Abstract:
Disclosed are compositions which bind to mammalian egg zona pellucida in species-specific fashion. Also disclosed are methods for speciating mammalian eggs, identifying species-specific sperm, and providing contraception in a mammalian population. Specifically disclosed are nucleic acid sequences and the corresponding amino acid sequences of specific sperm membrane proteins they encode, whose identification and characterization have permitted development of species-specific contraceptive and fertility compositions and methods.

Description:
The U.S. Government owns rights in the present invention pursuant to grant number 93-37203-9024 from the U.S. Department of Agriculture. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates generally to the fields of sperm proteins. More particularly, it provides DNA segments encoding sperm proteins that bind to eggs in a species specific manner, methods of making and using such DNA segments and proteins, methods for detecting sperm and eggs, and methods for inhibiting or promoting their interaction. 
     2. Description of the Related Art 
     Mammalian spermatozoa adhere to and then penetrate through the zona pellucida (ZP), an extracellular matrix of the egg; subsequent fusion of the plasma membranes of the gametes completes fertilization (Yanagimachi, 1981). Exocytosis of the sperm acrosome (the acrosome reaction) is one consequence of cellular signaling that occurs during sperm adhesion to the ZP, and is obligatory for sperm penetration of the ZP, possibly because of a requirement for release or exposure of hydrolytic enzymes. Solubilized, conspecific ZP can induce the acrosome reaction in several species (Hardy &amp; Garbers, 1993). Although the sperm surface receptors that transduce the signal for the acrosome reaction have not been identified, receptor-mediated activation of guanine nucleotide-binding regulatory proteins of the Gi class appears to be an important component of the signaling cascade (Hardy &amp; Garbers, 1993; Ward &amp; Kopf, 1993). 
     Homologous spermatozoa fertilize eggs in vitro more efficiently than heterologous spermatozoa, in part because spermatozoa generally adhere preferentially to conspecific ZP (Yanagimachi, 1981; Peterson et al., 1980; Schmell &amp; Gulyas, 1980). Induction of the acrosome reaction by the ZP is also species-selective (Cherr et al., 1986; Moller et al., 1990; Uto et al., 1988), suggesting that the sperm surface proteins that mediate adhesion and/or signaling bind species-specifically to complementary glycoproteins in the ZP. 
     The major glycoproteins that comprise the ZP have been characterized for some animals. In the mouse, an Mr 83,000 glycoprotein designated ZP3 possesses both adhesive activity and acrosome reaction-inducing activity; the other ZP glycoproteins (ZP2 and ZP1) may function as structural components that confer the correct spatial context for ZP3 during these processes (Wassarman, 1988). Hamster ZP3 also possesses the adhesive and acrosome reaction-inducing activity of the egg extracellular matrix, and is homologous to mouse ZP3 (Moller et al., 1990; Kinloch et al., 1990). In the pig, a Mr 55,000 glycoprotein of the extracellular matrix, designated ZP3α, appears to account for sperm adhesive activity (Sacco et al., 1989). The amino acid sequences of porcine ZP3α and mouse ZP3 (deduced from the sequences of cloned cDNAs) are not similar (Yurewicz et al., 1993). Hence, different gene products may mediate adhesion of conspecific spermatozoa to the egg extracellular matrix in different species. However, no mammalian sperm molecules have been identified to date that serve as species-specific adhesion ligands. 
     SUMMARY OF THE INVENTION 
     The present invention seeks to overcome these and other drawbacks inherent in the prior art by providing DNA segments that encode mammalian sperm proteins that bind to eggs in a species specific manner. Also provided are methods of making and using such DNA segments, proteins and peptides, methods for detecting sperm and eggs, and compositions and methods for inhibiting or promoting the interaction of sperm and eggs. 
     To delineate the sperm proteins involved in specific adhesion or signaling, the inventors used native, particulate ZP as an affinity matrix to isolate ZP-binding proteins from detergent-solubilized membranes of pig spermatozoa. Two predominant classes of proteins (p105/45 and p56-62) were identified as minor components of the sperm membrane that bind to the egg extracellular matrix in a species-specific manner. This invention also provides DNA segments and vectors that encode the p105/45 sperm adhesion protein. 
     The invention concerns DNA segments that comprise isolated sperm genes that encode species-specific sperm proteins or peptides, particularly those that include an amino acid sequence essentially as set forth by a contiguous sequence from SEQ ID NO:2, examples of which are those DNA segments that include nucleic acid sequences essentially as set forth by a contiguous sequence from SEQ ID NO:1. 
     The DNA segments may, of course, comprise sperm genes that encode peptides, such as from about 15 to about 30 or about 50 amino acids in length, or may encode longer proteins, e.g., up to about 2476 amino acids in length, in one exemplary embodiment. Also representative is a DNA segment that comprises a sperm gene that has a nucleic acid sequence as set forth by the sequence of SEQ ID NO:1. 
     These DNA segments may be positioned under the control of a promoter, and particularly, a recombinant promoter, in order to create a recombinant vector, such as a recombinant expression vector. 
     Smaller nucleic acid segments are also encompassed, as may be used as probes or primers, such as those that comprises at least a 14 nucleotide long contiguous stretch that corresponds to a nucleic acid sequence of SEQ ID NO:1. Examples include nucleic acid segments with sequences in accordance with SEQ ID NO:3 and SEQ ID NO:4. 
     The DNA segments may be expressed in a cell system, e.g., by preparing and expressing a recombinant vector in which a species-specific sperm adhesion protein gene DNA segment, such as one that encodes a sperm protein or peptide that includes an amino acid sequence essentially as set forth by a contiguous sequence from SEQ ID NO:2, is positioned under the control of a promoter. One would introduce such a recombinant vector into a recombinant host cell, culture the recombinant host cell under conditions effective to allow expression of an encoded sperm protein or peptide, and then collect the expressed sperm protein or peptide. 
     The invention thus also provides protein or peptide compositions, free from total sperm cells, that comprise purified species-specific sperm adhesion proteins or peptides, as represented by one that includes an amino acid sequence essentially as set forth by a contiguous sequence from SEQ ID NO:2. Such proteins or peptides may be native or recombinant forms. 
     The nucleic acids of the present invention may be used in other embodiments, such as in the detection of sperm, or sperm components, in a sample. For example, one may obtain nucleic acids from a sample suspected of containing sperm and contact the nucleic acids with a sperm nucleic acid segment that encodes a species-specific sperm protein or peptide, e.g., one that includes an amino acid sequence essentially as set forth by a contiguous sequence from SEQ ID NO:2. This would be done under conditions effective to allow hybridization of substantially complementary nucleic acids, whereby the hybridized complementary nucleic acids formed could later be detected. 
     Methods for detecting eggs are also provided, such as may be achieved by contacting a porcine egg with a protein or peptide composition that comprises a purified sperm protein or peptide that includes an amino acid sequence essentially as set forth by a contiguous sequence from SEQ ID NO:2 under conditions effective to allow binding of said protein or peptide to said egg. The presence of proteins or peptides bound to the egg would then be detected. 
     The interaction of sperm and eggs may also be altered using the present invention, as may be used as part of either contraceptive or fertilization methods. Such methods generally comprise contacting a sperm or egg with an effective amount of a compound that changes the binding of species-specific sperm adhesion protein(s) to the egg. This may be sued to inhibit the interaction of a sperm and an egg, wherein the compound inhibits the binding of the sperm protein to the egg, or to stimulate the interaction of a sperm and an egg, wherein the compound promotes the binding of the sperm protein to the egg. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The following drawings form part of the present specification and are included to further demonstrate certain aspects of the present invention. The invention may be better understood by reference to one or more of these drawings in combination with the detailed description of specific embodiments presented herein. 
     FIG. 1. Identification of ZP-binding proteins. Shown are SDS-PAGE/Western blots of sperm biotinylated proteins (detected with horseradish peroxidase-conjugated streptavidin). Lanes 1 and 3: 1 μg sperm proteins (particulate fraction) that did not bind ZP. Lanes 2 and 4: ZP-bound proteins (from 1 μg ZP incubated with detergent-solubilized material from 60 μg sperm membrane proteins). Lanes 1 and 2: disulfide bonds not reduced. Lanes 3 and 4: disulfide bonds reduced. Note that 60 times the amount of sperm biotinylated proteins shown in lanes 1 and 3 were used to obtain the ZP-binding proteins shown in lanes 2 and 4. 
     FIGS. 2A, 2B and 2C. FIG. 2 consists of FIGS. 2A, 2B and 2C, which represent the characterization of disulfide bonding. Shown are two-dimensional SDS-PAGE/Western blots of sperm biotinylated proteins (horizontal dimension, disulfide bonds not reduced; vertical dimension, disulfide bonds reduced). Biotin was detected with horseradish peroxidase-conjugated streptavidin. FIG. 2A: ZP-bound proteins (from 2 μg ZP incubated with detergent-solubilized material from 120 μg sperm membrane proteins) remaining after washing with 1% CHAPS/HNE. FIG. 2B: 2 μg ZP non-binding fraction of sperm proteins. FIG. 2C: ZP-bound proteins (from 2.5 μg ZP incubated with detergent-solubilized material from 50 μg sperm proteins) remaining after washing with 1% CHAPS/HNE and again with mRIPA. 
