptides of the present invention are preferably isolated. The term &#34;isolated&#34; in the context of the present invention denotes a separation of the polynucleotides and polypeptides from its original source or surroundings. 
     Preferably, the polynucleotides and polypeptides are brought to a more purified state. That is, the polynucleotides and polypeptides are substantially free of contaminants that otherwise would be present. Typically, the presence of contaminating nucleic acids and proteins are eliminated or greatly reduced. 
     The polynucleotides and polypeptides of the present invention can be purified by a variety of techniques, including gel electrophoresis (agarose or SDS-PAGE), isoelectric focusing, ion exchange chromatography, gel exclusion chromatography, affinity chromatography, immunoprecipitation, and combinations thereof. 
     The present invention is not limited to the exact nucleotide and amino acid sequences set forth herein. For example, the skilled artisan relying upon this specification can make changes in nucleotide sequences based upon the degeneracy of the genetic code. Furthermore, other changes in the amino acid sequence of the CD46 molecule and variants are contemplated in the present invention. The CD46 molecule and variants can be altered by changing the DNA encoding the protein. Preferably, only conservative amino acid alterations, using amino acids that have the same or similar properties, are undertaken. Illustrative amino acid substitutions include the changes of: alanine to serine; arginine to lysine; asparagine to glutamine or histidine; aspartate to glutamate; cysteine to serine; glutamine to asparagine; glutamate to aspartate; glycine to proline; histidine to asparagine or glutamine; isoleucine to leucine or valine; leucine to valine or isoleucine; lysine to arginine, glutamine, or glutamate; methionine to leucine or isoleucine; phenylalanine to tyrosine, leucine or methionine; serine to threonine; threonine to serine; tryptophan to tyrosine; tyrosine to tryptophan or phenylalanine; valine to isoleucine or leucine. 
     Additionally, other variants and fragments of the CD46 molecule can be made according to the present invention. These variants include analogs, homologs, derivatives, muteins and mimetics of the CD46 protein that retain the ability to cause the beneficial results described herein. Fragments of the CD46 molecule refer to portions of the amino acid sequence of the CD46 molecule that also retain this ability. Other CD46 variants and fragments can be generated directly from the CD46 molecule, or variants described herein, by chemical modification, by proteolytic enzyme digestion, or by combinations thereof. Additionally, genetic engineering techniques, as well as methods of synthesizing polypeptides directly from amino acid residues, can be employed. 
     Non-peptide compounds that mimic the binding and function of the CD46 molecule and variants, referred to as &#34;mimetics,&#34; can be produced by the approach outlined in Saragovi et al., Science 253: 792-95 (1991). Mimetics are molecules which mimic elements of protein secondary structure. See, for example, Johnson et al., &#34;Peptide Turn Mimetics&#34; in BIOTECHNOLOGY AND PHARMACY, Pezzuto et al., Eds., (Chapman and Hall, New York, 1993). The underlying rationale behind the use of peptide mimetics is that the peptide backbone of proteins exists chiefly to orient amino acid side chains in such a way as to facilitate molecular interactions. For the purposes of the present invention, appropriate mimetics can be considered to be the equivalent of the CD46 molecule and variants thereof. 
     Nucleic acid falling within the invention include those encoding a CD46 C-terminal variant and include the following: 
     PM5.1--a nucleic acid encoding a protein of about 377 amino acids, and being characterised by having: 
     (i) a first region encoding four contiguous substantially homologous units of approximately 60 amino acids and referred to as SCR (short consensus repeats); 
     (ii) a second region encoding a serine-threonine rich sequence of approximately 45 amino acids; 
     (iii) a third region encoding a transmembrane domain of approximately 23 amino acids; and 
     (iv) a fourth region encoding a 26 amino acid cytoplasmic domain containing predominantly charged amino acids. 
     The complete nucleotide sequence of PM5.1 is given in FIGS. 1a-1d (SEQ ID NO:1). 
     PM5.3--A nucleic acid corresponding to PM5.1 with the exception that: 
     (i) a 42 base pair fragment encoding 14 amino acids is deleted from the second, serine-threonine rich, region; and 
     (ii) a 93 base pair fragment is deleted from the fourth region encoding the cytoplasmic tail. 
     Due to the loss of a termination codon this encodes a variant cytoplasmic tail having the first seven amino acids of the PM5.1 cytoplasmic tail, and then a further 23 amino acids arising from 3&#39; untranslated sequences of PM5.1. 
     The variant C-terminus of PM5.3 is shown in FIGS. 3a-3c (SEQ ID NO:4). 
     PM5.6--A nucleic acid corresponding to PM5.1 with the exception that as for PM5.3, a 93 base pair fragment is deleted from the fourth region encoding the cytoplasmic tail. Additionally, a 37 base pair fragment is deleted from the transmembrane region (encoding the last 12 amino acids thereof) due to the use of a cryptic splice acceptor signal. The absence of this fragment changes the reading frame of the carboxy terminal end of CD46 to encode a peptide having 34 amino acids distinct from those encoded by other CD46 nucleic acids. 
     The C-terminal sequence of PM5.6 is shown in FIGS. 3a-3c (SEQ ID NO:4). 
     PM5.8--A nucleic acid corresponding in part to 5.1 with the exception that those regions after the first region encoding the contiguous SCR regions are replaced with an intron sequence encoding 16 hydrophobic amino acids. 
     The C-terminal nucleotide sequence of PM5.8 is also given in FIGS. 3a-3c depict (SEQ ID NO:9). 
     Further representative sequences are depicted in FIG. 12 (with the exception of transcript d which corresponds to the prior art sequence of MCP). 
     Transcript a. This sequence was derived by PCR and contains all exons. It encodes a high M r  protein 74 kDa) known as the γ isoform and is preferentially expressed in EBV transformed cells and leukaemic cells. It contains the new sequence of STP A encoded by exon 7. 
     Transcript b is similar to transcript a but exon 13 has been deleted which gives rise to a new cytoplasmic tail. This form also has a high molecular weight and is found in EBV transformed and leukaemic cells. 
     Transcript c. This transcript was identified by clone pm5.1 and has exon 7 deleted. It gives rise to the α chain (M r  66 kDa) which is found in all tissues except sperm. 
     Transcript d. This transcript has exons 7 and 13 deleted and gives rise to the 66 kDa α chain found in all tissues except sperm. It is probably the commonest form identified and corresponds to clone pm5.10/MCP although the published sequence of MCP is missing the 3&#39; untranslated region and pm5.10 is missing the 5&#39; untranslated region and leader sequence and first three SCR amino acids. It should be noted that transcripts c and d give rise to the same sized protein on gels as the deletions do not give rise to a large difference in molecular weight. 
     Transcript e has deletions of exons 7 and 8 and is found in all tissues except sperm and gives rise to 56 kDa β isoform of CD46. 
     Transcript f is similar to transcript e, but with a different cytoplasmic tail due to the deletion of exon 13. It should be noted that the polymorphism effecting the differential expression of exon 8 gives rise to the major changes in molecular weight found in the α and β chain. Thus there are individuals who are α:α; α:β; and β:β. 
     Transcript g has deleted exon 9 and gives rise to an isoform of 70 kDa and is found in some placentae. 
     Transcript h is similar to transcript g but with the alternative cytoplasmic tail. 
     Transcript i has exons 7 and 9 deleted giving rise to 63 kDa isoform (ξ) found in some placenta. 
     Transcript j is similar with the alternative cytoplasmic tail. 
     Transcript k has deletions of exons 7, 8 and 9. 
     Transcript l--the same exons are deleted in addition as an alternative cytoplasmic tail due to the deletion of exon 13. 
     Transcript m has deletion of exons 7 and 13 and part of exon 12. This arises from the use of an alternative cryptic splice acceptor sequence so that part of exon 12 can be used. This was identified originally by a clone pm5.6. 
     Transcript n has exons 7, 8, 12 and 13 deleted giving rise to low molecular weight form of 35 kDa (the δ isoform found in the sperm). 
     The nucleic acid sequence according to the present invention, such as those described above may be modified by the substitution, deletion or insertion of one or more nucleotides. Such variants would include naturally occurring allelic variants, as well as variants produced artificially by well known techniques, such as site directed mutagenesis. CD46 proteins encoded by such derivative nucleotide sequences may have activity characteristic of CD46 or the corresponding portion thereof as described herein or conceivably result in enhanced CD46 activity, particularly as regards solubility, half-life, potency, specificity or localisation. 
     The discovery underlying this invention, that the family of CD46 proteins appear to arise as splice variants of a stuctural gene allows the identification and isolation of additional splice variants not specifically set forth herein. Such additional variants may arise from further splicing permutations of the exons described herein and/or incorporate additional exons. To isolate such additional variants, a nucleic acid probe comprising say 10 or more bases from the sequence of FIG. 1 could be used to probe preparations of tissues or body fluids to detect members of the CD 46 family sharing exon usages. The preparation probed may comprise a nucleic acid preparation isolated from the tissue, a fixed tissue section or an homogenate of the tissue and use probing techniques and assays known in the art. 
     The probing techniques described immediately above may also find utility in diagnosis of aberrant isoforms or particular isoforms implicated in the susceptibility, severity or prognosis of diseases. Preliminary indications suggest that CD46 structure may be significant in systemic lupus erythematosis. 
     In a further aspect, this invention extends to a transfer or expression vector which encodes a nucleic acid in accordance with this invention. Transfer or expression vectors include plasmid and viral DNAs, or viral RNA, but are not limited thereto. Any vehicle capable of replication in a host cell, whether prokaryotic or eukaryotic, is within the scope of this invention. Generally, but without limitation, a transfer or expression vector in accordance with this invention will include an origin of replication, promoter, selective marker (such as antibiotic resistance), and a nucleic acid sequence encoding CD46 as herein described, under the control of a promoter. 
     In another aspect, the invention relates to a cell containing a transfer or expression vector in accordance with this invention and CD46 produced by such a cell. Suitable cells may be prokaryotic or eukaryotic. The nature of the cell is generally unimportant as long as the transfer vector is capable of replication and desirably expressing therein. Eukaryotic cells are generally used when CD46 is to be post-translationally modified by the addition of carbohydrate, etc. Prokaryotic cells, such as bacterial strains, are preferred when post translational modification is not desired or is considered unimportant. For instance, vectors pAV009/A + , pKC3 and pEE6/hCMV/GSCDM8 and other vectors are appropriate for expression in Cos and Chinese hamster ovary cells. pGEX-3X is useful for prokaryotic expression in E. coli. We have observed that sequences encoding CD46 isoforms contain two possible translational start sites (rather than the single site originally reported). Although the 5&#39;-most ATG is preferred this site does not appear to be in the optimal sequence context in the CD46 family of proteins. Accordingly to improve expression PCR can be used to amend the 5&#39; ATG to the consensus sequence or the 5&#39; ATG removed to allow more effective translation from the distal ATG. Similarly, as untranslated regions of some RNAs may effect stability of the RNA and translation efficiency, removal of 3&#39; and 5&#39; untranslated regions, for instance by PCR may be desirable. 
     Vectors containing CD46 nucleic acid sequences may be introduced into cells by well known methods such as electroporation, conjugation, calcium phosphate precipitation, transformation of competent cells (such as bacterial cells after treatment with CaCl 2 ) and the like. In an alternative aspect, this invention includes cells having nucleic acid encoding CD46 as described herein integrated into the host chromosome. 
     CD46 produced by host cells may be isolated by protein purification techniques such as chromatography on size-exclusion or ion exchange matrices, HPLC, protein precipitation, affinity chromatography (using, for example, antibodies directed against CD46) and like techniques which are well known in the art. A further aspect of this invention provides essentially pure CD46 isoforms or derivatives translated from a nucleic acid in accordance with this invention. 
     CD46 isoforms or derivatives may be varied relative to native isoforms by the deletion, insertion or addition of one or more amino acids. Variations may be naturally occurring such as allelic variants or may be produced by well known techniques such as site directed mutagenesis or solid phase peptide synthesis or the like. Such variants are included within this invention as are fragments of the CD46 protein sequence. CD46 variants may possess biological or immunological activity the same or similar to that of CD46. 
     The CD46 protein sequence may be subject to side chain modifications such as: 
     Modifications of amino groups including 
     Reductive alkylation by Schiff&#39;s base formation by an aldehyde followed by reduction with NaBH 4 . 
     Amidination with methylacetimidate. 
     Acylation with acetic anhydride. 
     Carbamoylation of amino groups with cyanate. 
     Trinitrobenzylation of amino groups with 2,4,6, trinitrobenzene sulphonic acid (TNBS). 
     Acylation of amino groups with succinic anhydride and tetrahydrophthalic anhydride. 
     Pyridoxylation of lysine with pyridoxal-5&#39;-phosphate followed by reduction with NaBH 4 . 
     Modification of the guanidino group of Arg by the formation of heterocyclic condensation products with reagents such as 2,3 butanedione, phenylglyoxal and glyoxal. 
     Modification of carboxyl groups by carbodiimide activation via O-acylisourea formation followed by subsequent derivitisation e.g. to a corresponding amide. 
     Modification of sulphydryl groups including 
     Carboxymethylation with iodoacetic acid or iodoacetamide. 
     Performic acid oxidation to cysteic acid. 
     Formation of a mixed disulphide with 5,5&#39; dithiobis(2-nitrobenzoic acid) (DTNB). 
     Reaction with maleimide, maleic anhydride or other substituted maleimide. Formation of mercurial derivatives using 4-chloromercuribenzoate, 4-chloromercuriphenylsulphinic acid, phenylmercury chloride, 2-chloromercuri-4-nitrophenol and other mercurials. 
     Carbamoylation with cyanate at alkaline pH. 
     Modification of imidazole ring of histidine including 
     Alkylation with iodoacetic acid derivatives and 
     N-carbethoxylation with diethylpyrocarbonate. 
     Modification of tryptophan residues including 
     Oxidation of N-bromosuccinimide. 
     Alkylation of the indole ring with 2-hydroxy-5-nitrobenzyl bromide or sulphenyl halides. 
     Modification of the tyrosine residues 
     Nitration with tetranitromethane to form 3-nitrotyrosine derivatives. Modifications as set out above may be produced according to standard chemical reactions well known in the art. 
     CD46 and variants and fragments thereof as herein described may be provided in the form of therapeutic compositions in association with one or more pharmaceutically acceptable carriers or excipients. Examples of carriers or excipients which may be utilized in this invention are provided in Remington&#39;s Pharmaceutical Sciences 16th Ed, 1980, Mack Publishing Company, Osoll et al, which is incorporated herein by reference. By way of example only, CD46 and variants and fragments thereof may be in association with saline, albumin, water, dextrose or the like. The invention thus extends to the use of the CD46 isoform or derivative produced in accordance with the invention in the manufacture of a medicament. Furthermore, as foreshadowed above, antibodies directed against epitopes encoded by the STP, UK, TM and CYT regions will also have utility in diagnosis and therapy. Therefore CD46 derivatives presenting such epitopes, typically somewhat truncated relative to native proteins, as well as mono or polyclonal antibody preparations directed thereto form a still further aspect of the invention. Epitopes to raise such antibodies may be constructed as synthetic oligonucleotides following the sequences herein or alternatively be expressed from a recombinant nucleic acid of the invention. Technology for raising antibodies to such epitopes including providing haptens or adjuvants and for immortalizing cell lines to produce monoclonal cell lines are well known and need not be described here. 
