Abstract:
The present invention concerns a new phosphatidyl-inositol-3-kinase (PI3Kγ), a nucleic acid coding for it, an antibody directed against the protein as well as the diagnostic and therapeutic use of the protein, the nucleic acid and the antibody.

Description:
RELATED APPLICATION 
     This application is a national stage application of PCT/EP95/03990 filed Oct. 10, 1995 under 35 USC 371. 
     BACKGROUND OF THE INVENTION 
     The present invention concerns a new phosphatidyl-inositol-3-kinase (PI3Kγ), a nucleic acid which codes for it, an antibody directed against the protein as well as the diagnostic and therapeutic use of the protein, of the nucleic acid and of the antibody. 
     Phosphatidylinositol-kinases belong, together with specific phospholipases, to an enzyme group which catalyses the formation of intracellular messenger substances from the membrane lipid phosphatidyl inositol (PI). The activity of these enzymes is regulated by extracellular effectors such as hormones, growth factors and neurotransmitters. It is assumed that the PI dependent messenger substances are involved among other processes in the regulation of important cells functions such as cell proliferation, secretion of cellular constituents, endocytotic processes, the targetted movement of certain cells, controlled changes of the cytoskeleton. Correspondingly the physiological importance of the PI kinases and phospholipases correlates with a series of disease states involving changes of the functions of these enzymes. 
     From various experimental results it is possible to conclude that the product of the reaction catalysed by PI3 kinase, PI-3,4,5 triphosphate plays an important role in the regulation of the following physiological cell functions: 
     Regulation of cell proliferation and cell differentiation by PI 3 kinase 
     Mitogens such as growth factors and cytokines generally lead to a stimulation of the PI 3 kinase activity in cells capable of division. The oncogenic transformation of cells is also often accompanied by an increase in the measurable PI 3 kinase activity (Varticovski et al., Biochim. Biophys. Acta 1226, 1-11 (1994), Berggren et al., Cancer Research 53, 4297-4302 (1993), Soldi et al., Oncogene 9, 2253-2260 (1994)). Inhibitors of PI 3 kinase are able to inhibit the PDGF-stimulated growth of normal connective tissue cells or smooth muscle cells and the proliferation of src-supratransformed fibroblasts (cancer cells) (Berggren et al., Cancer Research 53, 4297-4302 (1993), Vlahos et al., J.Biol.Chem. 269, 5241-5248 (1994)). Berggren et al., have speculated that the tumoristatic effect of ether lipid analogues is mainly based on their inhibitory action on PI 3 kinase. 
     The differentiation of the nerve cell line PC12 is suppressed by wortmannin an inhibitor of PI 3 kinase (Kimurea et al., J.Biol.Chem. 269, 18961-18967 (1994)). These findings as well as a clinical study in which there was shown to be a selective loss of PI 3 kinase activity in the brain of Alzheimer patients (Bothmer et al., Dementia 5, 6-11 (1994)) indicate that the enzyme has an important function in the formation and maintenance of nerve tissue. 
     Regulation of cytoskeletal-dependent processes by PI 3 kinase 
     Microscopically visible changes of cells often progress with the involvement of the cytoskeleton. A series of results shows that at least some of these processes are regulated by PI 3 kinase and its enzymatic products (PI3,4,5,P 3 , PI3,4P 2  and PI3P). Thus the membrane ruffling of epidermal cells induced by insulin or PDGF can be suppressed by the PI 3 kinase inhibitor wortmannin (Kotani et al., EMBO J. 13, 2313-2321 (1994), Wennstrom et al., Curr. Biol. 4, 385-393 (1994)). 
     Basophilic leucocytes are able to secrete histamine--a mediator of inflammations and allergic symptoms. The cytoskeleton of the cells is involved in this secretion process. Yano et al., J. Biol.Chem. 268, 25846-25856 (1993) were able to show that the antibody-induced histamine secretion can in turn be inhibited by the PI 3 kinase inhibitor wortmannin i.e. it is apparently controlled by 3-phosphorylated phosphoinositides. 
     Involvement of PI 3 kinase in intracellular transport processes 
     Investigations on yeast mutants show that one form of PI 3 kinase (Vps 34) is involved in these organisms in the selective distribution of proteins towards the yeast vacuoles (Schu et al., Science 260, 88-91 (1993)). Similar mechanisms may be the basis of the insulin-stimulated translocation of glucose transport protein (GLUT 4) from the interior of the cell to the plasma membrane (Kanai et al., Biochem.Biophys.Res.Commun. 195, 762-768 (1993)). This important process in various organs is also inhibited by wortmannin and apparently involves PI 3 kinase. 
     Inhibition of the O 2   -   production in neutrophilic granulocytes 
     Granulocytes produce superoxide anions (O 2   -   ) with the aim of destroying phagocytised foreign cells. This process is stimulated by the chemoattractant fMLP. The blocking of the fMLP-induced O 2   -  formation by wortmannin indicates a regulatory function of a PI 3 kinase species in this important process for the immune response of the body. 
     The above-mentioned results underlin e the central importance of PI 3 kinase and 3-phosphorylated inositol lipids in the regulation of important cell functions. Acquired or inherited defects of the said cell functions are undoubtedly the underlying cause of important clinical syndromes. Examples are: cancer, arteriosclerosis, immunopathies, skin diseases (such as psoriasis), degenerative diseases of the nervous system. 
     Since Pi 3 kinase is an essential element in the regulation of the said cell functions it is very probable that some of the clinical syndromes are due to malfunctions of PI 3 kinase species. The clinical study on PI 3 kinase in the brain of Alzheimer patients, the findings on the role of PI 3 kinase in the formation of the allergy inducer histamine and also the cancerostatic effect of PI 3 kinase-inhibiting ether lipids point in this direction. 
     A central concern of cell biology is to discover the mechanisms of intracellular signal transmission and the messenger substances that are involved. The final goal of these investigations is to selectively influence cell functions in a medical sense. 
     SUMMARY OF THE INVENTION 
     The present application describes the identification, cloning, expression and c harac terization of a new species of PI 3 kinase. This new species is activated by G protein subunits and hence differs from the previous species PI3Kα (Hiles et al., Cell 70 (1992) 419-429) and PI3Kβ (Hu et al., J.Mol.Cell. Biol. 13, (1993), 7677-7688) cloned from mammalian cells and from the PI3K-Vps34 from yeast (Schu et al., supra and Herman et al., Cell 64 (1991), 425-438) with regard to the regulation mechanism. The functional differences between the known enzymes PI3Kα and PI3Kβ on the one hand as well as the enzyme PI3Kγ according to the invention on the other hand are reflected in differences in the sequences of the important regulatory domains of the enzyme. 
     Hence a subject matter of the invention is a protein with phosphatidylinositol-3-kinase activity which is characterized in that it comprises 
     a) the amino acid sequence shown in SEQ ID NO. 2 
     b) the amino acid sequence shown in SEQ ID NO. 4 or 
     c) variants of the sequence from (a). 
     The PI3Kγ according to the invention is preferably a protein obtainable from humans i.e. it is the protein shown in SEQ ID NO. 1 and No. 2, the protein shown in SEQ ID NO. 3 and NO. 4 or a naturally occurring human variant thereof. 
     The invention also concerns a new protein which comprises parts of the amino acid sequence shown in SEQ ID NO. 1 and 2 or SEQ ID NO. 3 and 4. The invention preferably concerns a PI3K which comprises the amino acid sequence shown in SEQ ID NO. 1 and 2 or the amino acid sequence shown in SEQ ID NO. 3 and 4; it can, however, also contain variants of this sequence. The term &#34;variant&#34; within the sense of the present invention is understood as sequences which differ from the amino acid sequence shown in SEQ ID NO. 1 and 2 or in SEQ ID NO. 3 and 4 by substitution, deletion or/and insertion of individual amino acids or short sections of amino acids. 
     The term &#34;variant&#34; includes naturally occurring allelic variations of PI3Kγ as well as proteins produced by recombinant DNA technology (in particular by in vitro mutagenesis with the aid of chemically synthesized oligonucleotides) which, with regard to their biological or/and immunological activity, essentially correspond to the protein shown in SEQ ID NO. 1 and 2 or to the protein shown in SEQ ID NO. 3 and 4. 
     A preferred characteristic of proteins according to the invention is that at the amino acid level they have a homology of at least 80% particularly preferably of 90% and most preferably of 95% to the amino acid sequence shown in SEQ ID NO. 1 and 2 or to the amino acid sequences shown in SEQ ID NO. 3 and 4. 