     FIG. 3. Binding of pig sperm proteins to mouse or pig ZP. Shown are SDS-PAGE/Western blots of sperm biotinylated proteins (detected with horseradish peroxidase-conjugated streptavidin). Lanes 1 and 3: pig sperm proteins that bound to mouse ZP. Lanes 2 and 4: pig sperm proteins that bound to pig ZP. All lanes: ZP-bound proteins (from 1.25 μg ZP incubated with detergent-solubilized material from 80 μsperm membrane proteins) remaining after washing with 1% CHAPS/HNE. Lanes 1 and 2: disulfide bonds not reduced. Lanes 3 and 4: disulfide bonds reduced. 
     FIG. 4. FIG. 4 consists of FIG. 4, Right Panel and FIG. 4, Left Panel, which represent the binding of pig sperm proteins to pig ZP, bovine ZP, or Xenopus oocyte envelopes. Shown are SDS-PAGE/Western blots of sperm biotinylated proteins (detected with horseradish peroxidase-conjugated streptavidin) remaining bound, after washing with 1% CHAPS/HNE, to: Lane 1, 1 μg pig ZP; Lane 2, 0.4 μg bovine ZP; Lane 3, 1 μg Xenopus oocyte envelopes. Lanes 4-6: same as Lanes 1-3, respectively, after washing again with mRIPA. Left panel: disulfide bonds not reduced. Right panel: disulfide bonds reduced. 
     FIG. 5. Purification and characterization of p50. Lane 1: Western blot, biotinylated proteins detected with horseradish peroxidase-streptavidin, of pig sperm proteins that had bound to 2.5 μg pig ZP and were then eluted from ZP with mRIPA. Lane 2: Coomassie blue stained SDS-PAGE of p50 that had bound to pig ZP and was then eluted from the ZP with mRIPA and purified by streptavidin-agarose chromatography. Lanes 3-6: Western blots, proacrosin detected with a monospecific heteroantiserum. Lane 3: proteins that had bound to 10 μg pig ZP and were then eluted from the ZP with mRIPA. Lanes 4-6: Same samples as Lanes 1-3 of FIG. 4. All lanes: disulfide bonds reduced. 
     FIG. 6. Purification of p105/45. Lane 1: SDS-PAGE/western blot (disulfide bonds reduced) of biotinylated proteins from detergent-solubilized pig sperm membranes that remained bound to native porcine ZP after extensive washing (by centrifugation) consecutively with 1% CHAPS/HNE  1% (w/v) CHAPS in 20 mM NaHEPES, 130 mM NaCl, 1 mM EDTA, pH 7.5!, and then with mRIPA  1% (v/v) NP-40, 0.5% sodium deoxycholate, 0.1% SDS in 25 mM NaHEPES, 0.5M NaCl, 1 mM EDTA, pH7.5!. Biotinylated proteins were detected with peroxidase-conjugated streptavidin and enhanced chemiluminescence. Lane 2: SDS-PAGE (reducing conditions, stained with Coomassie brilliant blue R-250) of p105/45 purified by large-scale binding of biotinylated sperm membrane proteins to native ZP and subsequent separation of biotinylated proteins from ZP by streptavidin-agarose chromatography. 
     FIG. 7. Composite nucleotide sequence of overlapping cDNAS cloned using a p105 specific probe and by 5&#39; RACE. 
     FIG. 8. Deduced sequence and properties of the 2476 residue protein encoded by the 7431 base open reading frame identified in the sequence of the p105/45 message. 
     FIG. 9. Dot matrix plot of 2476 residue deduced sequence compared with itself. A highly repetitive region of the sequence is readily apparent between residues 300 and 700. Four mutually similar domains of approximately 400 residues each, and part of a fifth such domain, were also detected as indicated by the broken lines parallel to the diagonal. 
     FIG. 10. Restriction map of the composite nucleotide sequence, predicted domain structure of the 2476 residue protein deduced from the long open reading frame of the p105/45 message, and locations of p105 and p45 peptide sequences within the deduced sequence. 
     FIG. 11. Northern blot of poly(A) +  RNAs isolated from pig tissues hybridized with a 900 bp  32  P-labeled p105/45 specific probe. H: 4.5 μg heart RNA, B: 4.5 μg brain RNA, E: 3.4 μg epididymis RNA, K: 3.3 μg kidney RNA, Li: 2.9 μgliver RNA, T: 3.0 μg testis RNA. Migration of RNA standards (Bethesda Research Laboratories) is indicated on the left. 47 hour exposure. 
     FIG. 12. Consists of Panels A through E, which represent the localization of p105/45 message expression by in situ hybridization. FIG. 12, Panel A: hybridization of antisense RNA probe viewed at 40× magnification with dark field illumination. FIG. 12, Panel B: same field, illumination, and exposure as panel A of a parallel section hybridized with a sense RNA probe. FIG. 12, Panel C: Same field as panels A and B of a parallel section stained with hematoxylin and eosin and viewed with bright field illumination. By comparing panels A-C, note that specific hybridization of the antisense RNA probe is strong only in seminiferous tubules. FIG. 12, Panel D: a second field rich in seminiferous tubules hybridized and viewed as panel A. Note than only a small subset of seminiferous tubules expressed high levels of the p105/45 message at the time the tissue was collected. FIG. 12, Panel E: 250× phase contrast view (no counterstain) of two adjacent seminiferous tubules (boxed region of panel D). Note the difference in the level of p105/45 message expression between the two tubules. Expression in the strongly stained tubule is high in spermatids; note the clear zones appearing as halos surrounding the large round nuclei of spermatocytes (arrowheads) that indicate an absence of expression in the cytoplasm of these cells. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     The zona pellucida is an extracellular matrix surrounding the mammalian egg where species-specific gamete recognition and signaling occur. Pig zona pellucida were isolated in large amounts and used as an affinity matrix for detergent-solubilized, biotinylated membrane proteins of pig spermatozoa. On non-reducing SDS-polyacrylamide gel electrophoresis, specifically bound sperm proteins migrated with Mr 170,000, 150,000, 130,000, 56,000, and 50,000 (p50). Disulfide bond reduction separated each of the Mr 130-170,000 proteins into Mr 105,000 (p105) and Mr 45,000 (p45) subunits, indicating that these high Mr proteins are related. Based on two-dimensional electrophoresis, the Mr 56,000 band was composed of 3-4 proteins that migrated with Mr 56-62,000 (p56-62) in the second (reducing) dimension. p50 bound to heterologous zona pellucida (murine, bovine) and to Xenopus laevis oocyte envelopes, demonstrating a lack of species-specificity to its binding, and was identified as proacrosin/acrosin based on amino acid sequences of two tryptic peptides and its interaction with monospecific antibodies to proacrosin. In contrast, p105/p45 and one or more of the p56-62 proteins bound to pig zona pellucida but not to the egg extracellular matrices of the other species; these proteins therefore exhibited the species-specific binding to the zona pellucida expected for molecules involved in specific gamete adhesion. Amino acid sequences of nine tryptic peptides derived from p105/p45 did not match peptide sequences in existing databases, establishing it as a unique protein. 
     Degenerate oligonucleotide primers designed from tryptic peptide sequences of p105/45 were used to amplify a PCR product that encoded part of the protein; this PCR product was subsequently used as a probe to clone overlapping cDNAs that represent the entire coding sequence of the p105/45 mRNA. The 7785 base composite sequence contained a 7431 bp open reading frame; the sequences of eight tryptic peptides from p105 and five tryptic peptides from p45 were present in the 2476 amino acid deduced sequence, confirming that the open reading from encoded p105/45. The deduced sequence predicted a 2418 residue N-terminal extracellular region, a single transmembrane domain, and a 37 residue C-terminal intracellular segment. Dot matrix analysis identified four similar extracellular domains of approximately 400 residues each, and part of a fifth such domain. 
     Surprisingly, database comparisons revealed that the p105/45 domains are homologous to the D-domains of von Willebrand factor. The putative extracellular sequence also contained a region consisting of 53 imperfect repeats of a 7 residue sequence rich in proline and threonine residues that is characteristic of mucins. Northern blots and in situ hybridization detected expression of the p105/45 message only in spermatids. Thus, p105/45 is a sperm membrane specific protein that binds to the ZP and has structural characteristics similar to two different classes of molecules that regulate cellular interactions; these properties indicate a function for p105/45 in sperm adhesion to the zona pellucida. 
     The following examples are included to demonstrate preferred embodiments of the invention. It should be appreciated by those of skill in the art that the techniques disclosed in the examples which follow represent techniques discovered by the inventor to function well in the practice of the invention, and thus can be considered to constitute preferred modes for its practice. However, those of skill in the art should, in light of the present disclosure, appreciate that many changes can be made in the specific embodiments which are disclosed and still obtain a like or similar result without departing from the spirit and scope of the invention. 