     CD46 isoforms or derivatives in accordance with this invention may be utilised to prevent complement-mediated or inflammation mediated tissue damage, to enhance immunity to tumours and viruses, to control the process of fertilization, to prevent recurrent spontaneous abortion of the fetus during pregnancy and to facilitate the engrafting of transplanted tissue. 
     For example inhibition reactions of complement activation in the classical pathway are initiated by antibody binding to antigen and examples are blood transfusion reactions, glomerulonephritis, Goodpasture&#39;s syndrome, systemic lupus erythematosis, rheumatoid arthritis, graft rejection and other diseases where antibody interact with antigen. In addition, certain aspects of cellular immunity are mediated by the complement pathway such as complement receptor on macrophages, polymorphs and other cells binding to antigen-antibody-complement complexes, CD46 isoforms or derivatives in accordance with the invention could inhibit such reactions. In addition, CD46 isoforms or derivatives would be expected to inhibit the alternative pathway activated by inflammatory mediators, bacteria and other substances. Such activation occurs in most inflammatory conditions not necessarily of antibody, i.e. immunological, origin. For example, inflammation which occurs in myocardial infarction, hepatitis, pneumonia, gastroenteritis; indeed inflammation of any organ. Certain aspects of the inflammation are beneficial, i.e. to eradicate bacteria, viruses and the like. However, certain aspects of inflammation are non-specific and cause tissue damage. Soluble CD46 could inhibit such non-specific reactions. 
     An example of the diagnostic and therapeutic utility of the CD46 isoform or derivative nucleic acids or proteins is described above with regard to exon 7 expression in leukaemic cells. Additionally, in placenta there are clear differences in placental tissue of some individuals compared to others. For example, it is clear that some individuals have deletions found in transcripts g, h, i, j, k and l discussed above. These members of the CD46 family of proteins which are apparently synonymous with the TLX antigen (trophoblast leukocyte cross-reactive antigen) have been associated with habitual abortion in certain individuals. Some of these polymorphisms defined in the present invention may be associated with habitual abortion. It is, therefore, not unlikely that the presence or absence of exons found in certain sequences falling within the broad scope of the invention are responsible for retention/rejection of the fetus in pregnancy. From this, diagnostic tests, for instance nucleic acid probing of maternal or fetal tissue or fluids could be performed to determine which individuals are likely to abort. Administration of a soluble CD46 may serve to mop up surrounding complement to maintain a pregnancy in an habitually aborting mother. Antibodies or antisense oligonucleotides in accordance with the invention will be useful to cause or prevent the expression of these exons and thus overcome the problem of habitual abortion. 
     A further utility of nucleic acids and CD46 or derivative proteins in accordance with the invention lies in the field of male infertility and encouraging fertilization. It has been observed above that certain of the CD46 family are uniquely expressed on sperm cells, presumably to inhibit complement activated lysis. Individuals with azospermia may be diagnosed with antibodies or probes in accordance with the invention, directed to the unique structure of the sperm CD46. As mentioned above soluble CD46 promises to be useful in mopping up complement to facilitate survival of otherwise vulnerable sperm or to otherwise prevent inhibition of sperm function i.e. migration, penetration, motility or fertilization. It is also likely that CD46 on the sperm is part of a receptor complex responsible for sperm binding to oocytes prior to fertilization. It will be apparent that nucleic acids or CD46 proteins or derivatives will be useful in fertility control. 
     Nucleic acids and CD46 proteins or derivatives in accordance with the invention also find utility in transplantation. In the rejection of allografts, i.e. from one human to another, T cells are involved and establish inflammatory mechanisms. CD46 could inhibit such non-specific inflammatory reactions occurring after the specific event. In addition, allo-antibodies are involved either in hyperacute rejection or in the late phase of rejection and these act using complement. CD46 may also inhibit this procedure. With regard to xenotransplantation, i.e. form one species to another, it is possible that CD46 could have several actions. In the first soluble material could inhibit the action of complement which is involved in rejection. In the second, transgenic animals could be made expressing CD46 on the cell surface and any or all of the variants could be used for such a procedure. In this setting, one could envisage such species as pigs, sheep or other species expressing human CD46 being used for transplantation experiments. The human CD46 in these organs would break down complement as it was deposited and make the tissues resistance to complement mediated lysis. It is possible that such xenografts could become universal donors for transplants to humans. The pm5.1 clone, containing the CYT 1 tail, is the most likely candidate for this function as it has been shown to have increased cell surface expression compared to clones with the CYT 2 tail as for instance expressed in MCP or pm5.3, pm5.10. 
     Specific embodiments of the present invention will now be described by way of example only, with reference to the following non-limiting Figures and Examples. 
    
    
     BRIEF DESCRIPTION OF THE FIGURES 
     FIG. 1A shows the complete nucleotide sequence and predicted amino acid sequence of the pm5.1 cDNA clone of CD46 (SEQ ID NOS:1 and 2, respectively). The NH 2  -terminal amino acid sequence obtained from purified CD46 glycoprotein is underlined; potential addition sites for N-linked carbohydrate are marked with an asterisk; the region boxed with a hashed line is rich in Ser/Thr residues--potential O-linked glycosylation sites; the region boxed with a solid line is the hydrophobic transmembrane domain. The regions within the labelled arrows are the segments of DNA deleted by the other clones, all of the sequence beyond the arrow labelled pm5.8 has been exchanged for new sequence in the pm5.1 clone. 
     FIG. 1B shows the sequence (SEQ ID NO:3) of additional nucleotides in the 3&#39; untranslated region of the pm5.6 clone, which is longer than the pm5.1 sequence shown in FIG. 1A. The numbering corresponds to the position relative to the pm5.1 clone and does not take account of the 130 bp deleted from the coding sequence of pm5.6. 
     FIG. 2 shows the alignment of the NH 2  -terminal 251 amino acids of the mature CD46 protein (residues of 1-251 of SEQ ID NO:2) showing the four domains of internal homology, indicated by the boxes. Conservative substitutions are shaded. Spaces (-) have been introduced to maximise alignment. The alignment of these internally conserved residues with the consensus sequence of the 60- amino acid short consensus repeats of the complement regulatory proteins is shown at the bottom. 
     FIGS. 3a-3c depict the alternate carboxyl-terminal protein sequences deduced from the nucleotide sequences of the different cDNA clones for CD46 commencing from amino acid 252. The amino acid sequences encoded by the pm5.1 (SEQ ID NO:5), pm5.6 (SEQ ID NO:6), pm5.10 (SEQ ID NO:7), and pm5.3 (SEQ ID NO:8) clones are shown in (A) the regions of DNA deleted in these clone is denoted by the arrows above the pm5.1 DNA sequence (SEQ ID NO:4) and the dashes (-) in the protein sequence. The DNA and amino acid sequence of pm5.8 (SEQ ID NOS:9 and 10, respectively) that differs to that of the other clones is shown in (B) but is numbered relative to the pm5.1 clone. The regions of hydrophobic amino acids are shown with a solid box and regions rich in Ser and Thr residues are shown with a hatched box. 
     FIGS. 4a-4e show a summary of the structure of the five alternate cDNA clones for CD46 showing the positions where differences in sequence occur relative to the pm5.1 clone. The location of the 5&#39; untranslated (5&#39; UT), leader peptide (L), short consensus repeat (SCR), serine/threonine rich (S/T), hydrophobic transmembrane (TM), cytoplasmic tail (CYT), and 3&#39; untranslated (3&#39; UT) regions are labelled above the pm5.1 clone. The number of amino acids and calculated molecular weight of each version of CD46 potentially encoded by these is shown at the right. 
     FIGS. 5a-5b are is a northern blot analysis of 2 μg of poly(A) +  RNA separated under denaturing conditions by electrophoresis on 1.2% agarose gels containing formaldehyde, transferred to Nylon membrane and hybridized with  32  P-labelled CD46 cDNA from the pm5.1 clone. The autoradiograph shows RNA from human spleen tissue from patients with non-Hodgkins lymphoma (lane a), polycythemia vera (lane b), hairy cell leukaemia (lane c), physical trauma (normal) (lane g) and from the human T-lymphoblastoid cell line PEER (lane c), the myelomonocytic cell line U937 (lane f), and the gibbon ape T-lymphoblastoid cell-line UCD-144-MLA (lane d). Each sample had a predominant band of 3.2 kb and the spleen tissue infiltrated with hairy cell leukaemia cell had two minor bands at 4.8 kb and 7.7 kb. 
     FIG. 6 is a northern blot analysis of 2 μg of poly(A) +  from human placenta separated under denaturing conditions by electrophoresis on 1.2% agarose gels containing formaldehyde, transferred to strips of Nylon membrane that were hybridized with either  32  P-labelled CD46 cDNA from the pm5.1 clone (lane a), or the oligonucleotides; On63 which spans the site of the 93 bp deleted from the pm5.1 sequence and therefore specific for RNA corresponding to the pm5.3, pm5.6 and pm5.10 clones (lane b), On46 which is within this 93 bp segment of pm5.1 and therefore specific for RNA corresponding to the pm5.1 clone (lane c), On35 which spans the site of the 42 bp segment deleted by the pm5.3 clone and therefore specific for RNA corresponding to the pm5.3 clone (lane d), On44 which is within the 42 bp segment deleted by the pm5.3 clone and therefore specific for RNA corresponding to the pm5.3 clone (lane c), or the On68 which is within the new (intron) sequence of the pm5.8 clone (lane f). Details of these oligonucleotides are shown in Table 2. 
     FIGS. 7a-7g Expression of CD46 transcripts in human placenta. The variable region of CD46 was amplified by PCR using primers On37 and On24. Templates for the PCR reaction were the clones pm5.1, pm5.3, pm5.6, pm5.8 and pm5.10 (lanes a to e respectively), no template (lane f), and cDNA produced from placental poly (A) +  cytoplasmic RNA primed with On24 (lane g) and oligo(dT) (lane h).  32  P-labelled samples were electrophoresed on a 6% acrylamide gel containing urea with the M13mp18 sequence ladder as a size marker. Sizes of the PCR products are indicated on the right and the position of the PCR products corresponding to the clones are arrowed on the left. Unlabelled products were electrophoresed on a 1.5% agarose gel (Panel 1), transferred onto nylon and probed with oligonucleotides specific for different CD46 transcripts (Panels 2 to 6). Details of the oligonucleotides are shown in Table 2. 
     FIGS. 8a-8b Expression of pm5.6 and pm5.8 type transcripts in human placenta. The five clones (lanes a-e), placental cDNA from cytoplasmic RNA primed with oligo(dT) (1 lane g) or random hexamers (2 lane g) and placental genomic DNA (lanes h) were amplified with paris of primers including: (1) an oligonucleotide spanning the pm5.6 deletion (On36 and On39), or (2) on oligonucleotide in the new sequence of pm5.8 (On83 and On85), and electrophoresed on 1.5% agarose gels with Hpa 11 digested PUC19 DNA as a size marker (lanes s). Reaction mixes containing no template DNA were included as a control. 
     FIG. 9 Distribution of CD46 isoforms in various tissues. Western blot probed with E4.3 showing distribution of CD46 isoforms in lymphocytes (lanes 1-3), granulocytes (lane 4) and EBV-transformed B cells (lane 5), spermatozoa (lanes 6 and 7), leukemic cells (lanes 8-10), normal and malignant colon tissue from a patient with colon carcinoma (lanes 11 and 12 respectively), and full term placentae (lanes 13-16). Samples in lanes 3-6 are from the same donor as are samples in lanes 1 and 7. Relative molecular mass in kDa is shown at left and Greek letters at right indicate positions of isoforms. 
     FIG. 10A Position of primers used to amplify the region of alternative splicing. Sequence of P1:-5&#39;-GGCAGCGACACAATTGTC-3&#39; (SEQ ID NO:31) and P2:-5&#39;-CAGCCTCTCTGCTCTGCTG-3&#39; (SEQ ID NO:32). 
     FIG. 10B Exon organization of the CD46 gene; exons numbers are shown in boxes and functional domains of the derived amino acid sequence is shown above. Shaded boxes indicate constitutively spliced exons and white boxes indicate exons which are alternatively spliced. Dashed line indicates cryptic splice acceptor site. 
     FIG. 10C Nucleotide and derived amino acid sequence of exon 7 (SEQ ID NOS:11 and 12 respectively). 
     FIG. 10D Derived amino acid sequence of the COOH-terminal region of the CD46 isoforms (SEQ ID NOS:13-16) encoded by the differential splicing of exons 12 and 13. Spaces in amino acid sequence indicate deletions of the exons shown above and * indicates stop codons. 
     FIG. 11A Amplification of CD46 cDNA clones using PCR. CD46 cDNA clones, pm5.1, pm5.3 and pm5.10 were amplified together in the proportions indicated below each track. α  32  P!dCTP was incorporated into the PCR products and the samples were electrophoresed and autoradiographed. 
     FIG. 11B Electrophoresis of radiolabelled, amplified cDNA from lymphocytes (lanes 1-3), granulocytes (lane 4) and EBV-transformed B cells (lane 5), spermatozoa (lanes 6 and 7), leukemic cells (lanes 8-10), normal and malignant colon tissue from a patient with colon carcinoma (lanes 11 and 12 respectively), and full term placentae (lanes 13-16). samples 3-6 are from the same donor as are samples 1 and 7. 
     FIGS. 11C-11I Tissue distribution of individual exon combinations. Unlabelled, amplified cDNA from the same samples as 11B were electrophoresed, electroblotted and probed with oligonucleotides specific for different exons or exon combinations (see FIG. 12 for locations of probes). 
     C) exons 6-7 (SEQ ID NO:33): 5&#39;-CTAGATGGAGGCAGCACTTTAAGACACTTTGG-3&#39; 
     D) exons 8-9 (SEQ ID NO:34): 5&#39;-AAGTAGGCCTAGGACCTGAGGCACTGGACG-3&#39; 
     E) exons 6-9 (SEQ ID NO:35): 5&#39;-TAAGTAGGCCTAGGACCTTTAAGACACTTTG-3&#39; 
     F) exons 8-10 (SEQ ID NO:36): 5&#39;-CAGGTTTAGGATATCCTGAGGCACTGGACG-3&#39; 
     G) exon 13 (SEQ ID NO:37): 5&#39;-CCTTCTCAGAGAGAAGTAAATTTTACTTCTCTGTGG-3&#39; 
     H) exons 12-14 (SEQ ID NO:38): 5&#39;-CCACCATCTGCTTTCCCTTTCTTCTTCCTCC-3&#39; 
     I) exons 11-14 (SEQ ID NO:39): 5&#39;-CCACCATCTGCTTTCCTATGGCAATAACAATC-3&#39; 
     FIG. 12 Correlation of CD46 RNA transcripts with protein isoforms. The transcript name indicates exons which have been deleted, 12a indicates the first part of exon 12. Breaks in the solid black lines under &#34;Transcript structure&#34; indicate the deletion of exons corresponding to the diagram of exon structure shown below. Boxes indicate exons and the dashed line through exon 12 shows the position of the cryptic splice acceptor site. Arrow indicate positions of oligonucleotide probes used in FIG. 3 and letters denote the panel in which they were used. The protein M r  and name of the correlating protein isoform are shown; question marks indicate that the protein isoform was not discernible in the western blot of FIG. 1. The tissue distribution of RNA transcripts and protein isoforms is indicated in the right hand column. 