     The amino acid sequence shown in SEQ ID NO. 1 and 2 represents a whole PI3Kγ. This protein has 1049 amino acids and has a molecular mass of ca. 120 kDa. The amino acid sequence shown in SEQ ID NO. 3 and 4 represents a PI3Kγ with 1050 amino acids. 
     The amino acid sequence of PI3Kγ has a homology of 19 to 39% to the sequences of other known PI3K such as human PI3Kα (36% homology), human PI3Kβ (33.5% homology) and PI3KVps34 from yeast (27.7%). The most highly conserved region in this group of enzymes are the 400 C-terminal amino acid residues which presumably contain the kinase domain. There is no significant homology between PI3Kγ and the other enzymes in the amino-terminal region which is known to be responsible for the binding of PI3Kα and β-enzyme subunits to the regulatory and adaptory subunits p85α and p85β (Dhand et al., EMBO J. 13 (1994), 511-521). 
     PI3Kγ can be detected in the cell as a 110 kDa protein by immunoprecipitation and Western blot analysis of U937 and K562 cells using antipeptide antisera. A Northern blot analysis showed a 5.3 kb long mRNA in several different tissue types. 
     A further subject matter of the present invention is a nucleic acid which codes for a phosphatidylinositol-3-kinase or parts thereof according to the invention. This nucleic acid can for example be genomic DNA, cDNA or RNA. It is preferably a recombinant DNA molecule. 
     Another subject matter of the invention is a nucleic acid which contains 
     a) the coding sequence shown in SEQ ID NO. 1 
     b) the protein-coding sequence shown in SEQ ID NO. 3 
     c) a nucleic acid sequence corresponding to the sequence from (a) or (b) within the scope of the degeneracy of the genetic code or 
     d) a sequence hybridizing with the sequences from (a), (b) and/or (c) under stringent hybridization conditions. 
     Stringent hybridization conditions within the sense of the present invention are understood as a hybridization which also still occurs after washing at 55° C., preferably at 62° C., particularly preferably at 68° C. in an aqueous low salt buffer (e.g. 0.2×SSC, 0.1% SDS) (see also Sambrook et al. (1989) Molecular Cloning, A Laboratory Manual). 
     The invention also concerns nucleic acids which contain at least a 20 nucleotide long section of the sequence shown in SEQ ID NO. 1 or SEQ ID NO. 3. This section preferably has a specific nucleotide sequence for the PI3Kγ. These nucleic acids are especially suitable for the production of therapeutically applicable antisense nucleic acids which are preferably up to 50 nucleotides long. 
     Yet a further subject matter of the invention is a vector which contains at least one copy of a nucleic acid or a part thereof according to the invention. The vector can be capable of replication in eukaryotes or prokaryotes. It can be a vector which can be integrated into the genome of the host cell e.g. bacteriophage lambda, or a vector which is present extrachromosomally (e.g. a plasmid). The vector according to the invention can be obtained by subcloning the PI3Kγ DNA into a basic vector. Such basic vectors in particular vectors containing the necessary elements for protein expression are familiar to a person skilled in the art. 
     When a nucleic acid coding for PI3Kγ is cloned it is possible to construct an expression vector which can be made to express in a suitable host cell to form the protein according to the invention. Preferred host cells are microorganisms such as E. coli or yeast and also higher cells (e.g. mammalian or insect cells). Preferred expression vectors are e.g. plasmids, bacteriophage lambda for prokaryotes, yeast vectors or viral vectors for higher cells (e.g. SV40, vaccinia, baculorivuses). With regard to the expression of a nucleic acid coding for PI3Kγ particular reference is made to the methods mentioned in Sambrook et al. (1989) supra. 
     A specific example of a system suitable for the expression of PI3Kγ is the expression as a GST fusion protein in Sf9-insect cells using baculovectors according to the method described by Davis et al. (Biotechnology 11 (1993), 933-936). 
     A further subject matter of the present invention is a cell which is transformed with a nucleic acid according to the invention or a vector according to the invention. The cell can be a eukaryotic as well as a prokaryotic cell. Methods for the transformation of cells with nucleic acids are general state of the art and do not therefore need to be elucidated in more detail. 
     The use of the PI3Kγ protein or fragments of this protein as an immunogen for the production of antibodies is also a subject matter of the present invention. In this case the antibodies can be produced in the usual manner by immunizing experimental animals with the complete PI3Kγ protein or fragments thereof and subsequently isolating the resulting polyclonal antisera. The method of Kohler and Milstein or further developments thereof can be used to obtain monoclonal antibodies in a known manner from the antibody-producing cells of the experimental animals by cell fusion. It is also possible to produce human monoclonal antibodies. 
     Hence a further subject matter of the present invention is an antibody against a protein with phosphatidyl-inositol-3-kinase activity which is specific for phosphatidylinositol-3-kinase γ and does not exhibit any cross-reaction with other phosphatidylinositol-3-kinases. Such an antibody can for example be obtained by using a PI3Kγ-specific peptide sequence as the immunogen e.g. a peptide sequence which corresponds to the amino acids 741 to 755 of the amino acid sequence shown in SEQ ID NO. 1 and 2 or to the amino acids 742 to 756 of the amino acid sequence shown in SEQ ID NO. 3 and 4. 
     The provision of PI3 kinase γ, a nucleic acid which codes for it and an antibody which is directed towards it creates the basis for a specific search for effectors of this protein. The target for these substances should be the regulatory domains of the enzyme which are located in the region of the amino acid residues 1 to 700 of the amino acid sequences shown in SEQ ID NO. 1 and 2 or SEQ ID NO. 3 and 4. Substances which, via this region of the protein, have an inhibitory or activating effect on the activity are able to selectively influence the cell functions regulated by PI3Kγ. Consequently they can be used for the treatment of corresponding clinical pictures. In the case of clinical pictures which are due to a loss of PI3Kγ it may be possible to carry out a gene therapy treatment in which a nucleic acid coding for PI3Kγ optionally together with a nucleic acid which codes for the activating G proteins is transferred by means of vectors e.g. viral vectors into the appropriate target tissue. 
     Moreover the results that have been presented form the basis for a specific diagnosis of diseases which are causally linked to changes in PI3Kγ activity. These investigations can be carried out with the aid of specific nucleic acid probes for tests at the DNA level i.e. at the gene or transcription level or with the aid of antibodies against PI3Kγ for tests at the protein level. 
     Hence the present invention also concerns a pharmaceutical composition which comprises a PI3Kγ protein, an antibody directed towards it or a nucleic acid which codes for it as the active component optionally together with standard pharmaceutical auxiliary substances, carrier substances, fillers and diluents. 
     The pharmaceutical composition according to the invention can be used in particular to influence cell proliferation, receptor-mediated signal transmission, the structure of the cell membrane, the secretion of histamines, the differentiation of nerve cells, glucose transport and anti-lipolysis. Furthermore it can also be used in connection with the therapy of Alzheimer&#39;s disease. 
     The invention is elucidated in more detail by the following examples, figures and sequence protocols. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 shows the detection of PI3Kγ in human blood cells by specific antibodies, 
     FIG. 2a shows the recombinant expression of PI3Kγ in insect cells, 
     FIG. 2b shows the detection of the enzymatic activity of purified recombinant PI3Kγ, 
     FIG. 3 shows the absence of interaction between PI3Kγ and the proteins p85α and p85β, 
    
    
     DETAILED DESCRIPTION 
     SEQ ID NO. 1 shows a nucleic acid sequence which contains genetic information coding for PI3Kγ and 
     SEQ ID NO. 2 shows the amino acid sequence of a PI3Kγ. 
     SEQ ID NO: 3 shows a nucleic acid sequence which contains genetic information coding for a further PI3Kγ and 
     SEQ ID NO. 4 shows the amino acid sequence of a further PI3Kγ. 
     EXAMPLE 1 
     Isolation of PI3Kγ cDNA 
     In order to isolate cDNA sequences which code for new PI3K a human bone marrow cDNA library was screened using the polymerase chain reaction (PCR). For this degenerate oligonucleotide primers were used corresponding to the amino acid sequences KNGDDLR  SEQ ID NO:6! and HIDFG  SEQ ID NO:7!. A 402 bp long fragment was obtained. This fragment was subcloned and sequenced. 
     Several overlapping clones from a human U937 cDNA library were isolated using this PCR fragment as a probe. The largest clone contained the nucleic acid sequence shown in SEQ ID NO. 1 with an open reading frame which codes for a protein with 1049 amino acids (SEQ ID NO. 2). This protein named PI3Kγ has a molecular mass of approximately 120 kDa. 
     A further PI3Kγ sequence which was obtained from a cDNA library is shown in SEQ ID NO. 3 and codes for a protein with 1050 amino acids (SEQ ID NO. 4). 