     EXAMPLE I 
     Purification and Characterization of Species Specific Egg-Binding Proteins From Sperm 
     A. Materials and Methods 
     1. Protein Assay 
     Protein concentrations were measured with bicinchoninic acid (Pierce chemical Co.), using bovine serum albumin as a standard (Smith et al., 1985). 
     2. Electrophoresis 
     Polyacrylamide gel electrophoresis (PAGE; 8% polyacrylamide gels) in the presence of SDS was performed according to Laemmli (Laemmli, 1970). Disulfide bonds were reduced by heating (95° C., 5 min) in electrophoresis sample buffer containing 20 mM dithiothreitol. Two-dimensional SDS-PAGE was performed by loading extruded 1.5 mm tube gels of non-reduced samples horizontally on the top of 1.5 mm slab gels for electrophoresis under reducing conditions. In the second dimension, proteins were reduced during stacking by overlaying the tube gel with 1% (w/v) melted agarose in 1× stacking gel buffer containing 2% (w/v) SDS and 50 mM dithiothreitol prior to electrophoresis. 
     Western blots 
     Proteins separated by SDS-PAGE were transferred to nitrocellulose membranes (Sartorius, Hayward, Calif.) by Western blotting (6 V/cm, 2 h, 22° C.) (Towbin et al., 1979). Biotinylated proteins were detected by incubating (15 min, 22° C.) the nitrocellulose sheets containing the transferred proteins (blots) with horseradish peroxidase-conjugated streptavidin (TAGO Immunologicals, Burlingame, Calif.) diluted 10,000-fold in TBST (10 mM Tris.HCl pH 7.5, 150 mM NaCl, 0.1% Tween 20); after washing with TBST (2×10 s, 2×15 min, 22° C.), peroxidase activity was detected by enhanced chemiluminescence (Amersham, Arlington Heights, Ill.). Proacrosin was detected with a monospecific antiserum to proacrosin (Hardy et al., 1987). Blots were incubated at least 1 h at 22° C. in antiserum diluted 1000-fold in TBST. After washing with TBST as for biotin detection, blots were incubated 1 h at 22° C. with horseradish peroxidase-conjugated antibody to rabbit immunoglobulin (TAGO Immunologicals) diluted 10,000-fold in TBST. Blots were then washed and developed as for biotin detection. 
     Preparation of zona pellucida and Xenopus oocvte envelopes 
     Porcine oocytes were isolated from sliced ovaries by step-wise sieving through screens (Dunbar et al., 1980). Up to 10 l of ovaries were used per preparation. Bovine oocytes were also isolated by sieving; up to 200 ovaries were sliced with a hand-held tool fixed with one set of ganged razor blades. Porcine and bovine ZP were isolated from oocytes by homogenization in detergent and ultracentrifugation through Percoll as for isolation of mouse ZP (see below). 
     Mouse ZP were isolated from freshly dissected mouse (HSD.ICR strain, 21-28 d old, Harlan-Sprague Dawley, Indianapolis, Ind.) ovaries (Bleil &amp; Wassarman, 1986). After homogenization in buffer containing 1% (v/v) NP-40, and addition of sodium deoxycholate to 1% (w/v), ovary homogenates were mixed with isotonic Percoll (Pharmacia, Piscataway, N.J.) to produce a 50% (v/v) Percoll suspension and ultracentrifuged for 40 min at 90,000 g (35,000 rpm, Beckman 70.1 Ti rotor, 2° C.). A single, sharp ZP band was recovered at approximately 50% of the total distance of the resultant Percoll gradient. Purified ZP were washed at least 1000-fold with 1% (w/v) CHAPS in buffer HNE (20 mM NaHEPES, 130 mM NaCl, 1 mM EDTA pH 7.5) by centrifugation (2500 g, 10 min, 2° C.), resuspended in 1% CHAPS/HNE at 1-4 mg protein/ml, and stored frozen at -20° C. 
     By phase contrast microscopy, all ZP preparations appeared to contain only ZP fragments, and fewer than one in ten of the fragments contained adherent granular material derived from the egg cytoplasm. 
     Oocyte envelopes (OE) were isolated from ovaries of adult Xenopus laevis (Hedrick &amp; Hardy, 1991), then washed with 1% CHAPS/HNE and stored frozen at -20° C. as for ZP isolation. 
     Isolation of pig sperm membranes 
     Spermatozoa were flushed (retrograde) from caudal epididymides of mature boars (up to 20 tissues per preparation) with a HEPES-buffered capacitation medium containing 10 μg/ml heparin (Florman et al., 1989), and capacitated at 39° C. for 4 h (Florman &amp; First, 1988). The cell suspension was then centrifuged (1000 g, 20 min, 2° C.), and the sperm pellets were frozen on dry ice and stored at -20° C. 
     Frozen sperm pellets were thawed on ice in 600 ml HE/DFP (50 mM NaHEPES, 1 mM NaEDTA, 1 mM DFP pH 7.5, 0° C.). The cell suspension was filtered through a 210 μm nylon screen and equilibrated to 650 psi N 2  (30 min, 0° C.) in a Parr bomb. The cells were then disrupted by cavitation (Gillis et al., 1978), centrifuged (4000 g, 10 min, 2° C.), and the supernatant solution containing crude membranes was centrifuged again (235,000 g, 40 min, 2° C., Beckman Ti 45 rotor). The membrane pellets were resuspended by homogenization in 30 ml fresh HE/DFP (15 ml Dounce, tight pestle, on ice), and the membranes were washed once by dilution with 100 ml HE/DFP and ultracentrifugation (235,000 g, 40 min, 2° C.). The washed pellets were then resuspended at 20 mg protein/ml in fresh HE/DFP by Dounce homogenization. This particulate fraction was either biotinylated immediately or frozen and stored at -20° C. Using this method, a cumulative yield of 1360 mg membrane protein was obtained from 518 g of pig spermatozoa (5 preparations). 
     In some preliminary studies, the crude membranes were further purified by fractionation on sucrose step gradients  10, 20, 30, 40% (w/v) in HE/DFP!; however, results obtained with these purified membrane fractions were similar to those obtained with the crude particulate fraction, so further purification of the membranes was not routine. 
     Biotinylation and membrane protein solubilization 
     Amino groups of sperm membrane proteins were biotinylated with the 2-sulfo-N-hydroxysuccinimidyl ester of 6-N-caproylbiotinamide (NHS-LC-biotin, Pierce Chemical Co., Rockford, Ill.). Routinely, 40 μl of NHS-LC-biotin stock solution (50 mM in H 2  O, prepared fresh) were added per ml of membrane suspension (20 mg protein/ml in HE/DFP) to produce a ratio of approximately 1 mol NHS-LC-biotin per 100 mol protein amino acid. After rocking for 1 h at 22° C., 20 μl 1M TrisHCl pH 8.0 were added per ml of membrane suspension, and the mixture was rocked an additional 10 min at 22° C. to quench the biotinylation reaction. The biotinylated membranes were then diluted 3-fold with fresh HE/DFP and centrifuged 25 min, 277,000 g at 2° C. (Beckman 70.1 Ti rotor) for preparative scale studies, or 15 min, 540,000 g at 2° C. (Beckman TLA 100.3 rotor) for analytical scale studies. The biotinylated membranes were then resuspended at 20 mg protein/ml in HE/DFP by dounce homogenization, on ice. 
     Biotinylated membranes were solubilized by adding an equal volume of 2% (w/v) CHAPS in 300 mM NaCl containing 100 μM aprotinin, 20 μM E-64, and 2 mM EDTA. After rocking for 10 min at 22° C., the membrane/detergent mixture was centrifuged as after biotinylation, and the clear supernatant solution (=detergent solubilized, biotinylated membrane protein fraction) was used for all binding studies. The SDS-PAGE patterns of the biotinylated sperm proteins obtained were identical whether proteins were detected directly (by Coomassie blue or silver staining the gels) or by detecting biotin after western blotting (by enhanced chemiluminescence). Thus, the procedure appeared to result in uniform biotinylation of the proteins in the sperm particulate fractions. 