     FIGS. 13a-13g A summary of nucleic acid sequence and amino acid allocation for exons 7 to 14 of transcripts a to n of FIG. 12. 
     FIGS. 16a-16d depict a cDNA sequence and amino acid sequence for CD46 isoform PM5.8 (SEQ ID NO:45). 
     FIG. 13-a includes SEQ ID NOS 11 and 12; FIG. 13-b includes SEQ ID NOS 17 and 18; FIG. 13-c includes SEQ ID NOS 19 and 20; FIG. 13-d includes SEQ ID NOS 21 and 22; FIG. 13-e includes SEQ ID NOS 23, 24 and 25; FIG. 13-f includes SEQ ID NOS 26 and 27; and FIG. 13-g includes SEQ ID NOS 28, 29 and 30. 
     FIGS. 14a-14d depict a cDNA sequence and amino acid sequence for CD46 isoform PM5.3 (SEQ ID NO:41). 
     FIGS. 15a-15e depict a cDNA sequence and amino acid sequence for CD46 isoform PM5.6 (SEQ ID NO:43). 
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     EXAMPLE 1 
     Isolation of cDNA Clones 
     Using the sequence of the 23 N-terminal amino acids previously obtained from the 66 and 56 kDa α and β chains of CD46 (Purcell et al. (1989) Immunol. Cell Biol. 67, 279-389), five oligonucleotide probes were synthesized (Table 1) using an Applied Biosystems 380A DNA Synthesizer (Applied Biosystems Inc.). Short oligonucleotides containing either the full component of redundant codons, or longer oligonucleotides selected to have the most likely codon using the algorithm of Lathe et al. (1985) J. Mol. Biol. 183, 1-12, were end-labelled with γ 32  dATP using T4 polynucleotide kinase (Maxam and Gilbert (1977) Methods in Enzymology 65, 499-560) and unincorporated label removed with a Sepharose G-25 spun column. 
     A human placental cDNA library containing 5×10 6  independent clones in the λgt11 vector (Clonetech) was plated at a density of 5×10 4  p.f.u. per 15 cm plate and plaque DNA transferred in triplicate and covalently linked to nylon membranes (Hybond-N, Amersham; Huynh et al. (1988) DNA Cloning I, A Practical Approach, Glover (Ed), Oxford pp 47-48. Filters were probed with three pools of oligonucleotides in hybridization buffer containing 5×PE (1×PE=0.133 m phosphate/1 mM EDTA buffer, pH 6.9). 7% SDS, 0.5% BLOTTO (dried skim milk powder), 1 polyethylene glycol 2000 at 42° C. and washed with 2×SSC (0.3M, Nacl, 0.03M Sodium Citrate pH 7.0), 0.1% SDS at 2° C. below the lowest melting temperature of the oligonucleotides in the pool (Reed and Mann, 1985). Clones hybridizing with two or more of the pools were selected for further screening with both pools and individual oligonucleotides. After four rounds of screening, six clones (pm5.1, 0.2, 0.3, 0.6, 0.8 and 0.10), were isolated and phage DNA prepared by the DE52-Sepharose method (Benson and Taylor (1984) Bio Techniques, 2, 126-127). Inserts from cDNA clones were prepared by digesting with EcoRI and isolating insert bands by electrophoresis on an 0.8% agarose gel and subcloning into the pVZ plasmid vector for sequencing and other analyses. 
     DNA analysis. The nucleotide sequences of the CD46 cDNA clones were determined by the dideoxynucleotide chain termination method using the T4 polymerase, Sequenase II (Tabors and Richardson (1987) Proc. Natl. Acad. Sci. U.S.A., 84, 4767-4777) (United States Biochemical Corporation) from double and single stranded templates of cDNA clone in the pVZ vector. Products were analyzed on denaturing acrylamide gels containing urea. The sequencing strategy included using internal oligonucleotide primers, and using clones containing cDNA inserts truncated by the Mung bean exonuclease III method (Sambrook et al. (1989) Molecular Cloning, A Laboratory Manual (2nd Ed), Cold Spring Harbour Laboratory) to sequence both strands of each clone. Sequences were collated and corrected and sequence searches performed with the aid of a VAX computer using the MELBSYS and DBQUERY suite of programs. 
     The nucleotide sequences of these clones were mostly identical, having a single open reading frame, however five of the six clones differed at the 3&#39; end of the long open reading frame. Clone pm5.2 had a shorter 3&#39; untranslated region than clone pm5.6 but was otherwise identical. 
     The complete nucleotide sequence of the pm5.1 clone, which had the longest contiguous coding sequence, is shown in FIGS. 1a-1d (SEQ ID NO:1). The pm5.1 clone encodes a protein of 377 amino acids from the single long open reading frame, commencing from an initiation codon (ATG) at nucleotide position 33 or at position 102. The amino acid sequence commencing from the Cys at amino acid position 35 is identical to that obtained experimentally from purified CD46 (Purcell et al. (1990) Immunogenetics, 31, 21-28) and the sequence of the first 34 amino acids corresponds with that predicted for a typical leader peptide that is cleaved to generate the mature protein (von Heijne (1986) Nucleic Acids Res., 14, 4683-4690). The molecular weight calculated for the mature protein is 38,353 Da, which correlates well with earlier analyses of deglycosylated CD46 (Purcell et al. (1989) Immunol. Cell Biol., 67, 279-281) and biosynthetically labelled MCP precursor (Ballard et al. (1988) J. Immunol., 141, 3923-3929). There are three potential N-linked glycosylation sites (FIGS. 1a-1d) and multiple potential O-linked glycosylation sites, many of which exist in a region between amino acids 253 and 280. The addition of carbohydrate at these sites would account for the increased molecular weight of the mature protein. A stretch of 23 hydrophobic amino acids from position 295 to 317 are consistent with a membrane spanning domain (Kyte and Doolittle (1982) J. Mol. Biol., 157, 105-132). The rest of the open reading frame encodes a cytoplasmic tail of 26 mostly charged amino acids. Four regions of approximately 60 amino acids were identified at the NH 2  -terminal end of the mature protein that have between 18-35% amino acid identity (FIG. 2), and these each contain the consensus of the family of complement regulatory molecules and can therefore be considered as short consensus sequence repeat (SCR) units of this family of molecules (Reid et al. (1986) Immunol. Today, 7, 230-234). 
     The pm5.3, pm5.6 and pm5.10 clones each have segments of coding sequence deleted at regions 3&#39; to the segment encoding the four SCR units of the prototype pm5.1 clone (FIGS. 1a-1d). The pm5.10 clone lacks 93 bp of nucleotide sequence that encodes 16 of the 23 amino acids of the cytoplasmic tail and a portion of the 3&#39; untranslated sequence of the pm5.1 clone (FIG. 1, FIGS. 3a-3c, SEQ ID NOS:4-10). Since this 93 bp fragment contains the termination codon ending the open reading frame of pm5.1, the new reading frame of pm5.10 includes a segment of sequence that forms the initial portion of the 3&#39; untranslated sequence in pm5.1. Therefore, the CD46 molecule encoded by pm5.10 has a cytoplasmic tail of 33 amino acids, 23 of which differ from those encoded by pm5.1 (SEQ ID NO:7)(FIGS. 3a-3d). This new tail would be longer by 7 amino acids, but would also have a high proportion of charged amino acids. The pm5.10 clone is not full-length and lacks the sequence at the 5&#39; end that would encode the leader peptide (FIGS. 4a-4e), however the remainder of the nucleotide sequence is identical to pm5.1. The nucleotide sequence of the pm5.10 clone perfectly matches within that of a MCP cDNA clone isolated independently, without a single nucleotide different (Lublin et al. (1988) J. Exp. Med., 168, 181-194). 
     The pm5.3 clone also lacks the 93 bp fragment absent in pm5.10, but has an additional deletion of 42 bp from a region encoding the second half (14 amino acids) of the Ser/Thr rich region (FIGS. 3a-3c (SEQ ID NO:8), FIGS. 4a-4e) removing two potential O-linked carbohydrate addition sites and five kink forming Pro residues. Since loss of this segment of DNA does not change the reading frame the remainder of the CD46 protein encoded by this clone would have the same amino acid sequence as that encoded by pm5.10. 
     The pm5.6 clone also lacks the 93 bp fragment absent in pm5.10, but has an additional deletion of 37 bp from a region encoding the second half (12 amino acids) of the hydrophobic transmembrane domain resulting from the use of a cryptic splice acceptor sequence (TGTTGTCCCGTACAG, SEQ ID NO:4) at the 3&#39; and of this deleted segment (FIGS. 3a-3c, FIGS. 4a-4e). The absence of this fragment changes the reading frame and the CD46 protein encoded by the pm5.6 clone would have 34 different amino acids at the carboxyl-terminus compared to CD46 protein from the other clones. Subsequently, the resulting CD46 molecule (SEQ ID NO:6) would have hydrophilic and predominantly charged amino acids substituting for half of the transmembrane domain, and this may lead to secretion of this version of CD46 from the cell. The pm5.6 clone had a 3&#39; untranslated region that was 465 bp longer than the pm5.1 clone (FIG. 1B). A second independent clone, pm5.2, had the same set of deletions as pm5.6, but was 286 bp shorter than pm5.6 in the 3&#39; untranslated region. Neither a poly(A) signal sequence (AATAAA) nor a poly(A) tail was found in the 3&#39; untranslated sequences of any of the clones. 
     The sequence of the pm5.8 clone was identical to the pm5.1 clone in the portion encoding the NH 2  leader and four SCR regions, however the sequence after nucleotide 890 of pm5.1 was different to any sequence derived from all the other clones, (FIG. 3B) SEQ ID NO:9 and 10) and results from reading through of the cDNA into an intron sequence after the fourth SCR (see below). If protein were encoded by this new sequence it would contain a stretch of 16 hydrophobic amino acids possibly serving as a membrane spanning sequence, although this is a little shorter than typically found (Kyte and Doolittle (1982) J. Mol. Biol., 157, 105-132). The putative cytoplasmic tail of this version of CD46 would also contain a high proportion of charged amino acids. The structure of the proteins derived from the 5 alternative versions of CD46 cDNA clones isolated from the human placental cDNA library are summarized in FIG. 4. 
     EXAMPLE 2 
     Northern Blot Analysis of CD46 mRNA 
     RNA was prepared from fresh human placental tissue using guanidinium isothiocyanate method (Chirgwin et al. (1979) Biochem., 18, 5294-5299) and poly(A)+ RNA isolated by chromatography on oligo (dT) cellulose (Aviv and Leder, (1972) Proc. Natl. Acad. Sci. U.S.A., 69, 1408-1412). RNA was denatured and size fractionated on a 1% agarose gel in the presence of 0.8% formaldehyde and blotted onto nylon membranes using 0.1M NaOH transfer buffer. Filters were prehybridized with 4×PE defined earlier, 50% formamide, 7% SDS, 0.5% BLOTTO (skim milk powder), 1% polyethylene glycol at 42° C. then hybridized with either pm5.1 cDNA insert labelled with 32Pα-ATP by nick transplantation, or with oligonucleotides complimentary to sequence spania the splice site or to or deleted segments of the cDNA clones (Table 2). Oligonucleotides were end-labelled using T4 polynucleotide kinase as before. Filters were washed in 1×SSC at 60° C. for the cDNA probes or 1×SSC at 1° C. below the Tdmin for the oligonucleotides. 
     The size and number of CD46 mRNA species was determined in samples of spleen from human and gibbonape cell lines (FIGS. 5a-5b). Each of the samples tested had a dominant band at 3.2 kb and the spleen infiltrated with hairy cell leukaemia (FIG. 5c) had two other fainter bands of 4.8 and 7.7 kb. Using densitometric scanning equivalent levels of the 3.2 kb CD46 mRNA were observed in spleen from patients with non-Hodgkins lymphoma and polycythemia vera and in the human cell-lines PEER and U937 and in the gibbon ape cell line 144-MLA. The 144-MLA line is chronically infected with the gibbon ape leukaemia virus which encodes a virion surface glycoprotein (SU70) that bears a cross-reactive antigenic epitope of CD46 recognised by the E4.3 mAb (Purcell et al. (1989) Leukocyte Typing IV White Cell Differentiation Antigens, pp 653-655, Oxford University Press). The E4.3 mAb to CD46 recognised thirty fold more protein at the surface of 144-MLA cells than other human cell lines, however the equivalent levels of CD46 mRNA supports the earlier finding that the E4.3 mAb predominantly reacts with the gibbon ape leukaemia virus surface gp70 molecules on the 144-MLA cell. The spleen sample infiltrated with hairy cell leukaemia showed a ten fold greater level of the 3.2 kb CD46 mRNA than the other spleen samples and the histopathologically normal spleen from a trauma patient had twenty fold less CD46 mRNA than the spleen samples infiltrated by neoplastic cells. This again showed that malignant tissue samples and cell-lines contain ten to twenty fold more CD46 than the corresponding non-malignant cell and shows that this is due to elevated transcription of CD46 RNA. Size variations of around 100 bp in the 3.2 kb band, as predicted from the sequence of the clones, were beyond the resolution capability of these gels. To verify the existence of, and examine the relative proportion of, the alternatively spliced CD46 RNA species predicted from the clones, a series of antisense oligonucleotides were constructed that would differentially hybridize with alternately spliced CD46 mRNA (Table 2). These were used to probe Northern blots of poly(A) +  RNA from human placenta (FIG. 6). When a CD46 cDNA insert from the pm5.1 clone was used as a probe three bands were noted, a broad band at 3.2 kb as with the other human cells, a band of 1.9 kb and a fainter band of 5.2 kb. The 1.9 kb band probably relates to the use of cryptic polyadenylation signals (AATATA or AATGAA) found at positions 1579 and 1592 of the pm5.1 clone. These sequences were apparently used by the clone of MCP isolated by Lublin et al. (1988) J. Exp. Med., 168, 181-194. Hybridization with the On63 oligonucleotide, specific for RNA lacking the 93 bp segment of the pm5.1 clone between positions 1115 and 1208 (i.e., corresponding to the pm5.3, pm5.6 and pm5.10 clones), yielded a faint band of 3.2 kb (arrowed in FIG. 6, lane D) showing that RNA lacking the 93 bp segments is a genuine component of the pool of CD46 mRNA. Hybridization with the On46 oligonucleotide, specific for RNA containing the 93 bp segment (pm5.1) yielded a predominant 3.2 kb CD46 band (FIG. 6, lane c). Hybridization with the On35 oligonucleotide, which is specific for RNA containing pm5.3 type of deletion of 42 bp, also yielded the 3.2 kb CD46 RNA band verifying that a subpool of CD46 RNA contains this deletion (FIG. 6, lane d). Hybridization of the On44 oligonucleotide, which is specific for RNA retaining the 42 bp deletion yielded a very faint 3.2 kb CD46 RNA band showing that a subpool of CD46 RNA retains this deleted segment (FIG. 6, lane e). Hybridization with the On68 oligonucleotide, which is specific for the new (intron) sequence of the pm5.8 clone, did not result in the detection of any RNA bands (FIG. 6, lane f). The results show that the pm5.1, pm5.3, pm5.6 and pm5.10 cDNA clones of CD46 isolated from the placental cDNA library result from the presence of corresponding alternative RNA species for CD46 and are not a result of rearrangements during the construction of the library or other manipulations. 