     EXAMPLE 2 
     Detection of PI3Kγ at a protein and transcript level 
     A polyclonal rabbit antiserum against PI3Kγ was produced by immunization with a 15 amino acid long peptide of the sequence NSQLPESFRVPYDPG SEQ ID NO:5 (corresponding to amino acids 741 to 755 in SEQ ID NO. 2 or amino acids 742 to 756 in SEQ ID NO. 4). The serum was purified by protein A chromatography and affinity chromatography using the peptide antigen coupled to Actigel (Sterogene). 
     PI3Kγ can be detected as a 110 kDa protein using this antiserum by immunoprecipitation and Western blot analysis of U937 and K562 cells (FIG. 1). The immunoprecipitation and Western blot were carried out according to the method of Hiles et al. (Cell 70 (1992) 419-429). A conjugate of horseradish peroxidase and anti-rabbit antiserum (Sigma, 1:2000 dilution) was used as the secondary antibody. The bound peroxidase was visualized by chemiluminescence. 
     A Northern blot analysis of human tissue from the pancreas, kidney, skeletal muscle, liver, lung, placenta, brain and heart each showed different concentrations of a 5.3 kb long mRNA. 
     EXAMPLE 3 
     Recombinant expression of PI3Kγ 
     The DNA coding for PI3Kγ was cloned into the vector pAcG2T (Davis et al., Biotechnology 11 (1993), 933-936). The resulting recombinant vector pAcG2T-PI3Kγ contained the PI3Kγ cDNA from codon 4 onwards in a fusion with the glutathione S transferase (GST) gene. Sf9 cells were cotransfected with pAcG2T-PI3Kγ and linearized baculovirus DNA (BaculoGold, Pharmingen). Individual recombinant baculovirus GST-PI3Kγ plaques were purified and amplified. The expression and purification of recombinant protein were carried out using standard protocols (Dhand et al., EMBO J. 13 (1994), 511-521). FIG. 2a shows the expression of recombinant PI3Kγ GST fusion protein or GST alone after fractionation on a SDS polyacrylamide gel. The detection was carried out by staining with coomassie blue. 
     FIG. 2b shows a detection of the enzymatic activity of purified recombinant PI3Ky. Phosphatidylinositol (PI, lane 1), phosphatidylinositol-4-phosphate (PI4-P, lane 2) and phosphatidylinositol-4,5-diphosphate (PI 4,5-P 2 , lane 3) were used as substrates. The test was carried out essentially according to the method of Stephens et al. (Cell 77 (1994), 83-93) but without cholate. 30 μl sonicated lipid vesicles containing 320 μM phosphatidyl ethanolamine, 140 μM phosphatidyl choline, 300 μM phosphatidyl serine, 30 μM sphingomyelin and 320 μM substrate were added to 10 μl enzyme (0.1 ng) and incubated for 8 minutes on ice. The test was started by addition of 10 μl 20 μM ATP containing 10 μCi γ( 32  P)ATP and incubated for 15 minutes at room temperature. The extracted lipids were separated and visualized. The identity of the 3-phosphorylated phosphoinositides was confirmed by anion exchange HPLC after deacylation of the lipids (Auger et al., Cell 57 (1989), 167-175). 
     FIG. 2b shows that the substrates were phosphorylated in the D-3 position of the inositol ring. In addition it was found that PI3Kγ was inhibited by wortmannin at nanomolar concentrations. 
     EXAMPLE 4 
     Regulation of PI3Kγ 
     In order to detect an interaction between the regulatory and adaptory subunits of p85 (p85α and p85β) and PI3Kγ, human PI3Kγ and bovine PI3Kα (Hiles et al., supra) were expressed in Sf9 insect cells according to the process described in example 3 as GST fusion proteins either alone or together with p85α and p85β. After lysis and centrifugation of the cells, glutathione-Sepharose was added to the supernatant in order to bind the GST fusion proteins. The particles were washed and analysed by SDS-PAGE and Western-blot. PI3Kγ was detected using the polyclonal antipeptide antibody described in example 2. Appropriate mixtures of specific monoclonal antibodies (Dhand et al., supra) as a primary antibody and conjugates of horseradish peroxidase and anti-mouse antibodies (Dianova, 1:4000 dilution) as the secondary antibody were used to detect p85α, p85β and bovine PI3Kα. 
     FIG. 3 shows that PI3Kγ in contrast to PI3Kα does not bind to p85α and p85β subunits. The regulation mechanism of PI3Kγ is therefore different from PI3Kα. 
     In order to detect an interaction between PI3Kγ and G proteins, purified recombinant human PI3Kγ and bovine PI3Kα was incubated with the transducin species G t  βγ. A substantial amplification of the kinase activity of PI3Kγ was found. This stimulation was suppressed by adding GTP-loaded G t  α which confirms the specificity of the interaction. 
     In contrast the enzymatic activity of PI3Kα could not be stimulated by addition of G t  βγ. A similar activation of the enzyme was found after addition of Gα in the presence of 20 μM AlCl 3  and 10 mM NaF. The complex Gα-GDP-AlF 4  - acts as an activating species. 
     The determination of activity was carried out as described in example 3. The G t  proteins purified from bovine retina according to the method of Camps et al. (Nature 360 (1992) 684-686) were incubated on ice with the lipid vesicles for 5 min (G t  βγ) or for 20 min (G t  βγ plus G t  α-GTP) before adding the enzyme. 