     Identification and isolation of ZP-binding proteins 
     Unless otherwise noted, ZP-binding reactions were at 22° C. with continuous mixing using 40 μl of detergent-solubilized membranes (from 20 μg membrane protein) per 1 μg particulate ZP protein. Purified ZP in 1% CHAPS/HNE were centrifuged (2500 g, 5 min, 4° C. for preparative studies; 15,000 g, 1 min, 22° C. for analytical studies) to remove excess buffer. Solubilized, biotinylated membrane protein was then mixed with the ZP pellets, and the resultant suspension was rocked for 1 h at 22° C. Analytical scale reactions (100 μg ZP protein) were washed 320,000-fold either quickly at 22° C. with 5×200 μl wash buffer (1% CHAPS/HNE) on a manifold equipped with a 96 well 0.45 μm hydrophilic membrane filtration plate (Millipore, Bedford, Md.), or at 2° C. with 5×500 μl wash buffer by centrifugation (15,000 g, 30 s). The washed ZP with bound, biotinylated proteins from sperm membranes were then solubilized in 40 μl 1X SDS-PAGE sample buffer (no reducing agent). Preparative scale reactions (up to 10 mg ZP protein) were washed at 2° C. with 4×10 ml wash buffer (160,000-fold wash) by centrifugation (2500 g, 5 min). The ZP pellets with bound sperm proteins were then washed once quickly with 5 ml H 2  O (0° C.) by centrifugation (2500 g, 5 min, 2° C.). In some studies, the resultant pellet was dissolved by adding an equal volume of 0.2% (w/v) SDS, and incubating at 22° C. for 45 min. Alternatively, the ZP pellet was washed again by adding an equal volume of 2×-concentrated mRIPA  10 mM NaHEPES pH 7.5, 1M NaCl, 2% (v/v) NP-40, 1% (w/v) NaDeoxycholate, 0.2% (w/v) SDS!, rocking for 30 min at 22° C., and then microfuging (2 min, 14,000 g, 22° C.). Following three more equal volume washes with 1× mRIPA, the mRIPA washes containing eluted sperm proteins were pooled and stored frozen at -20° C. The mRIPA-washed ZP pellet was washed twice more with H 2  O by microfugation as for mRIPA , dissolved in SDS as described above, and stored frozen at -20° C. 
     Biotinylated sperm proteins that had bound to the ZP were separated from solubilized ZP glycoprotein by affinity chromatography on streptavidin-agarose (Pierce Chemical Co., Rockford, Ill.). Stock solutions of NaCl, NaDeoxycholate, and NP-40 were added to SDS-solubilized ZP/binding proteins to produce 1× mRIPA concentrations, and the solution (containing up to 23 mg ZP protein) was applied to a streptavidin-agarose column (0.5 ml bed volume, equilibrated in mRIPA). The column was washed with 20 bed volumes of mRIPA and 10 bed volumes of H 2  O. The column bed containing bound, biotinylated proteins was then collected in 0.5 ml elution buffer  4% (w/v), 2 mM D-biotin, 125 mM TrisHCl pH 6.8! and the suspension heated (95° C., 20 min). The suspension was then poured back into the empty column and washed with 1×0.5 ml 6M urea containing 1 mM D-biotin and then with 3×0.5 ml H 2  O to collect the eluted, biotinylated sperm proteins. 
     Peptide mapping and amino acid sequencing 
     Biotinylated ZP-binding proteins purified by streptavidin-agarose chromatography were separated by SDS-PAGE, blotted to polyvinylidene difluoride membranes, and proteolyzed in situ with trypsin (Fernandez et al., 1992). Tryptic peptides released from the membrane were purified by sequential reversed-phase HPLC separations with two different solvent systems (Fernandez et al., 1992; Krupinski et al., 1989). The twice-purified peptides were then sequenced by automated Edman degradation using Applied Biosystems model 475A or 477A sequenators (Krupinski et al., 1989). 
     B. Results 
     Results of a typical ZP-binding study are shown in FIG. 1. Biotinylated proteins of Mr 170,000, 150,000, 130,000, 72,000, 56,000 and 50,000 bound to the ZP as assessed by non-reducing SDS-PAGE. The proteins that bound to the ZP were not major sperm biotinylated proteins, suggesting specificity to their interaction. However, the amount of the 72,000 Mr protein that bound to the ZP at physiological salt concentrations was highly variable, and decreased dramatically at ionic strengths above 150 mM, suggesting that this protein bound primarily by ionic interactions that may not be specific. In contrast, the other proteins consistently bound to the ZP even at high ionic strength. Disulfide bond reduction altered the migration of the sperm proteins (FIG. 1); under reducing conditions, 105,000, 78,000, 56,000, 50,000, and 45,000 Mr bands were observed. 
     The differences in the electrophoretic patterns obtained under reducing and non-reducing conditions suggested that the ZP-binding proteins possessed intra- and intermolecular disulfide bonds. To characterize further these disulfide bonds, ZP-bound proteins were separated by two-dimensional SDS-PAGE (disulfide bonds not reduced in the first dimension, reduced in the second dimension), then detected on Western blots (FIG. 2). The two-dimensional SDS-PAGE pattern of the ZP-bound fraction (FIG. 2A) differed markedly from the patterns observed for the starting material in the binding study and for the ZP non-binding fraction (FIG. 2B). The Mr 130,000, 150,000, and 170,000 proteins migrated as Mr 105,000 (p105) and Mr 45,000 (p45) subunits after reduction (FIGS. 2A &amp; 2C). Thus the Mr 130-170,000 proteins are related, each being comprised in part of p105 and p45, and they will be referred to collectively as p105/45. Some of the very high Mr material that migrated near the top and at the stacking/resolving interface of the first dimension also contained p105 and p45 (FIGS. 2A &amp; 2C), and could represent covalent oligomers of p105/45. Reduction decreased the mobility of the Mr 72,000 protein, but did not change the mobility of the Mr 50,000 protein (p50). In addition, 3 or 4 biotinylated proteins that comprised the Mr 56,000 band were resolved (Mr 56,000-62,000 under reducing conditions). These proteins will be referred to collectively as p56-62. The results are summarized in Table 1. 
     
                       TABLE 1______________________________________Summary of characteristics of ZP-binding proteinsM.sub.r             Protein    SpeciesNot reduced      Reduced      designation                              specificity______________________________________i &gt;&gt;200,000      105,000      p105/45    +      45,000130,000-170,000      105,000      p105/45    +      45,00072,000     78,000                  -56,000     56,000-62,000                   p56-62     ±50,000     50,000       p50        -______________________________________ 
    
     As the sperm proteins that bound reproducibly to the ZP at physiological ionic strength were minor proteins relative to those that did not bind, specificity of binding was evident, but species-selective binding would more strongly suggest that the bound proteins were of physiological importance. Although p50 in 1% CHAPS/HNE bound to both pig ZP and mouse ZP, p105/45 and one or more of the p56-62 proteins did not bind to the mouse ZP under these or other conditions tested (FIG. 3). Similar results also were obtained using bovine ZP and egg envelopes isolated from Xenopus laevis oocytes; in 1% CHAPS/HNE, p50 appeared to bind equally well to pig ZP, bovine ZP, and Xenopus envelopes, but one or more of the p56-62 proteins bound primarily and p105/45 bound exclusively to the pig ZP (FIG. 4). When these egg investments with bound pig sperm proteins were subsequently washed with a stronger combination of detergents and ionic strength (mRIPA) to examine relative binding affinities, the species specificity of p105/45 binding to the ZP was particularly evident (FIGS. 4 and 2C). Under these conditions, p50 and most or all of the p56 proteins were eluted from the pig ZP. Essentially no pig sperm proteins remained bound to mRIPA-washed bovine ZP or Xenopus envelopes. In contrast, p105/45 bound to the pig ZP with remarkably high apparent affinity, since it remained quantitatively bound to the pig ZP even after extensive washing with buffers containing high concentrations of detergent and NaCl (FIG. 4, lane 4). 
     To purify ZP-binding proteins for amino acid sequencing, the inventors performed large scale ZP-binding reactions using pig ZP and 1% CHAPS-solubilized, biotinylated proteins from pig sperm particulate fractions; the ZP with bound sperm proteins were washed extensively with 1% CHAPS/HNE in a manner similar to the analytical scale studies. Since the p45 subunit of p105/45 could not be resolved from p50 in one-dimensional SDS-PAGE, the inventors washed the ZP (and associated sperm proteins) with mRIPA to remove p50 (FIG. 5); p50, p105, and p45 were then purified by chromatography on streptavidin-agarose, and tryptic peptides isolated from the purified proteins were sequenced. The sequences of two p50 peptides were found to match residues 100-112 and 123-132 of the porcine proacrosin sequence (Baba et al., 1989). On immuno blots, p50 that had bound to pig ZP reacted strongly with a monospecific antibody to proacrosin (FIG. 5), as did p50 that bound to bovine ZP or Xenopus envelopes. Thus p50 is proacrosin/acrosin. Two other processed forms of proacrosin also were recognized by the proacrosin antibody (FIG. 5). 
     Sequences of seven p105 peptides and two p45 peptides were also obtained and compared with the sequences in the PIR 37 and Swiss-Prot 26 databases. No significant matches with known sequences were found. 
     C. Discussion 
     By using the extracellular matrix of the porcine egg as an affinity matrix, the inventors have isolated sperm proteins that are involved in species-specific gamete adhesion and/or signaling. The approach used has the advantage of isolating sperm molecules that interact with the zona pellucida of the egg without prior knowledge of the potential functions of any protein. Various evidence suggests that the binding of the sperm proteins was specific. First, only minor sperm proteins bound to the ZP under the described conditions, indicating that the observed binding was not adventitious binding that could occur with major proteins of the sperm membrane. Second, the apparent affinities of binding were very high, since the proteins remained bound even after extensive washing by centrifugation. And third, the p105/45 and p56-62 classes of protein bound in a species specific manner to the ZP. Although the use of high apparent affinity as a criterion may exclude important regulatory proteins that bind less avidly than p105/45 or p56-62, the method provides a novel means to assess the molecular basis of gamete recognition and signaling at the sperm surface. 