     EXAMPLE 3 
     Analysis of CD46 mRNA by Polymerase Chain Reaction (PCR) 
     Placental poly(A) +  RNA and total RNA was treated with RNase-free DNase and used as a template for the synthesis of cDNA with 100 U Molony murine leukemia virus reverse transcriptase. Reactions of 5 μg poly(A) +  RNA or 50 μg total RNA; 12.5 μM (each) dNTPs, 0.25 μM On24, and oligo (dT) 16-20 mer or random hexamers as primers were incubated at 37° C. for 1 hour, then DNA was amplified by Polymerase Chain Reaction (PCR) in 0.5 mM MgCl 2 , 10 mM Tris HCl (pH 8.3), 50 mM KCl, 200 mM (each) dNTPs, 4UTaq DNA polymerase (Amersham). Pairs of oligonucleotides were added to a final concentration of 1 μM and template was added at 2 μl, 1 μg, or 1 ng per 50 μl reaction for first strand cDNA, genomic DNA and cDNA clones respectively. To label the product the dCTP concentration was reduced to 100 mM and 0.5 μl α 32  P-dCTP was added. After 3 min. at 95° C. reactions were subjected to 30 cycles of denaturation (93° C., 1 min.) annealing (see Table 2, 2 min.), and elongation, (72° C., 1 min). Unlabelled PCR products were size fractionated on a 1.5% agarose gel transferred to Hybond N +  in 0.5M NaOH, 1.5M NaCl for probing with oligonucleotides. 
     Radiolabelled PCR samples were analyzed by electrophoresis on 6% acrylamide gels containing urea with sequencing reactions as size markers and autoradiographed at -70° C. on XAR-5 or XRP film. 
     To overcome the weak hybridization signals obtained in Northern blots using the type specific oligonucleotide probes, placental poly(A)+ cytoplasmic RNA was converted to cDNA with reverse transcriptase by priming with On24 or with oligo(dT) and alternate cDNAs for CD46 amplified by polymerase chain reaction (PCR) using CD46 primers On57 and On24 that hybridize outside the region of alternative splicing. Electrophoresis of labelled amplification products from the different CD46 clones and from placental cDNA on 6% acrylamide gels revealed a number of different sized bands (FIG. 7A), including bands corresponding in size to those amplified from the pm5.1, pm5.3, pm5.6 and pm5.10 clones on (391, 256, 261 and 298 bp respectively). Several additional bands (219, 247, 289, 304 and 349 bp) were observed from placental cDNA samples primed with both On24 and oligo(dT). While several of these extra bands differ from the 391 bp pm5.1--type band by sizes that may correspond to the deletion of different sets of the 37, 42 and 93 bp segments (eg. 349=391-42, or 219=391-37-42-93) or of the 27 and 75 bp segments between the 42, 37 and 93 bp regions (eg. 289=391-75-27, or 249=391-42-75-27) the structure of these and their significance requires further investigation. A doublet of 415 and 419 bp which is larger than the PCR products from any of the clones was also produced from cDNA primed with On24 but not with oligo(dT). The RNA molecules giving rise to these bands either lack a poly(A) tail or exist in the 5.2 kb poly (A)+RNA pool which would be reverse transcribed to the region of alternative splicing at low efficiency and may not be functionally important. None of the bands in the cDNA samples arose due to amplification of contaminating clones or genomic DNA because no bands were obtained after PCR from various controls including reaction mixes lacking template DNA, cDNA reaction mixes lacking reverse transcriptase (hence containing only RNA), an aliquot of reverse transcriptase enzyme mix used in cDNA synthesis and genomic DNA. To confirm the identity of the different bands amplified from cDNA, unlabelled PCR products were transferred to nylon filters after agarose gel electrophoresis and probed with the type--specific oligonucleotides (FIGS. 7b-7g). Probing with On63 for the 93 bp deletion of pm5.3, pm5.6 and pm5.10 (FIG. 7d) revealed a smear of bands from the position of the pm5.10 band to below the pm5.3 and pm5.6 bands. Probing within the 93 bp sequence with On46 showed a smear of several bands around the size of the pm5.1 band (FIG. 7f). Probing with On44 for the 42 bp sequence deleted in pm5.3 (FIG. 7c) detected several bands corresponding in size to the bands from the pm5.1, pm5.6 and pm5.10 clones. The On35 probe spanning the 42 bp deletion (FIG. 7e) also detected several bands including one of similar size to the pm5.3 band. The On45 probe which lies within the 37 bp deletion (FIG. 7g) detected several bands corresponding to pm5.1, pm5.3 and pm5.10. Each of these oligonucleotide probes confirmed the existence of RNA molecules in placenta that have the deletions identified in the CD46 cDNA clones however these probes detected with more PCR products amplified from cDNA than accounted for by amplification from the clones. This shows that several of the extra bands seen in FIG. 7A result from different combinations of the deleted segments contained in the clones. 
     Because the On36 oligonucleotide which spans the site of the 37 bp deletion failed to discriminate pm5.6 from the other CD46 clones when used as a probe in hybridization studies, we used On35 as a primer to amplify placental cDNA prepared with oligo(dT) priming by PCR (FIG. 8a). A product of 756 bp was amplified from the pm5.6 clone and from placental cDNA but not from controls. Two larger bands of unknown identity were also obtained from the PCR with placental cDNA. These results show that the 37 bp deletion of the pm5.6 and pm5.2 clones is due to RNA with this structure and not due to cloning artifact. Further, PCR amplification reactions were performed on cDNA from cytoplasmic RNA and genomic DNA using primers at either side of the boundaries of the deleted segments and the regions separating these to locate the intron/exon junctions (Table 3). After PCR across their boundaries, the 42 and 93 bp deleted segments, and the 45 bp region between the site of the pm5.8 alteration and before the 42 bp deletion of pm5.3, were each found to be separate exons yielding larger or no bands with genomic DNA template compared with cDNA template. Introns were located within the 75 bp region between the 42 and 37 bp deletions and the 5&#39; boundary of the 37 bp deletion site. By contrast, no intron was identified at the 3&#39; boundary of the 37 bp deletion, but rather at the boundary of the adjacent 27 bp region and the 93 bp segment. This suggests that the 37 and 27 bp regions are combined to form a single exon. The existence of an intron at the position where the pm5.8 sequence differs from the other clones and the presence of a consensus splice donor sequence (AAGGTACAA) at the site of sequence divergence led us to examine if this clone resulted from the failure to splice this intron. Genomic DNA from placenta and cDNA made by priming poly (A)+ cytoplasmic RNA with random hexamers were used as template in PCR using On85 and On83 to amplify across the region of sequence difference (FIG. 8b). A band of 300 bp was produced from the pm5.8 control and from genomic DNA, but not from cDNA or other controls, showing the different sequence in pm5.8 is due to the failure of removal of this intron. 
     The technique of PCR has been applied to examine the alternative RNAs from different tissues using On85 prepared to a unique stretch of nucleotide sequence in the fourth SCR (Table 2) and On24 in the 3&#39; intranslated region beyond the alternatively spliced region. These were used in PCR using single stranded cDNA template reverse transcribed from RNA from many cell types including several placenta, peripheral blood leukocytes, leukaemia cells from patients with several different malignancies, spleen from trauma, leukaemia and lymphoma patients and cell lines derived from lymphoid and solid tumours. This analysis has shown several interesting points; i) the serine/threonine rich region of CD46 is composed of three separate exons, the third of these was deleted from the pm5.3 clone of the CD46 the second is the 45 bp region between the sites of the pm5.3 and pm5.8 deletions and the first is another 45 bp segment that is not represented in any of our placental cDNA clones; ii) the first of the three Ser/Thr region exons is rarely included in spliced RNA in placenta; iii) the third Ser/Thr region exon is rarely included in spliced RNA from several cell-lines, but is commonly spliced from RNA from placentae; iv) the second Ser/Thr region exon is alternatively spliced in the RNA of most tissues examined to date; v) one 93 bp exon containing an inframe termination condon is alternately spliced to yield two different cytoplasmic tails corresponding to the two cytoplasmic tails found in our pm5.1 and pm5.10 clones, all cell types examined to date have alternately spliced this exon in the pool of RNAs encoding several CD46 isotypes; vi) a third type of cytoplasmic tail used in the pm5.6 clone arises is some cell types due to the use of a cryptic splice acceptor sequence within the second of two exons encoding the transmembrance domain, generating a potentially secreted from of CD46. The PCR technique has been useful in mapping the intron/exon boundaries and identifying that different spliced RNA species exist in different cell types, however most CD46 RNA splice variants are common to all cell types. 
     Synthetic peptides corresponding to the alternative carboxyl-terminal sequences were used to generate antiserum specific for CD46 isoforms. These CD46 isotype-specific antisera were used in conjunction with our E4.3 monodonal antibody which reacts with all isotypes of CD46 in an enzyme linked immunosorbant assay that specifically detects CD46 variants containing the alternative fragments of nucleic acid identified in the alternative cDNA clones (pm5.1, 5.3, 5.6 and 5.8). 
     As will be apparent from the foregoing, the presence of spliced RNAs encoding CD46 was totally unexpected. 
     The above described Examples and conclusions were consolidated to characterize the molecular events leading to the isoform heterogeneity and polymorphic expression of CD46. In particular CD46 and RNA from different tissues was examined. Fourteen alternatively spliced RNA transcripts (several of which correspond to pm.5 series clones described above) were found to be differently expressed, explaining the heterogenous nature of CD46 in tissue. 
     In the following Examples materials and methods are as follows: 
     Tissues. Heparinized blood from healthy donors or leukemic patients with chronic or acute leukemia was fractionated by centrifugation through Ficoll-Paque (Pharmacia, Uppsala, Sweden) or Mono-Poly Resolving Medium (ICN, Irvine, Calif.) according to manufacturers instructions, to obtain lymphocytes and granulocytes. The EBV-transformed B cell line was produced in the Research Center for Cancer and Transplantation, The University of Melbourne. Full term placentae, a resected colon tumor and adjacent normal colon were separately homogenized for RNA extraction or teased into single cell suspensions for protein extraction. Semen samples obtained from healthy volunteers were used unfractionated for RNA extraction; spermatozoa were isolated from protein analysis by liquefying for 30 min at room temperature, centrifuging for 10 min at 700 g and washing (×4) with phosphate buffered saline. 
     Western blot. Cell lysates were prepared at 5×10 7  cells/ml (or 5×10 8  spermatozoa/ml) in 0.5% Nonidet-P40 in 10 mM Tris, 0.15 NaCl, pH 7.4 containing 1 mM EDTA and 1 mM phenylmethylsulfonyl fluoride. Cell lysates were acid/base dissociated by the techniques of Swack et al. (1987) Biotechniques, 5, 564-571 and 30 μg aliquots of protein (measured using the Biorad protein assay) were separated by SDS-PAGE under non-reducing conditions (see Laemmli (1970) Nature 227, 680-685). Proteins were electroblotted onto Immobilon P membrane (Millipore, Bedford, Mass.) and the remaining protein-binding sites were blocked with 2% casein. The CD46 isoforms were detected by the anti-CD46 monoclonal antibody, E4.3 described in Sparrow et al. (1983) Hum. Immunol. 7, 1-15, followed by incubation with horseradish peroxidase-conjugated anti-mouse IgG reagent (Dakopatts, Denmark) and visualisation with a cobalt-enhanced diaminobenzidine substrate. 
     cDNA synthesis and PCR amplification. Total RNA was prepared using the guanidinium isothiocyanate method (Chirgwin et al. (1979) Biochem. 18, 5294-5299). First strand cDNA was synthesized from 10 μg RNA in 25 μl using 200 U Murine Leukemia Virus reverse transcriptase (BRL, Gaithersburg, Md.), 0.25 mM dATP, dGTP, dTTP, dCTP (each) and 0.5 μg random hexamer oligonucleotides. PCR amplification was performed with 1 U `Replinase` (NEN, Boston, Mass.), 5 μl first strand cDNA, 0.2 mM dATP, dGTP, dTTP, dCTP (each) and 1 μM each of primers P1 and P2 in 50 mM Tris-HCl (pH9.0), 20 mM (NH 4 ) 2  SO 4 , 1.5 mM MgCl 2 , with or without 2.5 μCi α  32  P!dCTP. After 2 min at 95° C., 1 min), annealing (57° C., 2 min), and elongation (72° C., 2 min). Stringent precautions were taken to avoid cross-contamination between the RNA and cDNA samples, including their preparation in a laboratory in which CD46 clones and PCR products were never handled. Controls, including no cDNA and individual cDNA clones are templates, were included in each PCR to confirm that cross-contamination did not occur. 
     Analysis of PCR products. The amplified PCR product was extracted with chloroform, and 5 μl aliquots (5% of total product) were electrophoresed on 6% denaturing polyacrylamide gels and autoradiographed. For nucleotide sequencing, bands were excised and eluted in 0.5M NH 4  OAc, 10 mM MgOAc, 1 mM EDTA, 0.1% SDS for 16 hrs at 4° C., then precipitated with ethanol. 25% of each sample was reamplified with the same primers, extracted with chloroform and purified using Elutip-d columns (Schleicher and Schuell, Dassel, Germany). The sample was denatured with 0.2M NaOH, neutralised, precipitated with ethanol and sequenced using   32  P!-labelled primers and T7 DNA polymerase (Amersham, Poole, UK). To assess the expression of each splice variant in different tissues, cDNA was amplified in the absence of α  32  P!dCTP and electrophoresed on 6% denaturing polyacrylamide gels, electroblotted onto nylon membranes in 45 mM Tris-borate, 2 mM EDTA, fixed with 0.25M NaOH, 1.5M NaCl, and probed with oligonucleotides specific for alternatively spliced exons or groups of exons (see FIG. 12 for location of exons). 
     EXAMPLE 4 
     Tissue Specific Expression of CD46 Protein Isoforms 
     Western blot analysis of the different M r  forms of CD46 protein in 16 tissues demonstrated several important features of CD46 protein heterogeneity (FIG. 9). 1) A 76 kDa isoform (termed γ) was observed in EBV-transformed B cells (lane 5) and two of the three leukemic samples (lanes 8, 10). 2) Lymphocytes from healthy donors and cells from leukemic patients contained CD46 isoforms that resolves into two major clusters of bands at 66 and 56 kDa (termed α and β respectively, previously called upper and lower), whose relative abundance varied according to an autosomal codominant polymorphism (9). The three phenotypes are: α-predominant (lanes 1 and 8); α and β in equal proportions (lanes 2 and 9); and β-predominant (lanes 3 and 10). 3) Some placentae expressed an isoform of 63 kDa (termed ξ, lanes 14-16), not seen in the other tissues, in addition to the α and β isoforms (lanes 13-16). 4) Spermatozoa expressed a unique 35 kDa form of CD46 (termed δ, lanes 6 and 7) not found in the other tissues examined, they did not express the α and β isoforms. It was also noted that granulocytes showed isoforms up to 78 kDa (termed ζ) together with the typical α and β isoforms (lane 4). Both normal colon and colon carcinoma tissue from a single donor expressed predominantly α CD46 isoforms with no difference between malignant and normal tissue (lanes 11 and 12). Thus, there are two types of polymorphism apparent here: a) allelic differences in the proportions of α and β isoforms; and b) tissue differences in expression of the α, β, γ, δ, ξ and ζ isoforms. 