     Binding studies with recombinant PI3Kγ showed that the regulator protein Ras in its active GTP-loaded form associates with the enzyme. Ras in its constitutively active version is able to oncogenically transform cells. Hence this is a further indication for the potential importance of PI3Kγ in the regulation of cellular proliferation. 
     
         __________________________________________________________________________SEQUENCE LISTING(1) GENERAL INFORMATION:(iii) NUMBER OF SEQUENCES: 7(2) INFORMATION FOR SEQ ID NO: 1:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 4134 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: both(D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(vi) ORIGINAL SOURCE:(A) ORGANISM: Homo sapiens(ix) FEATURE:(A) NAME/KEY: CDS(B) LOCATION:423..3569(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 1:GAATTCGGCACGAGCACTTCCTTCTCGGCTAGATTATCTGAAACTGTTGTCGGTTCTTGA60GATGATACTACCACCGAATGTCTGTGTTTCATTGTCTAGTCCAACCTGTATTGTGGATAT120CTACAACGTTCCGGCAATAGTTTTGCAGGTGCATCACATTTTTGTTTTTGTTTTGGGAGG180AAAAGGGAGGGCACGGCAGCCAGGCTTCATATTCCTACAAGTGCATGCTTCAAGATTACT240GTACTTACAGTGTTTCCAACATCTTCTCATAAAAGGGGAAAGCTTCATAGCCTCAACCAT300GAAGGAAACCAGTCGCATAGGGCATGGAGCTGGAGAACTATAAACAGCCCGTGGTGCTGA360GAGAGGACAACTGCCGAAGGCGCCGGAGGATGAAGCCGCGCAGTGCTGCCAGCCTGTCCT420CCATGGAGCTCATCCCCATCGAGTTCGTGCTGCCCACCAGCCAGCGC467MetGluLeuIleProIleGluPheValLeuProThrSerGlnArg51015AAATGCAAGAGCCCCGAAACGGCGCTGCTGCACGTGGCCGGCCACGGC515LysCysLysSerProGluThrAlaLeuLeuHisValAlaGlyHisGly202530AACGTGGAGCAGATGAAGGCCCAGGTGTGGCTGCGAGCGCTGGAGACC563AsnValGluGlnMetLysAlaGlnValTrpLeuArgAlaLeuGluThr354045AGCTGGCGCGGACTTCTACCACCGGCTGGGACCGCATCACTTCCTCCT611SerTrpArgGlyLeuLeuProProAlaGlyThrAlaSerLeuProPro505560GCTCTATCAGAAGAAGGGCAGTGGTACGAGATCTACGACAAGTACCAG659AlaLeuSerGluGluGlyGlnTrpTyrGluIleTyrAspLysTyrGln657075GTGGTGCAGACTCTGGACTGCCTGCGCTACTGGAAGGCCACGCACCGG707ValValGlnThrLeuAspCysLeuArgTyrTrpLysAlaThrHisArg80859095AGCCCGGGCCAGATCCACCTGGTGCAGCGGCACCCGCCCTCCGAGGAG755SerProGlyGlnIleHisLeuValGlnArgHisProProSerGluGlu100105110TCCCAAGCCTTCCAGCGGCAGCTCACGGCGCTGATTGGCTATGACGTC803SerGlnAlaPheGlnArgGlnLeuThrAlaLeuIleGlyTyrAspVal115120125ACTGACGTCAGCAACGTGCACGACGATGAGCTGGAGTTCACGCGCCGT851ThrAspValSerAsnValHisAspAspGluLeuGluPheThrArgArg130135140GGCTTGGTGACCCCGCGCATGGCGGAGGTGGCCAGCCGCGACCCCAAG899GlyLeuValThrProArgMetAlaGluValAlaSerArgAspProLys145150155CTCTACGCCATGCACCCGTGGGTGACGTCCAAGCCCCTCCCGGAGTAC947LeuTyrAlaMetHisProTrpValThrSerLysProLeuProGluTyr160165170175CTGTGGAAGAAGATTGCCAACAACTGCATCTTCATCGTCATTCACCGC995LeuTrpLysLysIleAlaAsnAsnCysIlePheIleValIleHisArg180185190AGCACCACCAGCCAGACCATTAAGGTCTCACCCGACGACACCCCCGGC1043SerThrThrSerGlnThrIleLysValSerProAspAspThrProGly195200205GCCATCCTGCAGAGCTTCTTCACCAAGATGGCCAAGAAGAAATCTCTG1091AlaIleLeuGlnSerPhePheThrLysMetAlaLysLysLysSerLeu210215220ATGGATATTCCCGAAAGCCAAAGCGAACAGGATTTTGTGCTGCGCGTC1139MetAspIleProGluSerGlnSerGluGlnAspPheValLeuArgVal225230235TGTGGCCGGGATGAGTACCTGGTGGGCGAAACGCCCATCAAAAACTTC1187CysGlyArgAspGluTyrLeuValGlyGluThrProIleLysAsnPhe240245250255CAGTGGGTGAGGCACTGCCTCAAGAACGGAGAAGAGATTCACGTGGTA1235GlnTrpValArgHisCysLeuLysAsnGlyGluGluIleHisValVal260265270CTGGACACGCCTCCAGACCCGGCCCTAGACGAGGTGAGGAAGGAAGAG1283LeuAspThrProProAspProAlaLeuAspGluValArgLysGluGlu275280285TGGCCGCTGGTGGACGACTGCACGGGAGTCACCGGCTACCATGAGCAG1331TrpProLeuValAspAspCysThrGlyValThrGlyTyrHisGluGln290295300CTTACCATCCACGGCAAGGACCACGAGAGTGTGTTCACCGTGTCCCTG1379LeuThrIleHisGlyLysAspHisGluSerValPheThrValSerLeu305310315TGGGACTGCGACCGCAAGTTCAGGGTCAAGATCAGAGGCATTGATATC1427TrpAspCysAspArgLysPheArgValLysIleArgGlyIleAspIle320325330335CCCGTCCTGCCTCGGAACACCGACCTCACAGTTTTTGTAGAGGCAAAC1475ProValLeuProArgAsnThrAspLeuThrValPheValGluAlaAsn340345350ATCCAGCATGGGCAACAAGTCCTTTGCCAAAGGAGAACCAGCCCCAAA1523IleGlnHisGlyGlnGlnValLeuCysGlnArgArgThrSerProLys355360365CCCTTCACAGAGGAGGTGCTGTGGAATGTGTGGCTTGAGTTCAGTATC1571ProPheThrGluGluValLeuTrpAsnValTrpLeuGluPheSerIle370375380AAAATCAAAGACTTGCCCAAAGGGGCTCTACTGAACCTCCAGATCTAC1619LysIleLysAspLeuProLysGlyAlaLeuLeuAsnLeuGlnIleTyr385390395TGCGGTAAAGCTCCAGCACTGTCCAGCAAGGCCTCTGCAGAGTCCCCC1667CysGlyLysAlaProAlaLeuSerSerLysAlaSerAlaGluSerPro400405410415AGTTCTGAGTCCAAGGGCAAAGTTCGGCTTCTCTATTATGTGAACCTG1715SerSerGluSerLysGlyLysValArgLeuLeuTyrTyrValAsnLeu420425430CTGCTGATAGACCACCGTTTCCTCCTGCGCCGTGGAGAATACGTCCTC1763LeuLeuIleAspHisArgPheLeuLeuArgArgGlyGluTyrValLeu435440445CACATGTGGCAGATATCTGGGAAGGGAGAAGACCAAGGAAGCTTCAAT1811HisMetTrpGlnIleSerGlyLysGlyGluAspGlnGlySerPheAsn450455460GCTGACAAACTCACGTCTGCAACTAACCCAGACAAGGAGAACTCAATG1859AlaAspLysLeuThrSerAlaThrAsnProAspLysGluAsnSerMet465470475TCCATCTCCATTCTTCTGGACAATTACTGCCACCCGATAGCCCTGCCT1907SerIleSerIleLeuLeuAspAsnTyrCysHisProIleAlaLeuPro480485490495AAGCATCAGCCCACCCCTGACCCGGAAGGGGACCGGGTTCGAGCAGAA1955LysHisGlnProThrProAspProGluGlyAspArgValArgAlaGlu500505510ATGCCCAACCAGCTTCGCAAGCAATTGGAGGCGATCATAGCCACTGAT2003MetProAsnGlnLeuArgLysGlnLeuGluAlaIleIleAlaThrAsp515520525CCACTTAACCCTCTCACAGCAGAGGACAAAGAATTGCTCTGGCATTTT2051ProLeuAsnProLeuThrAlaGluAspLysGluLeuLeuTrpHisPhe530535540AGATACGAAAGCCTTAAGCACCCAAAAGCATATCCTAAGCTATTTAGT2099ArgTyrGluSerLeuLysHisProLysAlaTyrProLysLeuPheSer545550555TCAGTGAAATGGGGACAGCAAGAAATTGTGGCCAAAACATACCAATTG2147SerValLysTrpGlyGlnGlnGluIleValAlaLysThrTyrGlnLeu560565570575TTGGCCAGAAGGGAAGTCTGGGATCAAAGTGCTTTGGATGTTGGGTTA2195LeuAlaArgArgGluValTrpAspGlnSerAlaLeuAspValGlyLeu580585590ACAATGCAGCTCCTGGACTGCAACTTCTCAGATGAAAATGTAAGAGCC2243ThrMetGlnLeuLeuAspCysAsnPheSerAspGluAsnValArgAla595600605ATTGCAGTTCAGAAACTGGAGAGCTTGGAGGACGATGATGTTCTGCAT2291IleAlaValGlnLysLeuGluSerLeuGluAspAspAspValLeuHis610615620TACCTTCTACAATTGGTCCAGGCTGTGAAATTTGAACCATACCATGAT2339TyrLeuLeuGlnLeuValGlnAlaValLysPheGluProTyrHisAsp625630635AGCGCCCTTGCCAGATTTCTGCTGAAGCGTGGTTTAAGAAACAAAAGA2387SerAlaLeuAlaArgPheLeuLeuLysArgGlyLeuArgAsnLysArg640645650655ATTGGTCACTTTTTGTTTTGGTTCTTGAGAAGTGAGATAGCCCAGTCC2435IleGlyHisPheLeuPheTrpPheLeuArgSerGluIleAlaGlnSer660665670AGACACTATCAGCAGAGGTTCGCTGTGATTCTGGAAGCCTATCTGAGG2483ArgHisTyrGlnGlnArgPheAlaValIleLeuGluAlaTyrLeuArg675680685GGCTGTGGCACAGCCATGCTGCACGACTTTACCCAACAAGTCCAAGTA2531GlyCysGlyThrAlaMetLeuHisAspPheThrGlnGlnValGlnVal690695700ATCGAGATGTTACAAAAAGTCACCCTTGATATTAAATCGCTCTCTGCT2579IleGluMetLeuGlnLysValThrLeuAspIleLysSerLeuSerAla705710715GAAAAGTATGACGTCAGTTCCCAAGTTATTTCACAACTTAAACAAAAG2627GluLysTyrAspValSerSerGlnValIleSerGlnLeuLysGlnLys720725730735CTTGAAAACCTGCAGAATTCTCAACTCCCCGAAAGCTTTAGAGTTCCA2675LeuGluAsnLeuGlnAsnSerGlnLeuProGluSerPheArgValPro740745750TATGATCCTGGACTGAAAGCAGGAGCGCTGGCAATTGAAAAATGTAAA2723TyrAspProGlyLeuLysAlaGlyAlaLeuAlaIleGluLysCysLys755760765GTAATGGCCTCCAAGAAAAAACCACTATGGCTTGAGTTTAAATGTGCC2771ValMetAlaSerLysLysLysProLeuTrpLeuGluPheLysCysAla770775780GATCCTACAGCCCTATCAAATGAAACAATTGGAATTATCTTTAAACAT2819AspProThrAlaLeuSerAsnGluThrIleGlyIleIlePheLysHis785790795GGTGATGATCTGCGCCAAGACATGCTTATTTTACAGATTCTACGAATC2867GlyAspAspLeuArgGlnAspMetLeuIleLeuGlnIleLeuArgIle800805810815ATGGAGTCTATTTGGGAGACTGAATCTTTGGATCTATGCCTCCTGCCA2915MetGluSerIleTrpGluThrGluSerLeuAspLeuCysLeuLeuPro820825830TATGGTTGCATTTCAACTGGTGACAAAATAGGAATGATCGAGATTGTG2963TyrGlyCysIleSerThrGlyAspLysIleGlyMetIleGluIleVal835840845AAAGACGCCACGACAATTGCCAAAATTCAGCAAAGCACAGTGGGCAAC3011LysAspAlaThrThrIleAlaLysIleGlnGlnSerThrValGlyAsn850855860ACGGGAGCATTTAAAGATGAAGTCCTGAATCACTGGCTCAAAGAAAAA3059ThrGlyAlaPheLysAspGluValLeuAsnHisTrpLeuLysGluLys865870875TCCCCTACTGAAGAAAAGTTTCAGGCAGCAGTGGAGAGATTTGTTTAT3107SerProThrGluGluLysPheGlnAlaAlaValGluArgPheValTyr880885890895TCCTGTGCAGGCTACTGTGTGGCAACCTTTGTTCTTGGAATAGGCGAC3155SerCysAlaGlyTyrCysValAlaThrPheValLeuGlyIleGlyAsp900905910AGACACAATGACAATATTATGATCACCGAGACAGGAAACCTATTTCAT3203ArgHisAsnAspAsnIleMetIleThrGluThrGlyAsnLeuPheHis915920925ATTGACTTCGGGCACATTCTTGGGAATTACAAAAGTTTCCTGGGCATT3251IleAspPheGlyHisIleLeuGlyAsnTyrLysSerPheLeuGlyIle930935940AATAAAGAGAGAGTGCCATTTGTGCTAACCCCTGACTTCCTCTTTGTG3299AsnLysGluArgValProPheValLeuThrProAspPheLeuPheVal945950955ATGGGAACTTCTGGAAAGAAGACAAGCCCACACTTCCAGAAATTTCAG3347MetGlyThrSerGlyLysLysThrSerProHisPheGlnLysPheGln960965970975GACATCTGTGTTAAGGCTTATCTAGCCCTTCGTCATCACACAAACCTA3395AspIleCysValLysAlaTyrLeuAlaLeuArgHisHisThrAsnLeu980985990CTGATCATCCTGTTCTCCATGATGCTGATGACAGGAATGCCCCAGTTA3443LeuIleIleLeuPheSerMetMetLeuMetThrGlyMetProGlnLeu99510001005ACAAGCAAAGAAGACATTGAATATATCCGGGATGCCCTCACAGTGGGG3491ThrSerLysGluAspIleGluTyrIleArgAspAlaLeuThrValGly101010151020AAAAATGAGGAGGATGCTAAAAAGTATTTTCTTGATCAGATCGAAGTT3539LysAsnGluGluAspAlaLysLysTyrPheLeuAspGlnIleGluVal102510301035TGGCAGAGACAAAGGATGGACTGTGCAGTTTAATTGGTTTCTACATCTTG3589TrpGlnArgGlnArgMetAspCysAlaVal10401045TTCTTGGCATCAAACAAGGAGAGAAACATTCAGCCTAATACTTTAGGCTAGAATCAAAAA3649CAAGTTAGTGTTCTATGGTTTAAATTAGCATAGCAATCATCGAACTTGGATTTCAAATGC3709AATAGACATTGTGAAAGCTGGCATTTCAGAAGTATAGCTCTTTTCCTACCTGAACTCTTC3769CCTGGAGAAAAGATGTTGGCATTGCTGATTGTTTGGTTAAGCAATGTCCAGTGCTAGGAT3829TATTTGCAGGTTTGGTTTTTTCTCATTTGTCTGTGGCATTGGAGAATATTCTCGGTTTAA3889ACAGACTAATGACTTCCTTATTGTCCCTGATATTTTGACTATCTTACTATTGAGTGCTTC3949TGGAAATTCTTTGGAATAATTGATGACATCTATTTTCATCTGGGTTTAGTCTCAATTTTG4009GTTATCTTTGTGTTCCTCAAGCTCTTTAAAGAAAAAGATGTAATCGTTGTAACCTTTGTC4069TCATTCCTTAAATGATGCTTCCAAACATCTCCTTAGTGTCTGCAGGTGTTAGTGGTGTGC4129TAAAA4134(2) INFORMATION FOR SEQ ID NO: 2:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 1049 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 2:MetGluLeuIleProIleGluPheValLeuProThrSerGlnArgLys151015CysLysSerProGluThrAlaLeuLeuHisValAlaGlyHisGlyAsn202530ValGluGlnMetLysAlaGlnValTrpLeuArgAlaLeuGluThrSer354045TrpArgGlyLeuLeuProProAlaGlyThrAlaSerLeuProProAla505560LeuSerGluGluGlyGlnTrpTyrGluIleTyrAspLysTyrGlnVal65707580ValGlnThrLeuAspCysLeuArgTyrTrpLysAlaThrHisArgSer859095ProGlyGlnIleHisLeuValGlnArgHisProProSerGluGluSer100105110GlnAlaPheGlnArgGlnLeuThrAlaLeuIleGlyTyrAspValThr115120125AspValSerAsnValHisAspAspGluLeuGluPheThrArgArgGly130135140LeuValThrProArgMetAlaGluValAlaSerArgAspProLysLeu145150155160TyrAlaMetHisProTrpValThrSerLysProLeuProGluTyrLeu165170175TrpLysLysIleAlaAsnAsnCysIlePheIleValIleHisArgSer180185190ThrThrSerGlnThrIleLysValSerProAspAspThrProGlyAla195200205IleLeuGlnSerPhePheThrLysMetAlaLysLysLysSerLeuMet210215220AspIleProGluSerGlnSerGluGlnAspPheValLeuArgValCys225230235240GlyArgAspGluTyrLeuValGlyGluThrProIleLysAsnPheGln245250255TrpValArgHisCysLeuLysAsnGlyGluGluIleHisValValLeu260265270AspThrProProAspProAlaLeuAspGluValArgLysGluGluTrp275280285ProLeuValAspAspCysThrGlyValThrGlyTyrHisGluGlnLeu290295300ThrIleHisGlyLysAspHisGluSerValPheThrValSerLeuTrp305310315320AspCysAspArgLysPheArgValLysIleArgGlyIleAspIlePro325330335ValLeuProArgAsnThrAspLeuThrValPheValGluAlaAsnIle340345350GlnHisGlyGlnGlnValLeuCysGlnArgArgThrSerProLysPro355360365PheThrGluGluValLeuTrpAsnValTrpLeuGluPheSerIleLys370375380IleLysAspLeuProLysGlyAlaLeuLeuAsnLeuGlnIleTyrCys385390395400GlyLysAlaProAlaLeuSerSerLysAlaSerAlaGluSerProSer405410415SerGluSerLysGlyLysValArgLeuLeuTyrTyrValAsnLeuLeu420425430LeuIleAspHisArgPheLeuLeuArgArgGlyGluTyrValLeuHis435440445MetTrpGlnIleSerGlyLysGlyGluAspGlnGlySerPheAsnAla450455460AspLysLeuThrSerAlaThrAsnProAspLysGluAsnSerMetSer465470475480IleSerIleLeuLeuAspAsnTyrCysHisProIleAlaLeuProLys485490495HisGlnProThrProAspProGluGlyAspArgValArgAlaGluMet500505510ProAsnGlnLeuArgLysGlnLeuGluAlaIleIleAlaThrAspPro515520525LeuAsnProLeuThrAlaGluAspLysGluLeuLeuTrpHisPheArg530535540TyrGluSerLeuLysHisProLysAlaTyrProLysLeuPheSerSer545550555560ValLysTrpGlyGlnGlnGluIleValAlaLysThrTyrGlnLeuLeu565570575AlaArgArgGluValTrpAspGlnSerAlaLeuAspValGlyLeuThr580585590MetGlnLeuLeuAspCysAsnPheSerAspGluAsnValArgAlaIle595600605AlaValGlnLysLeuGluSerLeuGluAspAspAspValLeuHisTyr610615620LeuLeuGlnLeuValGlnAlaValLysPheGluProTyrHisAspSer625630635640AlaLeuAlaArgPheLeuLeuLysArgGlyLeuArgAsnLysArgIle645650655GlyHisPheLeuPheTrpPheLeuArgSerGluIleAlaGlnSerArg660665670HisTyrGlnGlnArgPheAlaValIleLeuGluAlaTyrLeuArgGly675680685CysGlyThrAlaMetLeuHisAspPheThrGlnGlnValGlnValIle690695700GluMetLeuGlnLysValThrLeuAspIleLysSerLeuSerAlaGlu705710715720LysTyrAspValSerSerGlnValIleSerGlnLeuLysGlnLysLeu725730735GluAsnLeuGlnAsnSerGlnLeuProGluSerPheArgValProTyr740745750AspProGlyLeuLysAlaGlyAlaLeuAlaIleGluLysCysLysVal755760765MetAlaSerLysLysLysProLeuTrpLeuGluPheLysCysAlaAsp770775780ProThrAlaLeuSerAsnGluThrIleGlyIleIlePheLysHisGly785790795800AspAspLeuArgGlnAspMetLeuIleLeuGlnIleLeuArgIleMet805810815GluSerIleTrpGluThrGluSerLeuAspLeuCysLeuLeuProTyr820825830GlyCysIleSerThrGlyAspLysIleGlyMetIleGluIleValLys835840845AspAlaThrThrIleAlaLysIleGlnGlnSerThrValGlyAsnThr850855860GlyAlaPheLysAspGluValLeuAsnHisTrpLeuLysGluLysSer865870875880ProThrGluGluLysPheGlnAlaAlaValGluArgPheValTyrSer885890895CysAlaGlyTyrCysValAlaThrPheValLeuGlyIleGlyAspArg900905910HisAsnAspAsnIleMetIleThrGluThrGlyAsnLeuPheHisIle915920925AspPheGlyHisIleLeuGlyAsnTyrLysSerPheLeuGlyIleAsn930935940LysGluArgValProPheValLeuThrProAspPheLeuPheValMet945950955960GlyThrSerGlyLysLysThrSerProHisPheGlnLysPheGlnAsp965970975IleCysValLysAlaTyrLeuAlaLeuArgHisHisThrAsnLeuLeu980985990IleIleLeuPheSerMetMetLeuMetThrGlyMetProGlnLeuThr99510001005SerLysGluAspIleGluTyrIleArgAspAlaLeuThrValGlyLys101010151020AsnGluGluAspAlaLysLysTyrPheLeuAspGlnIleGluValTrp1025103010351040GlnArgGlnArgMetAspCysAlaVal1045(2) INFORMATION FOR SEQ ID NO: 3:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 4137 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: both(D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(vi) ORIGINAL SOURCE:(A) ORGANISM: Homo sapiens(ix) FEATURE:(A) NAME/KEY: CDS(B) LOCATION:423..3572(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 3:GAATTCGGCACGAGCACTTCCTTCTCGGCTAGATTATCTGAAACTGTTGTCGGTTCTTGA60GATGATACTACCACCGAATGTCTGTGTTTCATTGTCTAGTCCAACCTGTATTGTGGATAT120CTACAACGTTCCGGCAATAGTTTTGCAGGTGCATCACATTTTTGTTTTTGTTTTGGGAGG180AAAAGGGAGGGCACGGCAGCCAGGCTTCATATTCCTACAAGTGCATGCTTCAAGATTACT240GTACTTACAGTGTTTCCAACATCTTCTCATAAAAGGGGAAAGCTTCATAGCCTCAACCAT300GAAGGAAACCAGTCGCATAGGGCATGGAGCTGGAGAACTATAAACAGCCCGTGGTGCTGA360GAGAGGACAACTGCCGAAGGCGCCGGAGGATGAAGCCGCGCAGTGCTGCCAGCCTGTCCT420CCATGGAGCTCATCCCCATCGAGTTCGTGCTGCCCACCAGCCAGCGC467MetGluLeuIleProIleGluPheValLeuProThrSerGlnArg105010551060AAATGCAAGAGCCCCGAAACGGCGCTGCTGCACGTGGCCGGCCACGGC515LysCysLysSerProGluThrAlaLeuLeuHisValAlaGlyHisGly1065107010751080AACGTGGAGCAGATGAAGGCCCAGGTGTGGCTGCGAGCGCTGGAGACC563AsnValGluGlnMetLysAlaGlnValTrpLeuArgAlaLeuGluThr108510901095AGCGTGGCGGCGGACTTCTACCACCGGCTGGGACCGCATCACTTCCTC611SerValAlaAlaAspPheTyrHisArgLeuGlyProHisHisPheLeu110011051110CTGCTCTATCAGAAGAAGGGGCAGTGGTACGAGATCTACGACAAGTAC659LeuLeuTyrGlnLysLysGlyGlnTrpTyrGluIleTyrAspLysTyr111511201125CAGGTGGTGCAGACTCTGGACTGCCTGCGCTACTGGAAGGCCACGCAC707GlnValValGlnThrLeuAspCysLeuArgTyrTrpLysAlaThrHis113011351140CGGAGCCCGGGCCAGATCCACCTGGTGCAGCGGCACCCGCCCTCCGAG755ArgSerProGlyGlnIleHisLeuValGlnArgHisProProSerGlu1145115011551160GAGTCCCAAGCCTTCCAGCGGCAGCTCACGGCGCTGATTGGCTATGAC803GluSerGlnAlaPheGlnArgGlnLeuThrAlaLeuIleGlyTyrAsp116511701175GTCACTGACGTCAGCAACGTGCACGACGATGAGCTGGAGTTCACGCGC851ValThrAspValSerAsnValHisAspAspGluLeuGluPheThrArg118011851190CGTGGCTTGGTGACCCCGCGCATGGCGGAGGTGGCCAGCCGCGACCCC899ArgGlyLeuValThrProArgMetAlaGluValAlaSerArgAspPro119512001205AAGCTCTACGCCATGCACCCGTGGGTGACGTCCAAGCCCCTCCCGGAG947LysLeuTyrAlaMetHisProTrpValThrSerLysProLeuProGlu121012151220TACCTGTGGAAGAAGATTGCCAACAACTGCATCTTCATCGTCATTCAC995TyrLeuTrpLysLysIleAlaAsnAsnCysIlePheIleValIleHis1225123012351240CGCAGCACCACCAGCCAGACCATTAAGGTCTCACCCGACGACACCCCC1043ArgSerThrThrSerGlnThrIleLysValSerProAspAspThrPro124512501255GGCGCCATCCTGCAGAGCTTCTTCACCAAGATGGCCAAGAAGAAATCT1091GlyAlaIleLeuGlnSerPhePheThrLysMetAlaLysLysLysSer126012651270CTGATGGATATTCCCGAAAGCCAAAGCGAACAGGATTTTGTGCTGCGC1139LeuMetAspIleProGluSerGlnSerGluGlnAspPheValLeuArg127512801285GTCTGTGGCCGGGATGAGTACCTGGTGGGCGAAACGCCCATCAAAAAC1187ValCysGlyArgAspGluTyrLeuValGlyGluThrProIleLysAsn129012951300TTCCAGTGGGTGAGGCACTGCCTCAAGAACGGAGAAGAGATTCACGTG1235PheGlnTrpValArgHisCysLeuLysAsnGlyGluGluIleHisVal1305131013151320GTACTGGACACGCCTCCAGACCCGGCCCTAGACGAGGTGAGGAAGGAA1283ValLeuAspThrProProAspProAlaLeuAspGluValArgLysGlu132513301335GAGTGGCCGCTGGTGGACGACTGCACGGGAGTCACCGGCTACCATGAG1331GluTrpProLeuValAspAspCysThrGlyValThrGlyTyrHisGlu134013451350CAGCTTACCATCCACGGCAAGGACCACGAGAGTGTGTTCACCGTGTCC1379GlnLeuThrIleHisGlyLysAspHisGluSerValPheThrValSer135513601365CTGTGGGACTGCGACCGCAAGTTCAGGGTCAAGATCAGAGGCATTGAT1427LeuTrpAspCysAspArgLysPheArgValLysIleArgGlyIleAsp137013751380ATCCCCGTCCTGCCTCGGAACACCGACCTCACAGTTTTTGTAGAGGCA1475IleProValLeuProArgAsnThrAspLeuThrValPheValGluAla1385139013951400AACATCCAGCATGGGCAACAAGTCCTTTGCCAAAGGAGAACCAGCCCC1523AsnIleGlnHisGlyGlnGlnValLeuCysGlnArgArgThrSerPro140514101415AAACCCTTCACAGAGGAGGTGCTGTGGAATGTGTGGCTTGAGTTCAGT1571LysProPheThrGluGluValLeuTrpAsnValTrpLeuGluPheSer142014251430ATCAAAATCAAAGACTTGCCCAAAGGGGCTCTACTGAACCTCCAGATC1619IleLysIleLysAspLeuProLysGlyAlaLeuLeuAsnLeuGlnIle143514401445TACTGCGGTAAAGCTCCAGCACTGTCCAGCAAGGCCTCTGCAGAGTCC1667TyrCysGlyLysAlaProAlaLeuSerSerLysAlaSerAlaGluSer145014551460CCCAGTTCTGAGTCCAAGGGCAAAGTTCGGCTTCTCTATTATGTGAAC1715ProSerSerGluSerLysGlyLysValArgLeuLeuTyrTyrValAsn1465147014751480CTGCTGCTGATAGACCACCGTTTCCTCCTGCGCCGTGGAGAATACGTC1763LeuLeuLeuIleAspHisArgPheLeuLeuArgArgGlyGluTyrVal148514901495CTCCACATGTGGCAGATATCTGGGAAGGGAGAAGACCAAGGAAGCTTC1811LeuHisMetTrpGlnIleSerGlyLysGlyGluAspGlnGlySerPhe150015051510AATGCTGACAAACTCACGTCTGCAACTAACCCAGACAAGGAGAACTCA1859AsnAlaAspLysLeuThrSerAlaThrAsnProAspLysGluAsnSer151515201525ATGTCCATCTCCATTCTTCTGGACAATTACTGCCACCCGATAGCCCTG1907MetSerIleSerIleLeuLeuAspAsnTyrCysHisProIleAlaLeu153015351540CCTAAGCATCAGCCCACCCCTGACCCGGAAGGGGACCGGGTTCGAGCA1955ProLysHisGlnProThrProAspProGluGlyAspArgValArgAla1545155015551560GAAATGCCCAACCAGCTTCGCAAGCAATTGGAGGCGATCATAGCCACT2003GluMetProAsnGlnLeuArgLysGlnLeuGluAlaIleIleAlaThr156515701575GATCCACTTAACCCTCTCACAGCAGAGGACAAAGAATTGCTCTGGCAT2051AspProLeuAsnProLeuThrAlaGluAspLysGluLeuLeuTrpHis158015851590TTTAGATACGAAAGCCTTAAGCACCCAAAAGCATATCCTAAGCTATTT2099PheArgTyrGluSerLeuLysHisProLysAlaTyrProLysLeuPhe159516001605AGTTCAGTGAAATGGGGACAGCAAGAAATTGTGGCCAAAACATACCAA2147SerSerValLysTrpGlyGlnGlnGluIleValAlaLysThrTyrGln161016151620TTGTTGGCCAGAAGGGAAGTCTGGGATCAAAGTGCTTTGGATGTTGGG2195LeuLeuAlaArgArgGluValTrpAspGlnSerAlaLeuAspValGly1625163016351640TTAACAATGCAGCTCCTGGACTGCAACTTCTCAGATGAAAATGTAAGA2243LeuThrMetGlnLeuLeuAspCysAsnPheSerAspGluAsnValArg164516501655GCCATTGCAGTTCAGAAACTGGAGAGCTTGGAGGACGATGATGTTCTG2291AlaIleAlaValGlnLysLeuGluSerLeuGluAspAspAspValLeu166016651670CATTACCTTCTACAATTGGTCCAGGCTGTGAAATTTGAACCATACCAT2339HisTyrLeuLeuGlnLeuValGlnAlaValLysPheGluProTyrHis167516801685GATAGCGCCCTTGCCAGATTTCTGCTGAAGCGTGGTTTAAGAAACAAA2387AspSerAlaLeuAlaArgPheLeuLeuLysArgGlyLeuArgAsnLys169016951700AGAATTGGTCACTTTTTGTTTTGGTTCTTGAGAAGTGAGATAGCCCAG2435ArgIleGlyHisPheLeuPheTrpPheLeuArgSerGluIleAlaGln1705171017151720TCCAGACACTATCAGCAGAGGTTCGCTGTGATTCTGGAAGCCTATCTG2483SerArgHisTyrGlnGlnArgPheAlaValIleLeuGluAlaTyrLeu172517301735AGGGGCTGTGGCACAGCCATGCTGCACGACTTTACCCAACAAGTCCAA2531ArgGlyCysGlyThrAlaMetLeuHisAspPheThrGlnGlnValGln174017451750GTAATCGAGATGTTACAAAAAGTCACCCTTGATATTAAATCGCTCTCT2579ValIleGluMetLeuGlnLysValThrLeuAspIleLysSerLeuSer175517601765GCTGAAAAGTATGACGTCAGTTCCCAAGTTATTTCACAACTTAAACAA2627AlaGluLysTyrAspValSerSerGlnValIleSerGlnLeuLysGln177017751780AAGCTTGAAAACCTGCAGAATTCTCAACTCCCCGAAAGCTTTAGAGTT2675LysLeuGluAsnLeuGlnAsnSerGlnLeuProGluSerPheArgVal1785179017951800CCATATGATCCTGGACTGAAAGCAGGAGCGCTGGCAATTGAAAAATGT2723ProTyrAspProGlyLeuLysAlaGlyAlaLeuAlaIleGluLysCys180518101815AAAGTAATGGCCTCCAAGAAAAAACCACTATGGCTTGAGTTTAAATGT2771LysValMetAlaSerLysLysLysProLeuTrpLeuGluPheLysCys182018251830GCCGATCCTACAGCCCTATCAAATGAAACAATTGGAATTATCTTTAAA2819AlaAspProThrAlaLeuSerAsnGluThrIleGlyIleIlePheLys183518401845CATGGTGATGATCTGCGCCAAGACATGCTTATTTTACAGATTCTACGA2867HisGlyAspAspLeuArgGlnAspMetLeuIleLeuGlnIleLeuArg185018551860ATCATGGAGTCTATTTGGGAGACTGAATCTTTGGATCTATGCCTCCTG2915IleMetGluSerIleTrpGluThrGluSerLeuAspLeuCysLeuLeu1865187018751880CCATATGGTTGCATTTCAACTGGTGACAAAATAGGAATGATCGAGATT2963ProTyrGlyCysIleSerThrGlyAspLysIleGlyMetIleGluIle188518901895GTGAAAGACGCCACGACAATTGCCAAAATTCAGCAAAGCACAGTGGGC3011ValLysAspAlaThrThrIleAlaLysIleGlnGlnSerThrValGly190019051910AACACGGGAGCATTTAAAGATGAAGTCCTGAATCACTGGCTCAAAGAA3059AsnThrGlyAlaPheLysAspGluValLeuAsnHisTrpLeuLysGlu191519201925AAATCCCCTACTGAAGAAAAGTTTCAGGCAGCAGTGGAGAGATTTGTT3107LysSerProThrGluGluLysPheGlnAlaAlaValGluArgPheVal193019351940TATTCCTGTGCAGGCTACTGTGTGGCAACCTTTGTTCTTGGAATAGGC3155TyrSerCysAlaGlyTyrCysValAlaThrPheValLeuGlyIleGly1945195019551960GACAGACACAATGACAATATTATGATCACCGAGACAGGAAACCTATTT3203AspArgHisAsnAspAsnIleMetIleThrGluThrGlyAsnLeuPhe196519701975CATATTGACTTCGGGCACATTCTTGGGAATTACAAAAGTTTCCTGGGC3251HisIleAspPheGlyHisIleLeuGlyAsnTyrLysSerPheLeuGly198019851990ATTAATAAAGAGAGAGTGCCATTTGTGCTAACCCCTGACTTCCTCTTT3299IleAsnLysGluArgValProPheValLeuThrProAspPheLeuPhe199520002005GTGATGGGAACTTCTGGAAAGAAGACAAGCCCACACTTCCAGAAATTT3347ValMetGlyThrSerGlyLysLysThrSerProHisPheGlnLysPhe201020152020CAGGACATCTGTGTTAAGGCTTATCTAGCCCTTCGTCATCACACAAAC3395GlnAspIleCysValLysAlaTyrLeuAlaLeuArgHisHisThrAsn2025203020352040CTACTGATCATCCTGTTCTCCATGATGCTGATGACAGGAATGCCCCAG3443LeuLeuIleIleLeuPheSerMetMetLeuMetThrGlyMetProGln204520502055TTAACAAGCAAAGAAGACATTGAATATATCCGGGATGCCCTCACAGTG3491LeuThrSerLysGluAspIleGluTyrIleArgAspAlaLeuThrVal206020652070GGGAAAAATGAGGAGGATGCTAAAAAGTATTTTCTTGATCAGATCGAA3539GlyLysAsnGluGluAspAlaLysLysTyrPheLeuAspGlnIleGlu207520802085GTTTGGCAGAGACAAAGGATGGACTGTGCAGTTTAATTGGTTTCTACATCTTG3592ValTrpGlnArgGlnArgMetAspCysAlaVal20902095TTCTTGGCATCAAACAAGGAGAGAAACATTCAGCCTAATACTTTAGGCTAGAATCAAAAA3652CAAGTTAGTGTTCTATGGTTTAAATTAGCATAGCAATCATCGAACTTGGATTTCAAATGC3712AATAGACATTGTGAAAGCTGGCATTTCAGAAGTATAGCTCTTTTCCTACCTGAACTCTTC3772CCTGGAGAAAAGATGTTGGCATTGCTGATTGTTTGGTTAAGCAATGTCCAGTGCTAGGAT3832TATTTGCAGGTTTGGTTTTTTCTCATTTGTCTGTGGCATTGGAGAATATTCTCGGTTTAA3892ACAGACTAATGACTTCCTTATTGTCCCTGATATTTTGACTATCTTACTATTGAGTGCTTC3952TGGAAATTCTTTGGAATAATTGATGACATCTATTTTCATCTGGGTTTAGTCTCAATTTTG4012GTTATCTTTGTGTTCCTCAAGCTCTTTAAAGAAAAAGATGTAATCGTTGTAACCTTTGTC4072TCATTCCTTAAATGATGCTTCCAAACATCTCCTTAGTGTCTGCAGGTGTTAGTGGTGTGC4132TAAAA4137(2) INFORMATION