     Since acrosome-intact spermatozoa adhere preferentially to the ZP surrounding conspecific eggs in vitro (Yanagimachi, 1981; Peterson et al., 1980; Schmell &amp; Gulyas, 1980), and the limited amount of information available indicates that induction of the acrosome reaction by the ZP is at least species selective (Cherr et al., 1986; Moller et al., 1990; Uto et al., 1988), species-specificity of sperm protein binding to the ZP appears to be one of the most important criteria for functional relevance. The species-specific binding of p105/45 and of one or more of the p56-62 proteins indicates that these proteins mediate, at least in part, the species-specific adhesion of spermatozoa to the ZP, and possibly transduction of the signal for the acrosome reaction as well. 
     Sperm proteins that may recognize the egg extracellular matrix have been identified previously using a number of different methods. For example, solubilized, labeled (biotin or  125  I) ZP bound to proacrosin/acrosin that is purified by reversed-phase HPLC or separated by SDS-PAGE and transferred to nitrocellulose blots (Jones &amp; Brown, 1987; Topfer-Peterson &amp; Henschen, 1987; Urch &amp; Patel, 1991). Although small differences in the binding of homologous and heterologous ZP to proacrosin/acrosin (on blots) were observed (Williams &amp; Jones, 1993), species-specificity was generally not apparent. Since pig proacrosin/acrosin bound to all egg investments tested in these studies, the inventors conclude that the ZP-binding activity of this protein alone does not account for species-specific adhesion of spermatozoa to the ZP. 
     Several small (10-20,000 Mr) proteins of pig spermatozoa have been identified on western blots probed with  125  I-labeled, solubilized ZP (O&#39;Rand et al., 1985; Jonakova et al., 1991; Parry et al., 1992). At least some of these proteins are present in accessory gland secretions and on spermatozoa in high concentrations (O&#39;Rand et al., 1985; Jonakova et al., 1991; Parry et al., 1992) suggesting that they bind the ZP with low affinity. These proteins, if present, would have migrated at the dye front of our gels and would not have been detected. 
     A 95,000 Mr apparent ZP-binding protein has also been identified on western blots of mouse sperm proteins probed with  125  I-labeled, solubilized ZP (Leyton &amp; Saling, 1989). Evaluating the specificity of binding observed with this method is difficult, since specificity would depend on the concentrations of ZP and sperm proteins used and the extent to which native structure of these proteins was retained or recovered. Nevertheless, this technique is effective in some receptor-ligand systems. The method the inventors used for identification of ZP-binding proteins avoids denaturation of ZP or sperm proteins prior to their interaction. The fact that the inventors did not observe a 95,000 Mr ZP-binding protein suggests that prior denaturation of sperm proteins, ZP, or both is necessary for association of this protein with ZP glycoproteins. Denaturation may also explain why some of the ZP-binding proteins the inventors identified were not detected in previous studies. 
     A function for galactosyl transferase in mouse sperm adhesion to the ZP has been extensively characterized using a variety of methods (Shur, 1989; Miller et al., 1992). Mouse sperm surface galactosyl transferase is a 60,000 Mr plasma membrane-associated variant, encoded by an alternate transcript, of the enzyme that is expressed in the Golgi of other tissues (Lopez et al., 1991; Shur &amp; Neely, 1988). A 56,000 Mr protein on the surface of mouse spermatozoa, designated sp56, has been identified by photoaffinity cross-linking using solubilized,  125  I-labeled ZP3 as the ligand (Bleil &amp; Wassarman, 1990). A sperm membrane protein designated PH-20 that exists as 64,000 and 56,000 Mr isoforms has been identified with a monoclonal antibody that inhibits adhesion of guinea pig spermatozoa to the ZP (Primakoff et al., 1985; Primakoff et al., 1988). Species-specificity of galactosyl transferase, sp56, or PH-20 binding to the ZP has not been reported. 
     The inventors conclude that two distinct classes of sperm membrane proteins (p105/45 and p56-62) may mediate species-specific adhesion of pig spermatozoa to the egg extracellular matrix. These studies are the first to use apparent high affinity binding to intact ZP and species-selectivity as criteria for specificity, and the first to identify a ZP-binding protein with the characteristics of p105/45. 
     EXAMPLE II 
     Cloning and Sequencing of p105/45 
     A. Materials and Methods 
     1. p105/45 purification and peptide sequencing 
     p105/45 was purified by large scale binding of detergent-solubilized, biotinylated sperm membrane proteins to native porcine zona pellucida, with subsequent separation of bound, biotinylated proteins from zona pellucida by streptavidin-agarose chromatography (Example I). SDS-PAGE, peptide mapping and sequencing, western blots, and detection of biotinylated proteins with peroxidase-conjugated streptavidin and enhanced chemiluminescence were also as described in Example I. 
     2. RNA isolation 
     Total RNA was isolated by homogenizing tissues in guanidinium thiocyanate and N-lauroyl sarcosine, extracting with acidic phenol/CHCl 3 , and precipitating with isopropanol (Chomczynski &amp; Sacchi, 1987). Poly(A)+RNA was isolated from total RNA by oligo(dT)-cellulose chromatography (Fast Track Kit, Invitrogen). RNAs larger than 5 kb in length were purified from total RNA by gen filtration on Sephacryl S-1000. 
     3. Polymerase chain reaction (PCR) 
     PCR with degenerate oligonucleotide primers (Midland Certified Reagent Co.) was performed in 100 μl volumes containing 53 ng template DNA, 0.5 μM each primer, 200 μM each dNTP, and 5 U Taq polymerase in buffer (10 mM Tris-Cl pH 8.3, 1.5 mM MgCl 2 , 50 mM KCl 0.01% gelatin). Amplifications were for 40 cycles (denature 94° C. 1 min, anneal 50° C. 2 min, extend 72° C. 3 min) using a conventional thermal cycler (Ericomp). Sequences of degenerate primers were: 
     GAATTCGAATTCGA(A/G)GGICA(A/G)CCICCIGCITT(C/T)TA(C/T)(C/T)T (sense, SEQ ID NO:3) and GGATCCGGATCCCAIGCIGGIGC(C/T)TG(A/G)AAIGCIGC(C/T)TG (antisense, SEQ ID NO:4). PCR with specific oligonucleotide primers (5&#39; RACE, see below) was performed in glass capillaries (10 μl reaction volume) using air-driven thermal cycler (Idaho Technologies). Amplifications were for 35 cycles (denature 94° C. 0 s, anneal 60° C. 0 s, extend 72° C. 30 s) with 0.5 μM each primer, 200 μM each dNTP, and 2.5 U Taq polymerase in buffer (50 mM Tris-Cl pH 8.3, 2.0 mM MgCl 2 , 0.25 mg/ml BSA, 1 mM tartrazine, 0.5% ficoll). 
     4. cDNA library construction and screening 
     cDNA libraries were prepared from pig testis poly(A) +  RNA by priming first strand synthesis with either oligo-dT or random hexamers. Double-stranded cDNA with EcoRI sticky ends was prepared using the Superscript Choice kit (Bethesda Research Laboratories) and ligated into EcoRI-cut, dephosphorylated λZAPII (Stratagene). The resultant phage DNA was packaged with Gigapack Gold II (Stratagene). All libraries were screened first as primary libraries (unamplified) by hybridizing duplicate nylon filter (Hybond N, Amersham) lifts with a single-stranded PCR product labeled by asymmetric PCR (0.5 μM antisense primer, 5 nM sense primer). Pure phage plaques were picked, eluted, and pBluescript plasmids containing cDNA inserts were rescued in SOLR cells (Stratagene). Plasmid DNA was purified by alkaline lysis mini-preps (Sambrook et al., 1989) or by Wizard mini- or midi-preps (Promega). 
     5. DNA sequencing and sequence analysis 
     Restriction fragments of pBluescript inserts were subcloned into M13mp18 and M13mp19 and sequenced manually by dideoxy chain termination (Sanger et al., 1977) using Sequenase II (U.S. Biochemicals) and  35  S-dATP. Prior to ligation into vector, specific restriction fragments were purified by agarose gel electrophoresis in TAE (Sambrook et al., 1989) and QIAEX extraction (QIAGEN) of DNA in the excised bands. Sau3AI or Pstl fragments were shotgun-cloned into BamHI- or PSTl-cut vector, respectively. RACE products were cloned in pBluescript and sequenced by double-stranded cycle sequencing using an Applied Biosystems automated sequencer. Both strands of cDNAs spanning the entire length of the p105/45 message were sequenced at least once, and the composite sequence was assembled and analyzed using DNASTAR software. 