     EXAMPLE 5 
     Structure of CD46 RNA Transcripts 
     To investigate alternative splicing of CD46 mRNA, we first identified all alternatively spliced RNAs from the tissues described above, a number of placentae and lymphocyte samples, and from hemopoietic cell lines. RNA from these tissues was converted to cDNA and amplified, and all new splice variants identified were sequenced. No alternative splicing of RNA in the SCR region was observed (data not shown), thus excluding exon 1-6 (FIGS. 9, 12) from contributing to protein heterogeneity. Amplification and sequencing between the fourth SCR and the 3&#39; untranslated region (primers P1 and P2, FIG. 10A), however, identified 14 differently spliced RNAs. Sequencing indicated that most transcripts were derived from the alternative splicing of exons 8, 9, 12 and 13 shown in FIG. 10B, FIG. 12, but other RNAs contained new sequence immediately downstream of the SCR region (FIG. 10C, SEQ ID NOS:11 and 12). This sequence was designated exon 7 (STP A) because of its position in CD46 mRNA and its derived amino acid sequence, and completes the description of the exons identified in genomic clones for CD46. The nucleotide sequence of exon 7 was homologous to the sequence of the two other STP-encoding exons, as there was 69% identity with exon 8, (SEQ ID NO:17), and 62% identity with exon 9. The splicing of exons 7, 8 and 9 (SEQ ID NO:19) did not change the reading frame but effected the number of potential O-glycosylation sites as this region is rich in Ser and Thr residues. Exon 10 is of unknown UK significance and its boundary with exon 11 not yet comprehensively delimited. Exon 13 encoded a cytoplasmic tail (FIG. 10, D3, SEQ ID NO:15) or all (FIG. 10, D4, SEQ ID NO:16) of exon 12 changed the reading frame, giving rise to a third cytoplasmic tail and removing part of the transmembrane region. Thus, alternative splicing of five exons (7, 8, 9, 12 and 13) results in CD46 RNAs encoding protein isoforms with three different cytoplasmic tails and with differences in the length of both the hydrophobic transmembrane region and the STP-rich region of the glycoprotein. 
     EXAMPLE 6 
     Tissue Distribution of Alternatively Spliced CD46 RNAs 
     To determine the relative expression of the 14 RNA transcripts in different tissues, RNA from each tissue examined in FIG. 9 was converted to cDNA and amplified by PCR using primers P1 and P2 (SEQ ID NOS:31 and 32, respectively), spanning the alternatively spliced region. Amplification of CD46 cDNA clones (FIG. 11A) and multiple analysis of RNA samples showed that, although amplification did not allow the estimation of the total amount of CD46 in the sample, it is provided an accurate and reproducible estimation of the relative proportions of the different CD46 RNA variants. We note that no additional splice patterns were produced by this procedure, indicating that homologous recombination during amplification did not occur in these experiments. When α  32  P!dCTP was incorporated into the PCR products, the 14 transcripts migrated as only 6 bands after electrophoresis (FIG. 11B) due to the similar size of some of the exons. To identify the distribution of each transcript, unlabelled PCR products were electrophoresed, transferred onto nylon filters and probed with oligonucleotides specific for each splice variant (see FIG. 12 for location of probes). Fifteen oligonucleotides were used to determine the distribution of the 14 RNAs (representative gels in FIGS. 11C-I). 
     Five observations merit particular attention: 1) CD46 RNAs containing exon 7 (FIG. 11C) were preferentially expressed in EBV-transformed B cells (lane 5) and in two leukemic samples (lanes 8 and 10). RNAs containing exon 7 were also expressed in placentae, although to a lesser extent (lanes 13-16). 2) The ratio of the quantity of transcripts containing exon 8, to transcripts in which exon 8 have been deleted, was equivalent to the ratio of α and β isoforms detected on western blots in every tissue excepting sperm (FIGS. 9, 11D, 11E). This demonstrated that the α isoforms were derived from RNAs in which exon 8 had been inserted, and the β isoforms from RNAs in which exon 8 had been deleted. 3) Probing for the deletion of exon 9 demonstrated that RNA transcripts of this type occurred in 3 or the 4 placentae examined (FIG. 11F, lanes 14-16). 4) A transcript in which exons 12 and 13 were deleted occurred only in semen (FIG. 11I, lanes 6 and 7). 5) RNA transcripts both with and without exon 13 were present in every tissue and the ratio of these two groups of transcripts was similar in all tissues (FIG. 11G, 11H), Thus, each splice variant displayed a different distribution of expression, with tissue specific and allelic variations in splicing and with some RNAs expressed in every tissue. 
     EXAMPLE 7 
     Association of CD46 RNA Splice Variants with Protein Isoforms 
     Apart from three cases listed below, all of the different protein isoforms observed in each of the 16 tissues investigated (FIG. 9) correlated with the expression of a transcript with the appropriate sequence (FIGS. 11a-11i); all of this data is summarised in FIG. 12. FIGS. 13a-13g summarizes the nucleic acid sequence, amino acid assignments and exon assignments of exons 7 to 14. 
     FIG. 13-a includes SEQ ID NOS:11 and 12; FIG. 13-b includes SEQ ID NOS:17 and 18; FIG. 13-c includes SEQ ID NOS:19 and 20; FIG. 13-d includes SEQ ID NOS:21 and 22; FIG. 13-e includes SEQ ID NOS:23, 24 and 25; FIG. 13-f includes SEQ ID NOS:26 and 27; and FIG. 13-g includes SEQ ID NOS:28, 29 and 30. 
     Deletion of exons 12 and 13 would have little effect on protein M r , as they code for few amino acids, but exons 7, 8 and 9, which encode STP rich protein, could be expected to significantly change the M r  due to O-linked glycosylation of the mature protein. Transcript a has no deletions and gives rise to the γ isoform of 74 kDa seen in EBV-transformed and leukemic cells. Transcript c has deleted exon 7 and gives rise to an α isomer of CD46 (66 kDa). The deletion of exon 8 in transcript e gives rise to the β isoform of CD46 (56 kDa). Transcript g has deleted exon 9 and has only been found in low levels in some placentae. The expression of the corresponding protein was too low to be detected by western blot. Transcript i has deleted exons 7 and 9, is expressed by some placentae, and has a corresponding isoform of 63 kDa (ξ). Transcript k, in which all three STP-encoding exons (7-9) have been deleted, is expressed by some placentae at sufficiently high levels to encode detectable protein, however distortion in the gel at this site obscured detection. Transcripts b, d, f, h, j and l are similar to transcripts a, c, e, g, i and k respectively, but have also deleted exon 13, and so encode an alternative cytoplasmic tail. Neither transcript m (generated by the aberrant splicing of exon 12, described in 12), nor a corresponding protein isoform was detected in these tissues however this isoform may define a soluble form, as seen for instance in seminal fluid. Transcript n is expressed only in sperm and is derived from the deletion of exons 7, 8, 12 and 13, giving rise to a protein of 35 kDa (δ). Thus in almost all cases, the transcripts produced after the insertion or deletion of various exons were translated to produce the appropriate M r  protein isoform. 
     Three cases in which the distribution of RNA transcripts did not correlate with the distribution of their corresponding protein isoforms were noted. (i) A unique higher M r  protein isoform was found in granulocytes and no unique RNA transcript was observed, this possibly reflects cell-specific differences in glycosylation. (ii) Some RNA transcripts predicted to encode protein isoforms of lymphocytes were detected in semen, however these protein isoforms were not detected in isolated spermatozoa, indicating that semen RNA contains RNA from other cells. (iii) The 35 kDa protein isoform observed in spermatozoa was of slightly lower M r  than that predicted from the RNA sequence. This could be due to the alternative usage of translational start sites previously suggested for other molecules in sperm, or possibly to different glycosylation patterns. These discrepancies suggest that, although the primary determinant of CD46 protein heterogeneity is the expression of alternatively spliced RNA, other factors can influence expression. 
     It will be apparent from Examples 4 to 7 describing tissues from a single donor and the same tissues from different donors that CD46 displays both a genetic polymorphism and an extensive tissue polymorphism, with 14 different mRNA transcripts, coding for different protein isoforms, identified in 16 tissues. In the genetic polymorphism, the difference in the two alleles determines the splicing of exon 8, which gives rise to variable proportions of the α (66 kDa) and β (56 kDa) chains with αα, αβ and ββ phenotypes. The second, and perhaps more interesting polymorphism, is that which occurs in different tissues and which gives rise to additional different protein isoforms of CD46 described in FIG. 12. These are: the γ isoform (74 kDa, transcripts a, b); the δ isoform of sperm 35 kDa, transcript n and the ξ isoform of placenta (63 kDa, transcripts i, j). 
     Tumour cells, such as EBV-transformed cells and leukemic cells, have the longest STP region, with no exons deleted (FIGS. 4a-4e). The reason for this is not apparent, but may extend the active part of the molecule above the more extensive glycocalyx of tumour cells. By contrast some placentae may have only a short stalk as exon 9 is deleted. The placenta-specific isoforms may be related to the allotypic reactivity of TLX. 
     There are also transcripts for three cytoplasmic tails, two of which appear to be present in all cells, and the third in spermatozoa. Example 8 below suggests that these tails generate different intracellular signals. The deletion of exons in the cytoplasmic region do not significantly change the M r  of the protein and are not easily resolved by SDS-PAGE (FIG. 12), however the expression of each cytoplasmic tail has been confirmed using antipeptide antibodies. It is likely that more (native) protein isoforms exist in other tissues. 
     EXAMPLE 8 
     The sequences of the different CD46 variants were subjected to a computer analysis and homologies with sequences of known function were determined using &#34;Prosearch&#34;: Lee F. Kolakowski&#39;s search of protein sequences against Amos Bairoch&#39;s PROSITE database. Sequences corresponding to known phosphorylation sites and nuclear localisation sites were identified. 
     (a) A sequence associated with cyclic AMP-dependent phosphorylation (KKGT) was identified in the &#34;CYT1&#34; cytoplasmic tail corresponding to the pm5.1 clone. This tail also contained the consensus sequence for Protein kinase C dependent phosphorylation (THR). 
     (b) Sequences associated with casein kinase 2 phosphorylation were identified in both the CYT 1 (pm5.1) and CYT 2 (pm5.3, pm5.10) cytoplasmic tails (THRE and TPAE respectively). 
     (c) The sequence KKKGK of the CYT 2 cytoplasmic tail has been identified as a nuclear localisation signal. 
     These results are suggestive of a signal role possibly phosphorylation based for portions of the CD46 molecule remote from the SCR domains active in the complement cascade. The activity status of the SCR domains could trigger this signal role through, for instance, conformation changes in the molecule. The signal is conceivably implicated in feedback or cascade enhancement roles. 
     EXAMPLE 9 
     complete cDNA and Amino Acid SequenceS 
     FIGS. 14a14-d depict a cDNA sequence and amino acid sequence for CD46 isoform PM5.3. The coding sequence is at nucleotides 83-1192. The signal polypeptide is encoded at nucleotides 83-184, and the mature polypeptide is encoded is encoded at nucleotides 185-1192. Nucleotides 939-983 encode exon 8 (STP-B). Nucleotides 1123-1247 encode exon 14 (CYT-2 and the 3&#39; UT). 
     FIG. 15a-15e depict a cDNA sequence and amino acid sequence for CD46 isoform PM5.6. The coding sequence is at nucleotides 29-1147. The signal polypeptide is encoded at nucleotides 29-130, and the mature polypeptide is encoded at nucleotides 131-1147. Nucleotides 885-971 encode exons 8 and 9 (STP-BC). Exon 11 is intact, and ends at nucleotide 1046. A cryptic splice-site has led to loss of exon 12A, causing a frame-shift in translation of subsequent exons. Exon 12B (nucleotides 1047-73) is followed by exon 14 (nucleotides 1074-1986). Translation of exons 12B and 14 predicts a unique cytoplasmic tail of about 34 amino acids. 
     FIGS. 16a-16d depict a cDNA sequence and amino acid sequence for CD46 isoform PM5.8. The coding sequence is at nucleotides 94-1065. The signal polypeptide is encoded at nucleotides 94-195, and the mature polypeptide is encoded at nucleotides 196-1065. Exon 6 is intact, and ends at nucleotide 949. Intron 6 (413 nucleotides) has not been spliced out, and a read-through translation of the 353 nucleotide portion of intron 6 predicts a unique C-terminal sequence of 39 amino acids. PM5.8 includes 353 of the 413 nucleotides of intron 6 (85%). 
     It is to be understood that the description, specific examples and data, while indicating preferred embodiments, are given by way of illustration and exemplification and are not intended to limit the present invention. Various changes and modifications within the present invention will become apparent 
     The drawings herewith are incorporated in this specification. 