FOR SEQ ID NO: 4:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 1050 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 4:MetGluLeuIleProIleGluPheValLeuProThrSerGlnArgLys151015CysLysSerProGluThrAlaLeuLeuHisValAlaGlyHisGlyAsn202530ValGluGlnMetLysAlaGlnValTrpLeuArgAlaLeuGluThrSer354045ValAlaAlaAspPheTyrHisArgLeuGlyProHisHisPheLeuLeu505560LeuTyrGlnLysLysGlyGlnTrpTyrGluIleTyrAspLysTyrGln65707580ValValGlnThrLeuAspCysLeuArgTyrTrpLysAlaThrHisArg859095SerProGlyGlnIleHisLeuValGlnArgHisProProSerGluGlu100105110SerGlnAlaPheGlnArgGlnLeuThrAlaLeuIleGlyTyrAspVal115120125ThrAspValSerAsnValHisAspAspGluLeuGluPheThrArgArg130135140GlyLeuValThrProArgMetAlaGluValAlaSerArgAspProLys145150155160LeuTyrAlaMetHisProTrpValThrSerLysProLeuProGluTyr165170175LeuTrpLysLysIleAlaAsnAsnCysIlePheIleValIleHisArg180185190SerThrThrSerGlnThrIleLysValSerProAspAspThrProGly195200205AlaIleLeuGlnSerPhePheThrLysMetAlaLysLysLysSerLeu210215220MetAspIleProGluSerGlnSerGluGlnAspPheValLeuArgVal225230235240CysGlyArgAspGluTyrLeuValGlyGluThrProIleLysAsnPhe245250255GlnTrpValArgHisCysLeuLysAsnGlyGluGluIleHisValVal260265270LeuAspThrProProAspProAlaLeuAspGluValArgLysGluGlu275280285TrpProLeuValAspAspCysThrGlyValThrGlyTyrHisGluGln290295300LeuThrIleHisGlyLysAspHisGluSerValPheThrValSerLeu305310315320TrpAspCysAspArgLysPheArgValLysIleArgGlyIleAspIle325330335ProValLeuProArgAsnThrAspLeuThrValPheValGluAlaAsn340345350IleGlnHisGlyGlnGlnValLeuCysGlnArgArgThrSerProLys355360365ProPheThrGluGluValLeuTrpAsnValTrpLeuGluPheSerIle370375380LysIleLysAspLeuProLysGlyAlaLeuLeuAsnLeuGlnIleTyr385390395400CysGlyLysAlaProAlaLeuSerSerLysAlaSerAlaGluSerPro405410415SerSerGluSerLysGlyLysValArgLeuLeuTyrTyrValAsnLeu420425430LeuLeuIleAspHisArgPheLeuLeuArgArgGlyGluTyrValLeu435440445HisMetTrpGlnIleSerGlyLysGlyGluAspGlnGlySerPheAsn450455460AlaAspLysLeuThrSerAlaThrAsnProAspLysGluAsnSerMet465470475480SerIleSerIleLeuLeuAspAsnTyrCysHisProIleAlaLeuPro485490495LysHisGlnProThrProAspProGluGlyAspArgValArgAlaGlu500505510MetProAsnGlnLeuArgLysGlnLeuGluAlaIleIleAlaThrAsp515520525ProLeuAsnProLeuThrAlaGluAspLysGluLeuLeuTrpHisPhe530535540ArgTyrGluSerLeuLysHisProLysAlaTyrProLysLeuPheSer545550555560SerValLysTrpGlyGlnGlnGluIleValAlaLysThrTyrGlnLeu565570575LeuAlaArgArgGluValTrpAspGlnSerAlaLeuAspValGlyLeu580585590ThrMetGlnLeuLeuAspCysAsnPheSerAspGluAsnValArgAla595600605IleAlaValGlnLysLeuGluSerLeuGluAspAspAspValLeuHis610615620TyrLeuLeuGlnLeuValGlnAlaValLysPheGluProTyrHisAsp625630635640SerAlaLeuAlaArgPheLeuLeuLysArgGlyLeuArgAsnLysArg645650655IleGlyHisPheLeuPheTrpPheLeuArgSerGluIleAlaGlnSer660665670ArgHisTyrGlnGlnArgPheAlaValIleLeuGluAlaTyrLeuArg675680685GlyCysGlyThrAlaMetLeuHisAspPheThrGlnGlnValGlnVal690695700IleGluMetLeuGlnLysValThrLeuAspIleLysSerLeuSerAla705710715720GluLysTyrAspValSerSerGlnValIleSerGlnLeuLysGlnLys725730735LeuGluAsnLeuGlnAsnSerGlnLeuProGluSerPheArgValPro740745750TyrAspProGlyLeuLysAlaGlyAlaLeuAlaIleGluLysCysLys755760765ValMetAlaSerLysLysLysProLeuTrpLeuGluPheLysCysAla770775780AspProThrAlaLeuSerAsnGluThrIleGlyIleIlePheLysHis785790795800GlyAspAspLeuArgGlnAspMetLeuIleLeuGlnIleLeuArgIle805810815MetGluSerIleTrpGluThrGluSerLeuAspLeuCysLeuLeuPro820825830TyrGlyCysIleSerThrGlyAspLysIleGlyMetIleGluIleVal835840845LysAspAlaThrThrIleAlaLysIleGlnGlnSerThrValGlyAsn850855860ThrGlyAlaPheLysAspGluValLeuAsnHisTrpLeuLysGluLys865870875880SerProThrGluGluLysPheGlnAlaAlaValGluArgPheValTyr885890895SerCysAlaGlyTyrCysValAlaThrPheValLeuGlyIleGlyAsp900905910ArgHisAsnAspAsnIleMetIleThrGluThrGlyAsnLeuPheHis915920925IleAspPheGlyHisIleLeuGlyAsnTyrLysSerPheLeuGlyIle930935940AsnLysGluArgValProPheValLeuThrProAspPheLeuPheVal945950955960MetGlyThrSerGlyLysLysThrSerProHisPheGlnLysPheGln965970975AspIleCysValLysAlaTyrLeuAlaLeuArgHisHisThrAsnLeu980985990LeuIleIleLeuPheSerMetMetLeuMetThrGlyMetProGlnLeu99510001005ThrSerLysGluAspIleGluTyrIleArgAspAlaLeuThrValGly101010151020LysAsnGluGluAspAlaLysLysTyrPheLeuAspGlnIleGluVal1025103010351040TrpGlnArgGlnArgMetAspCysAlaVal10451050(2) INFORMATION FOR SEQ ID NO: 5:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 15 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 5:AsnSerGlnLeuProGluSerPheArgValProTyrAspProGly151015(2) INFORMATION FOR SEQ ID NO: 6:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH:7 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 6:LysAsnGlyAspAspLeuArg15(2) INFORMATION FOR SEQ ID NO: 7:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH:5 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 7:HisIleAspPheGly15__________________________________________________________________________