     6. 5&#39; RACE 
     cDNA corresponding to the 5&#39; end of the p105/45 message was amplified from gel filtration-purified pig testis RNA (larger than 5 kb) by 5&#39; RACE using the 5&#39; Amplifinder kit (Clontech). Primary 5&#39; RACE products were excised from low melting point agarose/TAE gels and re-amplified using nested antisense primers prior to purification, restriction enzyme digestion, and cloning. 
     7. Northern blots 
     Poly(A) +  RNAs from pig brain, liver, heart, lung, epididymis, kidney, spleen and testis were separated on 1% agarose/formaldehyde gels and blotted overnight to nylon membranes (Sambrook et al., 1989). Blots were hybridized with a 900 bp EcoRI-Xbal fragment (from a partial length cDNA clone) that had been labeled with α 32  P-dCTP by random nonamer priming (Redi-Prime, Amersham). Hybridized blots were washed at high stringency (1×10 min, 2× SSC, 0.1% SDS, 65° C., and then 2×20 min, 0.5× SSC, 0.1% SDS, 65° C.), and exposed at 85° C. to Hyperfilm-MP (Amersham). 
     8. In situ hybridization 
     Paraffin-embedded sections of pig testis (Novagen) were de-waxed and hybridized with digoxigenin-labeled RNA probes, then washed at high stringency (Vassar et al., 1993). Digoxigenin was then detected by incubation with alkaline phosphatase-conjugated antidigoxigenin followed by color development with 5-bromo-4-chloro-3-indoylphosphate and nitro blue tetrazolium (Vassar et al., 1993). Sense and antisense probes corresponding to the 1566 bp BamHI-Sall 3&#39; end fragment of the p105/45 cDNA were synthesized with T3 or T7 polymerases using templates of appropriately linearized pBluescript plasmids containing the 1566 bp insert. 
     B. Results 
     As reported in Example I, p105/45 bound species-specifically and with very high apparent affinity to the porcine zona pellucida; this property was exploited for its purification (FIG. 6). A cumulative yield of approximately 30 μg of p105 and 10-15 μg of p45 was obtained from a total of 800 mg sperm membrane protein and 40 mg zona pellucida protein (4 preparations). Amino acid sequences of eight p105 and five p45 tryptic peptides were determined (Table 2). These peptide sequences were all unique when compared with sequences in the PIR database. 
     
                       TABLE 2______________________________________Sequences of p45 and p105 tryptic peptides. X = not determinable.Underlined residues differ from the amino acid sequence deduced from thelong open reading frame of the p105/45 message.PROTEIN PEPTIDE SEQUENCE     LOCATION______________________________________p45     VTYILAQP             SEQ ID NO: 5   LFVYVP               SEQ ID NO: 6   VYVTLPBSTVTLLK       859 to 872   VTLPMPS              883 to 890   XLGSSYQT             SEQ ID NO: 7p105    GGNLEAKYVR           SEQ ID NO: 8   LGASWK               1349 to 1354   GSYHPVGESWYTDNS      1518 to 1532   EGQPPAFYLR           1624 to 1633   QVYVDIFNTLVTLKQDQVLIXGT                        1634 to 1656   VSLPATTQIR           1658 to 1667   AQEQCQAAFQAPAWANCAT  1777 to 1795   GTFLPVGR             1914 to 1921______________________________________ 
    
     Degenerate oligonucleotide primers were designed using the amino acid sequences of two p105 peptides (EGQPPAFYLR, position 1624 to 1633 of SEQ ID NO:2 and AQEQCQAAFQAPAWANCAT, position 1777 to 1795 of SEQ ID NO:2). The primers were used with template cDNA prepared from pig testis poly(A) +  RNA to amplify a 500 bp product by PCR. The 167 residue amino acid sequence deduced from the DNA sequence of the PCR product contained the sequences of two p105 peptides (QVYVDIFNTLVTLKQDQVLIXGT, position 1634 to 1656 of SEQ ID NO:2 and VSLPATTQIR, position 1658 to 1667 of SEQ ID NO:2) in addition to the two peptides used to design the degenerate primers, thus confirming that the 500 bp PCR product encoded part of p105. A preliminary northern blot of pig testis poly(A) +  RNA hybridized with the  32  P-labeled PCR product indicated that the full length of p105/45 message was at least 7.5 kb long. 
     Numerous cDNA clones were isolated from oligo-dT-primed and random hexamerprimed cDNA libraries (prepared from pig testis poly(A) +  RNA) using the  32  P-labeled PCR product as a probe. Two overlapping cDNA clones encompassing 6.5 kb of the p105/45 message were sequenced, but no candidate translation start site was identified. Although more than 2 million primary recombinant plaques were screened, no cDNA clone extending further 5&#39; than these two cDNAs was isolated. The inventors therefore cloned approximately 1.3 kb more 5&#39; end cDNA by 5&#39; RACE. Analysis of the 7785 base composite sequence obtained revealed a 297 base 5&#39; untranslated region, a satisfactory translation start site (Kozac, 1989), a 7431 base open reading frame, and a 57 base 3&#39; untranslated region containing a polyadenylation signal and a poly(A) tail (FIG. 7). 
     The 2476 residue amino acid sequence deduced from the long open reading frame contained the sequences of the eight p105 and five p45 peptides (Table 2 and FIG. 8), with a few minor discrepancies that probably reflect errors in the peptide sequences. The deduced sequence predicted an N-terminal 2431 residue extracellular region, a single membrane-spanning segment and a C-terminal 37 residue intracellular segment. Dot matrix analysis of the deduced sequence is shown in FIG. 9. A region of highly repetitive sequence between residues 300 and 700 was evident. Closer examination of this sequence revealed that it consisted of 53 imperfect repeats of a seven residue sequence rich in proline and threonine (FIG. 8). Four mutually similar tandem domains of approximately 400 residues each, preceded by a partial fifth such domain, followed the mucin-like domain (FIG. 9). Conservation of cysteine residues at numerous positions within the five domains was readily apparent. Unexpectedly, sequence comparisons (PIR database) revealed that these domains are homologous to the D-domains of von Willebrand factor (vWF). A sequence of vWF D-domains has been conserved in two of the p105/45 D-domains (CGLCG, designated D1 and D2, SEQ ID NO:2, positions 933 to 937 and 1321 to 1325). In addition, the partial D-domain of p105/45 (designed D0) truncated at precisely the same point in the sequence as a truncated D-domain present in the vWF precursor. A restriction map of the composite nucleotide sequence, the predicted domain structure of the protein encoded by the open reading frame and the locations of the p105 and p45 peptide sequences within the deduced amino sequence are shown in FIG. 10. All of the p45 peptide sequences were present in the predicted D1 domain, and the p105 peptide sequences were present in the predicted D2 and D3 domains. 
     A 900 bp p105/45 probe hybridized with a 7.5-8 kb message present in poly(A) +  RNA isolated from pig testis; no hybridization with poly(A) +  RNAs from various other pig tissues was observed (FIG. 11). As similar amounts of poly(A) +  RNAs were used, the apparent absence of expression in tissues other than testis cannot be a function of generally low synthesis of mRNAs in some tissues. The testicular cell types that express p105/45 message were identified by in situ hybridization (FIG. 12). No specific hybridization with interstitial (Leydig) cells was observed. Hybridization was restricted to the germinal epithelium of the seminiferous tubules; only a fraction of the tubules in a given section hybridized strongly with the p105/45 probe. Within strongly hybridizing tubules, expression was high only in spermatids. 
     C. Discussion 
     The inventors have purified the p105 and p45 subunits of a sperm membrane protein that bound species specifically to the porcine ZP, and cloned cDNAs encompassing the message that encodes it. The presence of eight p105 and five p45 peptide sequences in the deduced sequence confirms that the 7431 base open reading frame encodes the protein that bound species specifically to the ZP. Thus p45 and p105 are products of the same gene, and were produced by proteolysis of a larger precursor. The predicted molecular weight (270 kDa) of the protein encoded by the open reading frame is much larger than the sum (Mr 150,000) of the apparent sizes of the P105/45 subunits, indicating that a substantial amount of the mass of the p105/45 precursor had been removed proteolytically from the protein that bound to the ZP. This apparent processing may be due to physiological effects or may be a consequence of the purification procedure or a combination of these two possibilities. 
     Highly repetitive amino acid sequences rich in proline and threonine residues are characteristic of mucins (Hilkens et al., 1992). Thus the highly repetitive region between residues 300 and 700 of the p105/45 deduced sequence is a mucin-like domain. Mucins are heavily O-glycosylated on numerous serine and threonine residues, and their polypeptide chains have extended structures owing to the presence of many proline residues (Hilkens et al., 1992). These structural properties reflect the functions of mucins in regulating cellular interactions; the large, carbohydrate rich domains extend beyond most other cell surface glycoproteins and thereby inhibit some types of cell adhesion or promote cell adhesion by providing the carbohydrate ligands for selectins on the surfaces of other cells (Hilkens et al., 1992). It is possible that the mucin-like domain of p105/45 functions similarly during sperm transport through the female reproductive tract or during sperm-ovum interactions. 