     
         __________________________________________________________________________SEQUENCE LISTING(1) GENERAL INFORMATION:(iii) NUMBER OF SEQUENCES: 46(2) INFORMATION FOR SEQ ID NO:1:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 1659 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: double(D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(vii) IMMEDIATE SOURCE:(B) CLONE: pm5.1(ix) FEATURE:(A) NAME/KEY: CDS(B) LOCATION: 34..1167(ix) FEATURE:(A) NAME/KEY: sig.sub.-- peptide(B) LOCATION: 34..135(ix) FEATURE:(A) NAME/KEY: mat.sub.-- peptide(B) LOCATION: 136..1167(xi) SEQUENCE DESCRIPTION: SEQ ID NO:1:AATTCGGGGATAACAGCGTCTTCCGCGCCGCGCATGGAGCCTCCCGGCCGCCGC54MetGluProProGlyArgArg34-30GAGTGTCCCTTTCCTTCCTGGCGCTTTCCTGGGTTGCTTCTGGCGGCC102GluCysProPheProSerTrpArgPheProGlyLeuLeuLeuAlaAla25-20-15ATGGTGTTGCTGCTGTACTCCTTCTCCGATGCCTGTGAGGAGCCACCA150MetValLeuLeuLeuTyrSerPheSerAspAlaCysGluGluProPro10- 515ACATTTGAAGCTATGGAGCTCATTGGTAAACCAAAACCCTACTATGAG198ThrPheGluAlaMetGluLeuIleGlyLysProLysProTyrTyrGlu101520ATTGGTGAACGAGTAGATTATAAGTGTAAAAAAGGATACTTCTATATA246IleGlyGluArgValAspTyrLysCysLysLysGlyTyrPheTyrIle253035CCTCCTCTTGCCACCCATACTATTTGTGATCGGAATCATACATGGCTA294ProProLeuAlaThrHisThrIleCysAspArgAsnHisThrTrpLeu404550CCTGTCTCAGATGACGCCTGTTATAGAGAAACATGTCCATATATACGG342ProValSerAspAspAlaCysTyrArgGluThrCysProTyrIleArg556065GATCCTTTAAATGGCCAAGCAGTCCCTGCAAATGGGACTTACGAGTTT390AspProLeuAsnGlyGlnAlaValProAlaAsnGlyThrTyrGluPhe70758085GGTTATCAGATGCACTTTATTTGTAATGAGGGTTATTACTTAATTGGT438GlyTyrGlnMetHisPheIleCysAsnGluGlyTyrTyrLeuIleGly9095100GAAGAAATTCTATATTGTGAACTTAAAGGATCAGTAGCAATTTGGAGC486GluGluIleLeuTyrCysGluLeuLysGlySerValAlaIleTrpSer105110115GGTAAGCCCCCAATATGTGAAAAGGTTTTGTGTACACCACCTCCAAAA534GlyLysProProIleCysGluLysValLeuCysThrProProProLys120125130ATAAAAAATGGAAAACACACCTTTAGTGAAGTAGAAGTATTTGAGTAT582IleLysAsnGlyLysHisThrPheSerGluValGluValPheGluTyr135140145CTTGATGCAGTAACTTATAGTTGTGATCCTGCACCTGGACCAGATCCA630LeuAspAlaValThrTyrSerCysAspProAlaProGlyProAspPro150155160165TTTTCACTTATTGGAGAGAGCACGATTTATTGTGGTGACAATTCAGTG678PheSerLeuIleGlyGluSerThrIleTyrCysGlyAspAsnSerVal170175180TGGAGTCGTGCTGCTCCAGAGTGTAAAGTGGTCAAATGTCGATTTCCA726TrpSerArgAlaAlaProGluCysLysValValLysCysArgPhePro185190195GTAGTCGAAAATGGAAAACAGATATCAGGATTTGGAAAAAAATTTTAC774ValValGluAsnGlyLysGlnIleSerGlyPheGlyLysLysPheTyr200205210TACAAAGCAACAGTTATGTTTGAATGCGATAAGGGTTTTTACCTCGAT822TyrLysAlaThrValMetPheGluCysAspLysGlyPheTyrLeuAsp215220225GGCAGCGACACAATTGTCTGTGACAGTAACAGTACTTGGGATCCCCCA870GlySerAspThrIleValCysAspSerAsnSerThrTrpAspProPro230235240245GTTCCAAAGTGTCTTAAAGTGTCGACTTCTTCCACTACAAAATCTCCA918ValProLysCysLeuLysValSerThrSerSerThrThrLysSerPro250255260GCGTCCAGTGCCTCAGGTCCTAGGCCTACTTACAAGCCTCCAGTCTCA966AlaSerSerAlaSerGlyProArgProThrTyrLysProProValSer265270275AATTATCCAGGATATCCTAAACCTGAGGAAGGAATACTTGACAGTTTG1014AsnTyrProGlyTyrProLysProGluGluGlyIleLeuAspSerLeu280285290GATGTTTGGGTCATTGCTGTGATTGTTATTGCCATAGTTGTTGGAGTT1062AspValTrpValIleAlaValIleValIleAlaIleValValGlyVal295300305GCAGTAATTTGTGTTGTCCCGTACAGATATCTTCAAAGGAGGAAGAAG1110AlaValIleCysValValProTyrArgTyrLeuGlnArgArgLysLys310315320325AAAGGCACATACCTAACTGATGAGACCCACAGAGAAGTAAAATTTACT1158LysGlyThrTyrLeuThrAspGluThrHisArgGluValLysPheThr330335340TCTCTCTGAGAAGGAGAGATGAGAGAAAGGTTTGATTTTATCATTAAAAGGAAAGC1214SerLeuAGATGGTGGAGCTGAATATGCCACTTACCAGACTAAATCAACCACTCCAGCAGAGCAGAG1274AGGCTGAATAGATTCCACAACCTGGTTTGCCAGTTCATCTTTTGACTCTATTAAAATCTT1334CAATAGTTGTTATTCTGTAGTTTCACTCTCATGAGTGCAACTGTGGCTTAGCTAATATTG1394CAATGTGGCTTGAATGTAGGTAGCATCCTTTGATGCTTCTTTGAAACTTGTATGAATTTG1454GGTATGAACAGATTGCCTGCTTTCCCTTAAATAACACTTAGATTTATTGGACCAGTCAGC1514ACAGCATGCCTGGTTGTATTAAAGCAGGGATATGCTGTATTTTATAAAATTGGCAAAATT1574AGAGAAATATAGTTCACAATGAAATTATATTTTCTTTGTAAAGAAAGTGGCTTGAAATCT1634TTTTTGTTCAAAGATTAATGCCCCG1659(2) INFORMATION FOR SEQ ID NO:2:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 377 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(xi) SEQUENCE DESCRIPTION: SEQ ID NO:2:MetGluProProGlyArgArgGluCysProPheProSerTrpArgPhe34- 30-25-20ProGlyLeuLeuLeuAlaAlaMetValLeuLeuLeuTyrSerPheSer15-10-5AspAlaCysGluGluProProThrPheGluAlaMetGluLeuIleGly1510LysProLysProTyrTyrGluIleGlyGluArgValAspTyrLysCys15202530LysLysGlyTyrPheTyrIleProProLeuAlaThrHisThrIleCys354045AspArgAsnHisThrTrpLeuProValSerAspAspAlaCysTyrArg505560GluThrCysProTyrIleArgAspProLeuAsnGlyGlnAlaValPro657075AlaAsnGlyThrTyrGluPheGlyTyrGlnMetHisPheIleCysAsn808590GluGlyTyrTyrLeuIleGlyGluGluIleLeuTyrCysGluLeuLys95100105110GlySerValAlaIleTrpSerGlyLysProProIleCysGluLysVal115120125LeuCysThrProProProLysIleLysAsnGlyLysHisThrPheSer130135140GluValGluValPheGluTyrLeuAspAlaValThrTyrSerCysAsp145150155ProAlaProGlyProAspProPheSerLeuIleGlyGluSerThrIle160165170TyrCysGlyAspAsnSerValTrpSerArgAlaAlaProGluCysLys175180185190ValValLysCysArgPheProValValGluAsnGlyLysGlnIleSer195200205GlyPheGlyLysLysPheTyrTyrLysAlaThrValMetPheGluCys210215220AspLysGlyPheTyrLeuAspGlySerAspThrIleValCysAspSer225230235AsnSerThrTrpAspProProValProLysCysLeuLysValSerThr240245250SerSerThrThrLysSerProAlaSerSerAlaSerGlyProArgPro255260265270ThrTyrLysProProValSerAsnTyrProGlyTyrProLysProGlu275280285GluGlyIleLeuAspSerLeuAspValTrpValIleAlaValIleVal290295300IleAlaIleValValGlyValAlaValIleCysValValProTyrArg305310315TyrLeuGlnArgArgLysLysLysGlyThrTyrLeuThrAspGluThr320325330HisArgGluValLysPheThrSerLeu335340(2) INFORMATION FOR SEQ ID NO:3:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 483 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(vii) IMMEDIATE SOURCE:(A) LIBRARY: pm5.6(xi) SEQUENCE DESCRIPTION: SEQ ID NO:3:TGTTCAAAGATTAATGCCAACTCTTAAGATTATTCTTTCACCAACTATAGAATGTATTTT60ATATATCGTTCATTGTAAAAAGCCCTTAAAAATATGTGTATACTACTTTGGCTCTTGTGC120ATAAAAACAAGAACACTGAAAATTGGGAATATGCACAAACTTGGCTTCTTTAACCAAGAA180TATTATTGGAAAAGTTCTCTAAAAGTTAATAGGGTAAATTCTCTATTTTTTGTAATGTGT240TCGGTGATTTCAGAAAGCTAGAAAGTGTATGTGTGGCATTTGTTTTCACTTTTTAAAACA300TCCCTAACTGATCGAATATATCAGTAATTTCAGAATCAGATGCATCCTTTCATAAGAAGT360GAGAGGACTCTGACAGCCATAACAGGAGTGCCACTTCATGGTGCGAAGTGAACACTGTAG420TCTTGTTGTTTTCCCAAAGAGAACTCCGTATGTTCTCTTAGGTTGAGTAACCCACTCTGC480CCG483(2) INFORMATION FOR SEQ ID NO:4:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 420 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: double(D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(xi) SEQUENCE DESCRIPTION: SEQ ID NO:4:GTGTCGACTTCTTCCACTACAAAATCTCCAGCGTCCAGTGCCTCAGGTCCTAGGCCTACT60TACAAGCCTCCAGTCTCAAATTATCCAGGATATCCTAAACCTGAGGAAGGAATACTTGAC120AGTTTGGATGTTTGGGTCATTGCTGTGATTGTTATTGCCATAGTTGTTGGAGTTGCAGTA180ATTTGTGTTGTCCCGTACAGATATCTTCAAAGGAGGAAGAAGAAAGGCACATACCTAACT240GATGAGACCCACAGAGAAGTAAAATTTACTTCTCTCTGAGAAGGAGAGATGAGAGAAAGG300TTTGATTTTATCATTAAAAGGAAAGCAGATGGTGGAGCTGAATATGCCACTTACCAGACT360AAATCAACCACTCCAGCAGAGCAGAGAGGCTGAATAGATTCCACAACCTGGTTTGCCAGT420(2) INFORMATION FOR SEQ ID NO:5:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 92 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: pm5.1(xi) SEQUENCE DESCRIPTION: SEQ ID NO:5:ValSerThrSerSerThrThrLysSerProAlaSerSerAlaSerGly151015ProArgProThrTyrLysProProValSerAsnTyrProGlyTyrPro202530LysProGluGluGlyIleLeuAspSerLeuAspValTrpValIleAla354045ValIleValIleAlaIleValValGlyValAlaValIleCysValVal505560ProTyrArgTyrLeuGlnArgArgLysLysLysGlyThrTyrLeuThr65707580AspGluThrHisArgGluValLysPheThrSerLeu8590(2) INFORMATION FOR SEQ ID NO:6:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 88 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: pm5.6(xi) SEQUENCE DESCRIPTION: SEQ ID NO:6:ValSerThrSerSerThrThrLysSerProAlaSerSerAlaSerGly151015ProArgProThrTyrLysProProValSerAsnTyrProGlyTyrPro202530LysProGluGluGlyIleLeuAspSerLeuAspValTrpValIleAla354045ValIleValIleAlaIleAspIlePheLysGlyGlyArgArgLysGly505560LysGlnMetValGluLeuAsnMetProLeuThrArgLeuAsnGlnPro65707580LeuGlnGlnSerArgGluAlaGlu85(2) INFORMATION FOR SEQ ID NO:7:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 99 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: pm5.10(xi) SEQUENCE DESCRIPTION: SEQ ID NO:7:ValSerThrSerSerThrThrLysSerProAlaSerSerAlaSerGly151015ProArgProThrTyrLysProProValSerAsnTyrProGlyTyrPro202530LysProGluGluGlyIleLeuAspSerLeuAspValTrpValIleAla354045ValIleValIleAlaIleValValGlyValAlaValIleCysValVal505560ProTyrArgTyrLeuGlnArgArgLysLysLysGlyLysAlaAspGly65707580GlyAlaGluTyrAlaThrTyrGlnThrLysSerThrThrProAlaGlu859095GlnArgGly(2) INFORMATION FOR SEQ ID NO:8:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 85 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: pm5.3(xi) SEQUENCE DESCRIPTION: SEQ ID NO:8:ValSerThrSerSerThrThrLysSerProAlaSerSerAlaSerGly151015TyrProLysProGluGluGlyIleLeuAspSerLeuAspValTrpVal202530IleAlaValIleValIleAlaIleValValGlyValAlaValIleCys354045ValValProTyrArgTyrLeuGlnArgArgLysLysLysGlyLysAla505560AspGlyGlyAlaGluTyrAlaThrTyrGlnThrLysSerThrThrPro65707580AlaGluGlnArgGly85(2) INFORMATION FOR SEQ ID NO:9:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 356 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: double(D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(vii) IMMEDIATE SOURCE:(B) CLONE: pm5.8(ix) FEATURE:(A) NAME/KEY: CDS(B) LOCATION: 1..120(xi) SEQUENCE DESCRIPTION: SEQ ID NO:9:GGTACAAAGGTTATCTTTTTTCTGTCTTGGTTTGTTATTGTTGTTGCT48GlyThrLysValIlePhePheLeuSerTrpPheValIleValValAla151015GTTCATTTTAGACTTTATTTCTTTGATATTAACTATCAGTCATACAAA96ValHisPheArgLeuTyrPhePheAspIleAsnTyrGlnSerTyrLys202530ATAACTGAAAAGAAACAATTTTAGTATTTAACTCTGTCTTGTATTCATTTC147IleThrGluLysLysGlnPhe3540TATGCCAGATGAATGACACGAAATTCACATAAAATTCTGCTGTTGTGATTTTTTGTGCTT207TTCCAGGGTTCTTAGCACGTTATGTACATTGCATGGGTATATGCTTTTAATATTTTTATG267TATAAAAAGTGAATTACAACAACTTTTTGGAATTGAAACATGGGCATTTTTATCTAAGTA327AGTCAACAATGGCATAATTCATATACCCG356(2) INFORMATION FOR SEQ ID NO:10:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 39 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(xi) SEQUENCE DESCRIPTION: SEQ ID NO:10:GlyThrLysValIlePhePheLeuSerTrpPheValIleValValAla151015ValHisPheArgLeuTyrPhePheAspIleAsnTyrGlnSerTyrLys202530IleThrGluLysLysGlnPhe35(2) INFORMATION FOR SEQ ID NO:11:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 45 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: double(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: exon 7(xi) SEQUENCE DESCRIPTION: SEQ ID NO:11:TGCTGCCTCCATCTAGTACAAAACCTCCAGCTTTGAGTCATTCAG45(2) INFORMATION FOR SEQ ID NO:12:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 16 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(xi) SEQUENCE DESCRIPTION: SEQ ID NO:12:ValLeuProProSerSerThrLysProProAlaSerSerHisSerVal151015(2) INFORMATION FOR SEQ ID NO:13:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 38 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(xi) SEQUENCE DESCRIPTION: SEQ ID NO:13:ValValGlyValAlaValIleCysValValProTyrArgTyrLeuGln151015ArgArgLysLysLysGlyThrTyrLeuThrAspGluThrHisArgGlu202530ValLysPheThrSerLeu35(2) INFORMATION FOR SEQ ID NO:14:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 45 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(xi) SEQUENCE DESCRIPTION: SEQ ID NO:14:ValValGlyValAlaValIleCysValValProTyrArgTyrLeuGln151015ArgArgLysLysLysGlyLysAlaAspGlyGlyAlaGluTyrAlaThr202530TyrGlnThrLysSerThrThrProAlaGluGlnArgGly354045(2) INFORMATION FOR SEQ ID NO:15:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 34 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(xi) SEQUENCE DESCRIPTION: SEQ ID NO:15:AspIlePheLysGlyGlyArgArgLysGlyLysGlnMetValGluLeu151015AsnMetProLeuThrArgLeuAsnGlnProLeuGlnGlnSerArgGlu202530AlaGlu(2) INFORMATION FOR SEQ ID NO:16:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 25 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(xi) SEQUENCE DESCRIPTION: SEQ ID NO:16:GlyLysGlnMetValGluLeuAsnMetProLeuThrArgLeuAsnGln151015ProLeuGlnGlnSerArgGluAlaGlu2025(2) INFORMATION FOR SEQ ID NO:17:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 45 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: double(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: exon 8(xi) SEQUENCE DESCRIPTION: SEQ ID NO:17:TGTCGACTTCTTCCACTACAAAATCTCCAGCGTCCAGTGCCTCAG45(2) INFORMATION FOR SEQ ID NO:18:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 15 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(xi) SEQUENCE DESCRIPTION: SEQ ID NO:18:ValSerThrSerSerThrThrLysSerProAlaSerSerAlaSer151015(2) INFORMATION FOR SEQ ID NO:19:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 42 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: double(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: exon 9(xi) SEQUENCE DESCRIPTION: SEQ ID NO:19:GTCCTAGGCCTACTTACAAGCCTCCAGTCTCAAATTATCCAG42(2) INFORMATION FOR SEQ ID NO:20:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 14 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(xi) SEQUENCE DESCRIPTION: SEQ ID NO:20:GlyProArgProThrTyrLysProProValSerAsnTyrPro1510(2) INFORMATION FOR SEQ ID NO:21:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 74 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: double(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: exons 10/11(xi) SEQUENCE DESCRIPTION: SEQ ID NO:21:GATATCCTAAACCTGAGGAAGGAATACTTGACAGTTTGGATGTTTGGGTCATTGCTGTGA60TTGTTATTGCCATA74(2) INFORMATION FOR SEQ ID NO:22:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 25 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(xi) SEQUENCE DESCRIPTION: SEQ ID NO:22:GlyTyrProLysProGluGluGlyIleLeuAspSerLeuAspValTrp151015ValIleAlaValIleValIleAlaIle2025(2) INFORMATION FOR SEQ ID NO:23:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 65 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: double(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: exon 12(xi) SEQUENCE DESCRIPTION: SEQ ID NO:23:GTTGTTGGAGTTGCAGTAATTTGTGTTGTCCCGTACAGATATCTTCAAAGGAGGAAGAAG60AAAGG65(2) INFORMATION FOR SEQ ID NO:24:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 22 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(xi) SEQUENCE DESCRIPTION: SEQ ID NO:24:ValValGlyValAlaValIleCysValValProTyrArgTyrLeuGln151015ArgArgLysLysLysGly20(2) INFORMATION FOR SEQ ID NO:25:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 9 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(xi) SEQUENCE DESCRIPTION: SEQ ID NO:25:AspIlePheLysGlyGlyArgArgLys15(2) INFORMATION FOR SEQ ID NO:26:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 58 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: double(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: exon 13(ix) FEATURE:(A) NAME/KEY: CDS(B) LOCATION: 2..49(xi) SEQUENCE DESCRIPTION: SEQ ID NO:26:CACATACCTAACTGATGAGACCCACAGAGAAGTAAAATTTACTTCT46ThrTyrLeuThrAspGluThrHisArgGluValLysPheThrSer151015CTCTGAGAAGGA58Leu(2) INFORMATION FOR SEQ ID NO:27:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 16 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(xi) SEQUENCE DESCRIPTION: SEQ ID NO:27:ThrTyrLeuThrAspGluThrHisArgGluValLysPheThrSerLeu151015(2) INFORMATION FOR SEQ ID NO:28:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 84 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: double(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: exon 14(ix) FEATURE:(A) NAME/KEY: CDS(B) LOCATION: 2..73(xi) SEQUENCE DESCRIPTION: SEQ ID NO:28:GAAAGCAGATGGTGGAGCTGAATATGCCACTTACCAGACTAAATCA46LysAlaAspGlyGlyAlaGluTyrAlaThrTyrGlnThrLysSer151015ACCACTCCAGCAGAGCAGAGAGGCTGAATAGATTCCAC84ThrThrProAlaGluGlnArgGly20(2) INFORMATION FOR SEQ ID NO:29:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 23 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(xi) SEQUENCE DESCRIPTION: SEQ ID NO:29:LysAlaAspGlyGlyAlaGluTyrAlaThrTyrGlnThrLysSerThr151015ThrProAlaGluGlnArgGly20(2) INFORMATION FOR SEQ ID NO:30:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 25 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(xi) SEQUENCE DESCRIPTION: SEQ ID NO:30:GlyLysGlnMetValGluLeuAsnMetProLeuThrArgLeuAsnGln151015ProLeuGlnGlnSerArgGluAlaGlu2025(2) INFORMATION FOR SEQ ID NO:31:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 18 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: p1(xi) SEQUENCE DESCRIPTION: SEQ ID NO:31:GGCAGCGACACAATTGTC18(2) INFORMATION FOR SEQ ID NO:32:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 19 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: p2(xi) SEQUENCE DESCRIPTION: SEQ ID NO:32:CAGCCTCTCTGCTCTGCTG19(2) INFORMATION FOR SEQ ID NO:33:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 32 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: exons 6-7(xi) SEQUENCE DESCRIPTION: SEQ ID NO:33:CTAGATGGAGGCAGCACTTTAAGACACTTTGG32(2) INFORMATION FOR SEQ ID NO:34:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 30 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: exons 8-9(xi) SEQUENCE DESCRIPTION: SEQ ID NO:34:AAGTAGGCCTAGGACCTGAGGCACTGGACG30(2) INFORMATION FOR SEQ ID NO:35:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 31 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: exons 6-9(xi) SEQUENCE DESCRIPTION: SEQ ID NO:35:TAAGTAGGCCTAGGACCTTTAAGACACTTTG31(2) INFORMATION FOR SEQ ID NO:36:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 30 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: exons 8-10(xi) SEQUENCE DESCRIPTION: SEQ ID NO:36:CAGGTTTAGGATATCCTGAGGCACTGGACG30(2) INFORMATION FOR SEQ ID NO:37:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 36 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: exon 13(xi) SEQUENCE DESCRIPTION: SEQ ID NO:37:CCTTCTCAGAGAGAAGTAAATTTTACTTCTCTGTGG36(2) INFORMATION FOR SEQ ID NO:38:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 31 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: exons 12-14(xi) SEQUENCE DESCRIPTION: SEQ ID NO:38:CCACCATCTGCTTTCCCTTTCTTCTTCCTCC31(2) INFORMATION FOR SEQ ID NO:39:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 32 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(vii) IMMEDIATE SOURCE:(B) CLONE: exons 11-14(xi) SEQUENCE DESCRIPTION: SEQ ID NO:39:CCACCATCTGCTTTCCTATGGCAATAACAATC32(2) INFORMATION FOR SEQ ID NO:40:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 15 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(xi) SEQUENCE DESCRIPTION: SEQ ID NO:40:TGTTGTCCCGTACAG15(2) INFORMATION FOR SEQ ID NO:41:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 1247 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(ix) FEATURE:(A) NAME/KEY: CDS(B) LOCATION: 83..1192(ix) FEATURE:(A) NAME/KEY: mat.sub.-- peptide(B) LOCATION: 185..1192(xi) SEQUENCE DESCRIPTION: SEQ ID NO:41:AATTCGGGGGACTTCCCTGCTCGGCTGGCTCTCGGTTTCTCTGCTTTCCTCCGGAGAAAT60AACAGCGTCTTCCGCGCCGCGCATGGAGCCTCCCGGCCGCCGCGAGTGTCCC112MetGluProProGlyArgArgGluCysPro34-30- 25TTTCCTTCCTGGCGCTTTCCTGGGTTGCTTCTGGCGGCCATGGTGTTG160PheProSerTrpArgPheProGlyLeuLeuLeuAlaAlaMetValLeu20-15-10CTGCTGTACTCCTTCTCCGATGCCTGTGAGGAGCCACCAACATTTGAA208LeuLeuTyrSerPheSerAspAlaCysGluGluProProThrPheGlu515GCTATGGAGCTCATTGGTAAACCAAAACCCTACTATGAGATTGGTGAA256AlaMetGluLeuIleGlyLysProLysProTyrTyrGluIleGlyGlu101520CGAGTAGATTATAAGTGTAAAAAAGGATACTTCTATATACCTCCTCTT304ArgValAspTyrLysCysLysLysGlyTyrPheTyrIleProProLeu25303540GCCACCCATACTATTTGTGATCGGAATCATACATGGCTACCTGTCTCA352AlaThrHisThrIleCysAspArgAsnHisThrTrpLeuProValSer455055GATGACGCCTGTTATAGAGAAACATGTCCATATATACGGGATCCTTTA400AspAspAlaCysTyrArgGluThrCysProTyrIleArgAspProLeu606570AATGGCCAAGCAGTCCCTGCAAATGGGACTTACGAGTTTGGTTATCAG448AsnGlyGlnAlaValProAlaAsnGlyThrTyrGluPheGlyTyrGln758085ATGCACTTTATTTGTAATGAGGGTTATTACTTAATTGGTGAAGAAATT496MetHisPheIleCysAsnGluGlyTyrTyrLeuIleGlyGluGluIle9095100CTATATTGTGAACTTAAAGGATCAGTAGCAATTTGGAGCGGTAAGCCC544LeuTyrCysGluLeuLysGlySerValAlaIleTrpSerGlyLysPro105110115120CCAATATGTGAAAAGGTTTTGTGTACACCACCTCCAAAAATAAAAAAT592ProIleCysGluLysValLeuCysThrProProProLysIleLysAsn125130135GGAAAACACACCTTTAGTGAAGTAGAAGTATTTGAGTATCTTGATGCA640GlyLysHisThrPheSerGluValGluValPheGluTyrLeuAspAla140145150GTAACTTATAGTTGTGATCCTGCACCTGGACCAGATCCATTTTCACTT688ValThrTyrSerCysAspProAlaProGlyProAspProPheSerLeu155160165ATTGGAGAGAGCACGATTTATTGTGGTGACAATTCAGTGTGGAGTCGT736IleGlyGluSerThrIleTyrCysGlyAspAsnSerValTrpSerArg170175180GCTGCTCCAGAGTGTAAAGTGGTCAAATGTCGATTTCCAGTAGTCGAA784AlaAlaProGluCysLysValValLysCysArgPheProValValGlu185190195200AATGGAAAACAGATATCAGGATTTGGAAAAAAATTTTACTACAAAGCA832AsnGlyLysGlnIleSerGlyPheGlyLysLysPheTyrTyrLysAla205210215ACAGTTATGTTTGAATGCGATAAGGGTTTTTACCTCGATGGCAGCGAC880ThrValMetPheGluCysAspLysGlyPheTyrLeuAspGlySerAsp220225230ACAATTGTCTGTGACAGTAACAGTACTTGGGATCCCCCAGTTCCAAAG928ThrIleValCysAspSerAsnSerThrTrpAspProProValProLys235240245TGTCTTAAAGTGTCGACTTCTTCCACTACAAAATCTCCAGCGTCCAGT976CysLeuLysValSerThrSerSerThrThrLysSerProAlaSerSer250255260GCCTCAGGATATCCTAAACCTGAGGAAGGAATACTTGACAGTTTGGAT1024AlaSerGlyTyrProLysProGluGluGlyIleLeuAspSerLeuAsp265270275280GTTTGGGTCATTGCTGTGATTGTTATTGCCATAGTTGTTGGAGTTGCA1072ValTrpValIleAlaValIleValIleAlaIleValValGlyValAla285290295GTAATTTGTGTTGTCCCGTACAGATATCTTCAAAGGAGGAAGAAGAAA1120ValIleCysValValProTyrArgTyrLeuGlnArgArgLysLysLys300305310GGGAAAGCAGATGGTGGAGCTGAATATGCCACTTACCAGACTAAATCA1168GlyLysAlaAspGlyGlyAlaGluTyrAlaThrTyrGlnThrLysSer315320325ACCACTCCAGCAGAGCAGAGAGGCTGAATAGATTCCACAACCTGGTTTGCCAGT1222ThrThrProAlaGluGlnArgGly330335TCATCTTTTGACTCTATCCCGCCCG1247(2) INFORMATION FOR SEQ ID NO:42:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 370 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(xi) SEQUENCE DESCRIPTION: SEQ ID NO:42:MetGluProProGlyArgArgGluCysProPheProSerTrpArgPhe34- 30-25-20ProGlyLeuLeuLeuAlaAlaMetValLeuLeuLeuTyrSerPheSer15-10-5AspAlaCysGluGluProProThrPheGluAlaMetGluLeuIleGly1510LysProLysProTyrTyrGluIleGlyGluArgValAspTyrLysCys15202530LysLysGlyTyrPheTyrIleProProLeuAlaThrHisThrIleCys354045AspArgAsnHisThrTrpLeuProValSerAspAspAlaCysTyrArg505560GluThrCysProTyrIleArgAspProLeuAsnGlyGlnAlaValPro657075AlaAsnGlyThrTyrGluPheGlyTyrGlnMetHisPheIleCysAsn808590GluGlyTyrTyrLeuIleGlyGluGluIleLeuTyrCysGluLeuLys95100105110GlySerValAlaIleTrpSerGlyLysProProIleCysGluLysVal115120125LeuCysThrProProProLysIleLysAsnGlyLysHisThrPheSer130135140GluValGluValPheGluTyrLeuAspAlaValThrTyrSerCysAsp145150155ProAlaProGlyProAspProPheSerLeuIleGlyGluSerThrIle160165170TyrCysGlyAspAsnSerValTrpSerArgAlaAlaProGluCysLys175180185190ValValLysCysArgPheProValValGluAsnGlyLysGlnIleSer195200205GlyPheGlyLysLysPheTyrTyrLysAlaThrValMetPheGluCys210215220AspLysGlyPheTyrLeuAspGlySerAspThrIleValCysAspSer225230235AsnSerThrTrpAspProProValProLysCysLeuLysValSerThr240245250SerSerThrThrLysSerProAlaSerSerAlaSerGlyTyrProLys255260265270ProGluGluGlyIleLeuAspSerLeuAspValTrpValIleAlaVal275280285IleValIleAlaIleValValGlyValAlaValIleCysValValPro290295300TyrArgTyrLeuGlnArgArgLysLysLysGlyLysAlaAspGlyGly305310315AlaGluTyrAlaThrTyrGlnThrLysSerThrThrProAlaGluGln320325330ArgGly335(2) INFORMATION FOR SEQ ID NO:43:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 1986 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(ix) FEATURE:(A) NAME/KEY: CDS(B) LOCATION: 29..1147(ix) FEATURE:(A) NAME/KEY: mat.sub.-- peptide(B) LOCATION: 131..1147(xi) SEQUENCE DESCRIPTION: SEQ ID NO:43:AATTCGGGCGGGGTCTTCCGCGCCGCGCATGGAGCCTCCCGGCCGCCGCGAG52MetGluProProGlyArgArgGlu34-30TGTCCCTTTCCTTCCTGGCGCTTTCCTGGGTTGCTTCTGGCGGCCATG100CysProPheProSerTrpArgPheProGlyLeuLeuLeuAlaAlaMet25-20-15GTGTTGCTGCTGTACTCCTTCTCCGATGCCTGTGAGGAGCCACCAACA148ValLeuLeuLeuTyrSerPheSerAspAlaCysGluGluProProThr10-515TTTGAAGCTATGGAGCTCATTGGTAAACCAAAACCCTACTATGAGATT196PheGluAlaMetGluLeuIleGlyLysProLysProTyrTyrGluIle101520GGTGAACGAGTAGATTATAAGTGTAAAAAAGGATACTTCTATATACCT244GlyGluArgValAspTyrLysCysLysLysGlyTyrPheTyrIlePro253035CCTCTTGCCACCCATACTATTTGTGATCGGAATCATACATGGCTACCT292ProLeuAlaThrHisThrIleCysAspArgAsnHisThrTrpLeuPro404550GTCTCAGATGACGCCTGTTATAGAGAAACATGTCCATATATACGGGAT340ValSerAspAspAlaCysTyrArgGluThrCysProTyrIleArgAsp55606570CCTTTAAATGGCCAAGCAGTCCCTGCAAATGGGACTTACGAGTTTGGT388ProLeuAsnGlyGlnAlaValProAlaAsnGlyThrTyrGluPheGly758085TATCAGATGCACTTTATTTGTAATGAGGGTTATTACTTAATTGGTGAA436TyrGlnMetHisPheIleCysAsnGluGlyTyrTyrLeuIleGlyGlu9095100GAAATTCTATATTGTGAACTTAAAGGATCAGTAGCAATTTGGAGCGGT484GluIleLeuTyrCysGluLeuLysGlySerValAlaIleTrpSerGly105110115AAGCCCCCAATATGTGAAAAGGTTTTGTGTACACCACCTCCAAAAATA532LysProProIleCysGluLysValLeuCysThrProProProLysIle120125130AAAAATGGAAAACACACCTTTAGTGAAGTAGAAGTATTTGAGTATCTT580LysAsnGlyLysHisThrPheSerGluValGluValPheGluTyrLeu135140145150GATGCAGTAACTTATAGTTGTGATCCTGCACCTGGACCAGATCCATTT628AspAlaValThrTyrSerCysAspProAlaProGlyProAspProPhe155160165TCACTTATTGGAGAGAGCACGATTTATTGTGGTGACAATTCAGTGTGG676SerLeuIleGlyGluSerThrIleTyrCysGlyAspAsnSerValTrp170175180AGTCGTGCTGCTCCAGAGTGTAAAGTGGTCAAATGTCGATTTCCAGTA724SerArgAlaAlaProGluCysLysValValLysCysArgPheProVal185190195GTCGAAAATGGAAAACAGATATCAGGATTTGGAAAAAAATTTTACTAC772ValGluAsnGlyLysGlnIleSerGlyPheGlyLysLysPheTyrTyr200205210AAAGCAACAGTTATGTTTGAATGCGATAAGGGTTTTTACCTCGATGGC820LysAlaThrValMetPheGluCysAspLysGlyPheTyrLeuAspGly215220225230AGCGACACAATTGTCTGTGACAGTAACAGTACTTGGGATCCCCCAGTT868SerAspThrIleValCysAspSerAsnSerThrTrpAspProProVal235240245CCAAAGTGTCTTAAAGTGTCGACTTCTTCCACTACAAAATCTCCAGCG916ProLysCysLeuLysValSerThrSerSerThrThrLysSerProAla250255260TCCAGTGCCTCAGGTCCTAGGCCTACTTACAAGCCTCCAGTCTCAAAT964SerSerAlaSerGlyProArgProThrTyrLysProProValSerAsn265270275TATCCAGGATATCCTAAACCTGAGGAAGGAATACTTGACAGTTTGGAT1012TyrProGlyTyrProLysProGluGluGlyIleLeuAspSerLeuAsp280285290GTTTGGGTCATTGCTGTGATTGTTATTGCCATAGATATCTTCAAAGGA1060ValTrpValIleAlaValIleValIleAlaIleAspIlePheLysGly295300305310GGAAGAAGAAAGGGAAAGCAGATGGTGGAGCTGAATATGCCACTTACC1108GlyArgArgLysGlyLysGlnMetValGluLeuAsnMetProLeuThr315320325AGACTAAATCAACCACTCCAGCAGAGCAGAGAGGCTGAATAGATTCCAC1157ArgLeuAsnGlnProLeuGlnGlnSerArgGluAlaGlu330335AACCTGGTTTGCCAGTTCATCTTTTGACTCTATTAAAATCTTCAATAGTTGTTATTCTGT1217AGTTTCACTCTCATGAGTGCAACTGTGGCTTAGCTAATATTGCAATGTGGCTTGAATGTA1277GGTAGCATCCTTTGATGCTTCTTTGAAACTTGTATGAATTTGGGTATGAACAGATTGCCT1337GCTTTCCCTTAAATAACACTTAGATTTATTGGACCAGTCAGCACAGCATGCCTGGTTGTA1397TTAAAGCAGGGATATGCTGTATTTTATAAAATTGGCAAAATTAGAGAAATATAGTTCACA1457ATGAAATTATATTTTCTTTGTAAAGAAAGTGGCTTGAAATCTTTTTTGTTCAAAGATTAA1517TGCCAACTCTTAAGATTATTCTTTCACCAACTATAGAATGTATTTTATATATCGTTCATT1577GTAAAAAGCCCTTAAAAATATGTGTATACTACTTTGGCTCTTGTGCATAAAAACAAGAAC1637ACTGAAAATTGGGAATATGCACAAACTTGGCTTCTTTAACCAAGAATATTATTGGAAAAG1697TTCTCTAAAAGTTAATAGGGTAAATTCTCTATTTTTTGTAATGTGTTCGGTGATTTCAGA1757AAGCTAGAAAGTGTATGTGTGGCATTTGTTTTCACTTTTTAAAACATCCCTAACTGATCG1817AATATATCAGTAATTTCAGAATCAGATGCATCCTTTCATAAGAAGTGAGAGGACTCTGAC1877AGCCATAACAGGAGTGCCACTTCATGGTGCGAAGTGAACACTGTAGTCTTGTTGTTTTCC1937CAAAGAGAACTCCGTATGTTCTCTTAGGTTGAGTAACCCACTCTGCCCG1986(2) INFORMATION FOR SEQ ID NO:44:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 373 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(xi) SEQUENCE DESCRIPTION: SEQ ID NO:44:MetGluProProGlyArgArgGluCysProPheProSerTrpArgPhe34- 30-25-20ProGlyLeuLeuLeuAlaAlaMetValLeuLeuLeuTyrSerPheSer15-10-5AspAlaCysGluGluProProThrPheGluAlaMetGluLeuIleGly1510LysProLysProTyrTyrGluIleGlyGluArgValAspTyrLysCys15202530LysLysGlyTyrPheTyrIleProProLeuAlaThrHisThrIleCys354045AspArgAsnHisThrTrpLeuProValSerAspAspAlaCysTyrArg505560GluThrCysProTyrIleArgAspProLeuAsnGlyGlnAlaValPro657075AlaAsnGlyThrTyrGluPheGlyTyrGlnMetHisPheIleCysAsn808590GluGlyTyrTyrLeuIleGlyGluGluIleLeuTyrCysGluLeuLys95100105110GlySerValAlaIleTrpSerGlyLysProProIleCysGluLysVal115120125LeuCysThrProProProLysIleLysAsnGlyLysHisThrPheSer130135140GluValGluValPheGluTyrLeuAspAlaValThrTyrSerCysAsp145150155ProAlaProGlyProAspProPheSerLeuIleGlyGluSerThrIle160165170TyrCysGlyAspAsnSerValTrpSerArgAlaAlaProGluCysLys175180185190ValValLysCysArgPheProValValGluAsnGlyLysGlnIleSer195200205GlyPheGlyLysLysPheTyrTyrLysAlaThrValMetPheGluCys210215220AspLysGlyPheTyrLeuAspGlySerAspThrIleValCysAspSer225230235AsnSerThrTrpAspProProValProLysCysLeuLysValSerThr240245250SerSerThrThrLysSerProAlaSerSerAlaSerGlyProArgPro255260265270ThrTyrLysProProValSerAsnTyrProGlyTyrProLysProGlu275280285GluGlyIleLeuAspSerLeuAspValTrpValIleAlaValIleVal290295300IleAlaIleAspIlePheLysGlyGlyArgArgLysGlyLysGlnMet305310315ValGluLeuAsnMetProLeuThrArgLeuAsnGlnProLeuGlnGln320325330SerArgGluAlaGlu335(2) INFORMATION FOR SEQ ID NO:45:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 1304 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(ix) FEATURE:(A) NAME/KEY: CDS(B) LOCATION: 94..1065(ix) FEATURE:(A) NAME/KEY: mat.sub.-- peptide(B) LOCATION: 196..1065(xi) SEQUENCE DESCRIPTION: SEQ ID NO:45:AATTCGGTGGACCCAGAAGGGACTTCCCTGCTCGGCTGGCTCTCGGTTTCTCTGCTTTCC60TCCGGAGAAATAACAGCGTCTTCCGCGCCGCGCATGGAGCCTCCCGGCCGCCGC114MetGluProProGlyArgArg34-30GAGTGTCCCTTTCCTTCCTGGCGCTTTCCTGGGTTGCTTCTGGCGGCC162GluCysProPheProSerTrpArgPheProGlyLeuLeuLeuAlaAla25-20-15ATGGTGTTGCTGCTGTACTCCTTCTCCGATGCCTGTGAGGAGCCACCA210MetValLeuLeuLeuTyrSerPheSerAspAlaCysGluGluProPro10- 515ACATTTGAAGCTATGGAGCTCATTGGTAAACCAAAACCCTACTATGAG258ThrPheGluAlaMetGluLeuIleGlyLysProLysProTyrTyrGlu101520ATTGGTGAACGAGTAGATTATAAGTGTAAAAAAGGATACTTCTATATA306IleGlyGluArgValAspTyrLysCysLysLysGlyTyrPheTyrIle253035CCTCCTCTTGCCACCCATACTATTTGTGATCGGAATCATACATGGCTA354ProProLeuAlaThrHisThrIleCysAspArgAsnHisThrTrpLeu404550CCTGTCTCAGATGACGCCTGTTATAGAGAAACATGTCCATATATACGG402ProValSerAspAspAlaCysTyrArgGluThrCysProTyrIleArg556065GATCCTTTAAATGGCCAAGCAGTCCCTGCAAATGGGACTTACGAGTTT450AspProLeuAsnGlyGlnAlaValProAlaAsnGlyThrTyrGluPhe70758085GGTTATCAGATGCACTTTATTTGTAATGAGGGTTATTACTTAATTGGT498GlyTyrGlnMetHisPheIleCysAsnGluGlyTyrTyrLeuIleGly9095100GAAGAAATTCTATATTGTGAACTTAAAGGATCAGTAGCAATTTGGAGC546GluGluIleLeuTyrCysGluLeuLysGlySerValAlaIleTrpSer105110115GGTAAGCCCCCAATATGTGAAAAGGTTTTGTGTACACCACCTCCAAAA594GlyLysProProIleCysGluLysValLeuCysThrProProProLys120125130ATAAAAAATGGAAAACACACCTTTAGTGAAGTAGAAGTATTTGAGTAT642IleLysAsnGlyLysHisThrPheSerGluValGluValPheGluTyr135140145CTTGATGCAGTAACTTATAGTTGTGATCCTGCACCTGGACCAGATCCA690LeuAspAlaValThrTyrSerCysAspProAlaProGlyProAspPro150155160165TTTTCACTTATTGGAGAGAGCACGATTTATTGTGGTGACAATTCAGTG738PheSerLeuIleGlyGluSerThrIleTyrCysGlyAspAsnSerVal170175180TGGAGTCGTGCTGCTCCAGAGTGTAAAGTGGTCAAATGTCGATTTCCA786TrpSerArgAlaAlaProGluCysLysValValLysCysArgPhePro185190195GTAGTCGAAAATGGAAAACAGATATCAGGATTTGGAAAAAAATTTTAC834ValValGluAsnGlyLysGlnIleSerGlyPheGlyLysLysPheTyr200205210TACAAAGCAACAGTTATGTTTGAATGCGATAAGGGTTTTTACCTCGAT882TyrLysAlaThrValMetPheGluCysAspLysGlyPheTyrLeuAsp215220225GGCAGCGACACAATTGTCTGTGACAGTAACAGTACTTGGGATCCCCCA930GlySerAspThrIleValCysAspSerAsnSerThrTrpAspProPro230235240245GTTCCAAAGTGTCTTAAAGGTACAAAGGTTATCTTTTTTCTGTCTTGG978ValProLysCysLeuLysGlyThrLysValIlePhePheLeuSerTrp250255260TTTGTTATTGTTGTTGCTGTTCATTTTAGACTTTATTTCTTTGATATT1026PheValIleValValAlaValHisPheArgLeuTyrPhePheAspIle265270275AACTATCAGTCATACAAAATAACTGAAAAGAAACAATTTTAGTATTTAA1075AsnTyrGlnSerTyrLysIleThrGluLysLysGlnPhe280285290CTCTGTCTTGTATTCATTTCTATGCCAGATGAATGACACGAAATTCACATAAAATTCTGC1135TGTTGTGATTTTTTGTGCTTTTCCAGGGTTCTTAGCACGTTATGTACATTGCATGGGTAT1195ATGCTTTTAATATTTTTATGTATAAAAAGTGAATTACAACAACTTTTTGGAATTGAAACA1255TGGGCATTTTTATCTAAGTAAGTCAACAATGGCATAATTCATATACCCG1304(2) INFORMATION FOR SEQ ID NO:46:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 324 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(xi) SEQUENCE DESCRIPTION: SEQ ID NO:46:MetGluProProGlyArgArgGluCysProPheProSerTrpArgPhe34- 30-25-20ProGlyLeuLeuLeuAlaAlaMetValLeuLeuLeuTyrSerPheSer15-10-5AspAlaCysGluGluProProThrPheGluAlaMetGluLeuIleGly1510LysProLysProTyrTyrGluIleGlyGluArgValAspTyrLysCys15202530LysLysGlyTyrPheTyrIleProProLeuAlaThrHisThrIleCys354045AspArgAsnHisThrTrpLeuProValSerAspAspAlaCysTyrArg505560GluThrCysProTyrIleArgAspProLeuAsnGlyGlnAlaValPro657075AlaAsnGlyThrTyrGluPheGlyTyrGlnMetHisPheIleCysAsn808590GluGlyTyrTyrLeuIleGlyGluGluIleLeuTyrCysGluLeuLys95100105110GlySerValAlaIleTrpSerGlyLysProProIleCysGluLysVal115120125LeuCysThrProProProLysIleLysAsnGlyLysHisThrPheSer130135140GluValGluValPheGluTyrLeuAspAlaValThrTyrSerCysAsp145150155ProAlaProGlyProAspProPheSerLeuIleGlyGluSerThrIle160165170TyrCysGlyAspAsnSerValTrpSerArgAlaAlaProGluCysLys175180185190ValValLysCysArgPheProValValGluAsnGlyLysGlnIleSer195200205GlyPheGlyLysLysPheTyrTyrLysAlaThrValMetPheGluCys210215220AspLysGlyPheTyrLeuAspGlySerAspThrIleValCysAspSer225230235AsnSerThrTrpAspProProValProLysCysLeuLysGlyThrLys240245250ValIlePhePheLeuSerTrpPheValIleValValAlaValHisPhe255260265270ArgLeuTyrPhePheAspIleAsnTyrGlnSerTyrLysIleThrGlu275280285LysLysGlnPhe290__________________________________________________________________________