     The inventors have observed high Mr sperm proteins (SDS-PAGE, non-reducing conditions) bound to the porcine ZP that appear to be covalent oligomers of p105/45 (Example I). The vicinal cysteines of the aforementioned vWF pentameric sequence may mediate covalent oligomerization of vWF monomers by disulfide interchange (Mayadas &amp; Wagner, 1992). Hence, conservation of this motif in the D1 and D2 domains of P105/45 may reflect an important function in covalent oligomerization of p105/45. Such oligomerization could be important in sperm adhesion to the ZP because of the increased binding avidity produced by multivalent interactions. Oligomerization could also promote membrane protein aggregation that may be important for induction of the sperm acrosome reaction (Leyton &amp; Saling, 1989; Macek et al., 1991). 
     Other functions of vWF D-domains include heparin and Factor VIII binding (Meyer &amp; Girma, 1993). These vWF D-domain properties have potentially important implications for p105/45 function in sperm physiology. Heparin and/or other glycosaminoglycans promote capacitation and acrosome reaction of bovine spermatozoa in vitro (Parrish et al., 1989), but the target(s) on spermatozoa for these agents is unknown. In addition, a possible requirement for sperm surface proteolytic activity in sperm adhesion to the ZP has been reported (Saling, 1981). By analogy to vWF, it is possible that binding of heparin and/or a protease to the D-domains of p105/45 affect sperm physiology. For example, action of a specific processing protease that binds to a p105/45 D-domain may be necessary for activation of p105/45 during capacitation. Such specific hypotheses can now be tested with recombinant p105/45 expressed in heterologous cells. 
     Northern blots of poly(A) +  RNAs from several pig tissues detected expression of p105/45 message only in testis, and within the testis, expression was restricted to the germinal epithelium of the seminiferous tubules, specifically spermatids. Only a fraction of the tubules in a given tissue section appeared to be expressing p105/45 message, consistent with the asynchrony of spermiogenesis among tubules. Spermatid-specific expression of the p105/45 message is consistent with participation of this protein in sperm adhesion to the ZP, since this is a sperm-specific function. 
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     All of the compositions and methods disclosed and claimed herein can be made and executed without undue experimentation in light of the present disclosure. While the compositions and methods of this invention have been described in terms of preferred embodiments, it will be apparent to those of skill in the art that variations may be applied to the composition, methods and in the steps or in the sequence of steps of the method described herein without departing from the concept, spirit and scope of the invention. More specifically, it will be apparent that certain agents which are both chemically and physiologically related may be substituted for the agents described herein while the same or similar results would be achieved. All such similar substitutes and modifications apparent to those skilled in the art are deemed to be within the spirit, scope and concept of the invention as defined by the appended claims. 
     
         __________________________________________________________________________SEQUENCE LISTING(1) GENERAL INFORMATION:(iii) NUMBER OF SEQUENCES: 8(2) INFORMATION FOR SEQ ID NO:1:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 7785 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(ii) MOLECULE TYPE: DNA(xi) SEQUENCE DESCRIPTION: SEQ ID NO:1:GGTGGCGGGTGTAAGGAGGTGCCTGCCCTTCAGCTTCAGGCCCGCACTCTCAGCGATTTG60TGTGAATCATCTCTGTACAGTGGGTCGAGAAAAGGAAGAGGATGTGGCTCTAGGGGACTT120CAAAAGCCACCATTTGAAGGACAAGATTCTGGCCTGTGCTTCTGAGAGGATGCCGCGATT180CCTAGGCAGCGCCCCCACCCTCACCCAGACCTGCCAAACGCTTCTGGAAGGATCCGAGGC240CTCAGCTCGTCGCGTGGCGGGTGTAGGCCCACCTCGGTGCTGGCTGATCCTAGGGAGATG300TTAGGGCTCCCTGCCCTCGCAGGCCCTATGGCTATGCCACACCCACCTCTAATTCCCTCC360ACTCCCACTTTATTGGCCTTTTCCTTCCCAGGTGGCTTCTACATGCTCCTGGACCCCAAG420AATGCAAAACCAAGGCAAAGATCTGCCCTCCTGAGCCCTCTGATCCAGTCCTCCGGCTGC480CTGAGCCTGTCCTTTCAGTACACCCAACGTGGCCAGGCGTCTGGTGCAACCCTCATGGTC540TATGCTTCTGTTTTGGGCAGCATCCGGAAACACACTCTTTTCTCAGGACAACCCGGACCC600AGTTGGCAGCCTGTTTCTGTCAATTACACAAGCCAAGGACAGATTCAGTTCACCCTGGTG660GGTGTGTTTGGAAAGATCCCAGAGCCAGCTGTGGCAGTAGATGCAATCAGCATTGCTCCC720TGTGAAGAGAGCTTTCCTCAGTGTGACTTTGAAGATAATGCCCATCCCTTCTGTGACTGG780GTACAGGCATCACAGGATGGTGGATACTGGAGGCAGGGAAATAAAAATACATTCATCCAG840CCTGCAGGCCCCTTTGGAATCTCCCTTAATGGAGAAGGTCACTACATCTTCCTTGAGACT900GACAAGTTCTCCCAGGCAGGCCAGTCTTTCAGACTGGTGAGCCGGCCCTTCTGTGCCCCG960GCTGTGATCTGCGTGACGTTTACCTACCACATGTATGGCCTGGGACAGGGCACAAAGCTC1020AGGCTGCTGCTGGGGAGTCCTGCGGGTAGTCCCCCAAGTTCTCTCTGGGAACGTGTTGGG1080CCTCAGAGCCCTGAATGGCTGAACACCTCCGTCACCATCCCTTCAGGACATCAACAGCCC1140ATGCAGCTGATATTTGAAGCCGTCAGGGGCACCAACACCGCCTTTGTTGTTGCTCTGGGT1200TTCGTCTTGATCAATCATGGGACCTGTCGAGGACCTTCTGAAACCTCTGTCTCCACAGAA1260AAACCCGTGGCCCCTACAGAAAAACCAACTGTCCCCAGTGAAATATACACTATCCCCACA1320GAAAAGCCCATGGTCCACATGGAGAAGCCCATTGTACACACTGAAAAACCTACAGTTCCC1380ACAGAAAAACCTACAATCCCAACAGAAAAATCTACAGTGCCCACCAAAAAACCCACTGTC1440TTTAAAGAACCCACCCTTCCACCTGAAGGGCCCACCGTCCCTGCTGAACGGCCTACCACC1500CCGCCTGAAGGGCCTGCTGTCCCTCCTAAAGGGCCCACTGTCCTCACTGAATGGCCCACA1560AGCCACACAGAAAAATCTACTGTCCACACAGAGAAACCCATTCTCCCCACAGGAAAATCC1620ACCATCCCCACAGAAAAACCCATGGTCCCCACCAAAAGGACCACCACTCCCACTGAAAGG1680ACCACTATCCCCGCAGAAAAGCCAACTGTCCCCATAGAAAAACCAATGGTCCCCACCGAA1740AGGACCACCATTCCCACTGAAAGAACCACTATCCCCACAGAAAAACCTACTGTTCCCACA1800GAAAAACTCACTGTCCCCACAGAAAAGCCAATTGTCCCCACAGAAAAGCCGATTGTCCCC1860ACAGAAAAACACACCATCCCCACAGAAAAACTGACAGTCCTCACTGAGAGGACCACTACT1920CCCACTGAAAGAACCACTATCCCCACAGAAAAACCTACTGTCCCCACAGAAAAACCCTCT1980GTCCCCACAGAAAAGCCAACTGTCCCCACAGAAGAACCCACCATCCCCACAGAAAAGCTT2040ACCGTCCCCACTGAGAGGACCACCACTCCCACCAAAAGGACCACCACTCCCACCATAAGG2100ACCACCACCCCCACCATAAGGACCACCACCCCCACCGAAAGGACCACCACCCCCACCATA2160AGGACCACCACTCCCACTGAAAGGACCACCATCCCCACGAAAAAGACCACTGTTCCCACA2220GAAAAAACCATTATCCCCACTGAAAGGACCATAGCTCCTACAACACCCCAGCCCAGCCCA2280ACTCTTGTACCCACTCAGCCAGCAGCCGTCGTGATGCCAAGTACTTCCGCGACCACTGTG2340ACCCCGAGAACTACTATAGCGAGCTGCCCCCCAAATGCCCACTTTGAACGCTGCGCCTGC2400CCAGTGTCCTGCCAGAGCCCCACACCCAACTGTGAGCTCTTCTGCAAGCCCGGCTGTGTC2460TGTGATCCTGGCTTTTTATTCAGTGGCTCCCACTGCGTCAACGCCTCTTCCTGTGATTGC2520TTCTACAACGACAATTACTATAAGCTGGGGACAGATTGGTTCAGCCCCAACTGCACAGAA2580CATTGCCACTGCCGGCCCAGCAGTCGGATGGAGTGCCAGACCTTCAAGTGCGGGACACAC2640ACAGTGTGCCAGCTGAAGAATGGCCAGTACGGCTGCCACCCCTATGGCAGTGCCACCTGC2700TCTGTCTACGGAGACCCTCACTACCTCACCTTCGACGGGAGGCGCTTTAACTTCATGGGC2760AAGTGCACCTACATCTTGGCCCAACCCTGTGGCAACTTGACAGAGCACTTCTTCAGGGTG2820CTGGTGAAGAAGGAGGAGCGAGGACAGGAGGGCGTGTCCTGCCTAAGCAAGGTCTACGTG2880ACTCTGCCTGAAAGCACCGTCACTCTGCTCAAGGGCAGACACACGCTGGTCGGAGGTCAG2940CGAGTCACCCTCCCAGCCATACCTTCTAGAGGTGTCTTCCTGGCTCCCAGTGGGCGATTT3000GTGGAGCTGCAGACGGCGTTCGGTCTGCGGGTGAGATGGGATGGTGACCAGCAGCTGTTT3060GTGAGTGTGCCCAGCACCTTCTCTGGCAAACTCTGTGGTCTCTGTGGCGACTATGACGGT3120GACAGCAGCAACGACAACCAGAAGCCGGATGGCAGTCCAGCAAAAGATGAGAAGGAGCTG3180GGTAGCAGCTGGCAGACCTCGGAGGATGCGGACCAGCAGTGCGAGGAGAACCAGGTGTCT3240CCCCCGTCTTGCAACACGGCCTTGCAGAATACTATGTCGGGGCCAGAGTTCTGTGGACAG3300CTGGTGGCCCCTCATGGAGTCTTCGAGGCGTGCCTGCCTCACCTCAGGGCCTCTTCCTTC3360TTCAAGAGCTGCACGTTTGACATGTGTAACTTCCAGGGGCTGCAGCATATGCTGTGTGCT3420CACATGTCGGCCTTGACTGAGAACTGCCAGGATGCTGGCTACACGGTGAAGCCCTGGAGA3480GGACCCCAGTTCTGCCCGCTGGCCTGCCCCCGCAACAGTAGGTACACGCTGTGTGCCAGG3540CTGTGCCCCGACACCTGCCATTCTGAGTTCTCGGGCAGGGCCTGCAAGGACCGCTGCGTG3600GAGGGCTGCGAGTGCGACCCAGGCTTCGTCCTCAGTGGCCTCCAGTGCGTCTCCCGGTCC3660GAGTGTGGCTGCCTCGACTCCACAGCGGGTTATGTCAAGGTAGGGGAGCGGTGGTTCAAG3720CCAGGCTGCAGACAGCTCTGTATCTGTGAGGGTAACAACAGAACTCGCTGTGTGCTCTGG3780AGGTGCCAGGCCCAGGAGTTCTGCGGTCAGCAGGATGGCATCTACGGCTGCCATGCTCAA3840GGGTCTGCCACCTGCACTGTCTCGGGGGACCCCCACTACCTGACGTTCGACGGAGCCCTG3900CACCACTTCACGGGCACCTGCACCTACACCCTGACCAAACCTTGCTGGCTGAGGTCCCTA3960GAGAATTCTTTCCTTGTGAGTGCCACCAATGAGTTCCGCGGTGGAAATTTAGAGGCCTCC4020TACGTCAGAGCCGTCCAGGTGCAGGTCTTCAACCTCAGAATCTCGCTGATCAAAGGCCGC4080AAAGTCACGCTGGATGGCCGCAGGGTGGCCTTGCCCCTGTGGCCCGCACAAGGCCGGGTG4140AGCATCACGTCCAGTGGCTCCTTCATCCTCCTCTACACGGACTTTGGGCTTCAAGTTCGC4200TATGATGGCGACCACCTGGTGGAAGTGACCGTGCCCTCCTCCTACGCTGGCCGGCTCTGT4260GGGCTCTGCGGGAACTACAACAACAACAGCCTGGACGACATTCTGCAGCCTGATAAAAGG4320CCTGCAAGCAGCTCTGTGCGCCTGGGGGCCTCCTGGAAGATAAATGAGTTATCTGAACCT4380GGCTGCTTTGCTGAAGGTGGCAAGCCCCCCAGGTGCCTGGGGAAGGAAGTGGCAGACGCC4440TGGCGTAAGAACTGTGATGTCTTAATGAACCCTCAGGGACCCTTCTCTCAATGCCACAGG4500GTGGTGGCCCCTCAATCCAGCTTCTCCAGCTGTTTGTATGGCCAGTGTGCGACCAAGGGG4560GACACCCTGACCCTGTGCCGCTCCCTGCAGGCCTACGCGTCCCTGTGCGCGCGCGCTGGC4620CAGGCCCTCACCTGGCGGAATGGCACCTTCTGCCCTCTGAAGTGCCCGTCAGGCAGCAGC4680TATAGCACCTGTGCCAACCCCTGCCCAGCCACCTGCCTCAGCCTGAACAATCCATCATAC4740TGCCCATCCACGCTGCCCTGTGCCGAGGGCTGCGAGTGCCAGAAAGGCCACATCTTGAGC4800GGAACCTCCTGCGTGCCCCTCAGCCAGTGTGGCTGCACCACCCAGAGGGGCTCCTACCAC4860CCGGTTGGGGAGAGCTGGTACACGGACAACAGCTGCTCCAGGCTCTGCACCTGCTCTGCC4920CACAACAACATCTCCTGCCGCCAGGCCTCCTGCAAGCCCAGCCAGATGTGCTGGCCCCAG4980GATGGGCTGATACGGTGCCGGGTGGCAGGGATGGGAGTGTGCCGCATCCCTGACACATCC5040CACTACGTGAGCTTCGATGGCAGCTACCATGCTGTCAGGGGCAACTGCACTTACGTCCTG5100GTGAAAATATGCCACTCCACCATGGACCTGCCTTTCTTCAAGATCAGTGGCGAGAATGGG5160AAGCGGGAAGGCCAACCCCCGGCTTTCTACCTCCGCCAGGTCTACGTGGATATCTTTAAT5220ACCCTGGTCACCCTGAAACAGGACCAAGTGCTGATCAATGGCACACGGGTCAGTCTGCCT5280GCAACCACGCAGATCCGTGGGGTCAGAGTCATTTCCAGGGACGGCTACACCGTGCTCACC5340ATCAACATCGGGGTGCAGGTCAAGTTTGACGGCAGAGGTTTCCTTGAGGTTGAAATCCCC5400AAAGCCTATTACGGAAGGACCTGCGGCGTGTGCGGGAACTTCAACGACGAGGAAGAAGAC5460GAGCTCATGATGCCCAGTGATGCACTAGCTCTGGATGACGTCATGTATGTGGACAGCTGG5520CGAGATAAGGAGATCGACCCAAATTGCCAGGAAGATGACAGGAAGACCGAAGCAGAATCG5580CAAGAGCAGCCAAGTGCAAACTGCAGGCCAGCTGACCTGGAGCGAGCCCAGGAGCAGTGC5640CAGGCGGCCTTTCAGGCCCCGGCCTGGGCAAACTGTGCCACCCGCGTGGTGCTCAGTCCC5700TACGTGCGCAGCTGTACTCACAAGCTCTGTGAGTTTGGAGGCCTAAACCGTGCCTTTTGC5760GAGTCTCTGCAAGCCTTCGGGGCCGCCTGCCAGGCCCAGGGGATCAAGCCCCCAGTCTGG5820AGAAACAGCAGCTTCTGCCCTCTGGACTGCTCCGCCCACAGCGTCTACACCTCCTGCGTC5880CCCTCCTGCCTCCCTTCCTGCCAGGACCCCGAAGGCCAGTGCACAGGCGCCGGAGCTCCC5940TCCACCTGTGAGGAGGGCTGCATTTGTGAGCCCGGCTACGTGCTCAGCGAGCAGCAGTGT6000GTGGCCAGGAGTCAGTGCGGCTGCAGGGACGCCAGGGGCACTTTCCTTCCCGTGGGTAGG6060TTCCGGCTCTCCAGCGGCTGCTCCCAGATGTGTGTCTGCACAGCGGGAGCCATTGAGTGC6120AGGCCCTTCACCTGCCCCTCCGGCTCCCAGTGCGAGCCCAACGAAGACGGCAAGGACTTC6180TGCCAACCCAACAGCTCCAATCTATGCTCAGTTTTCGGGGATCCCCATTACCGCACATTT6240GATGGCCTCAGCTACCGCTTCCAGGGCCGCATGACCTACACCCTGGTCAAGACCTTGGAC6300GTGCTCCCCGATGGGGTGGAGCCCCTGGTGGTGGAGGGACGCAACAAGGTGTATCCATCC6360TTAACCCCGGTCTTCCTGCAAGAGATCATCGTCATGGTCTACGGCTACACAGTCCAGCTC6420CAGGCCGAACTGGAGCTTGTGGTCAACGGTCAGAAGGTGTCCATCCCCTACAAGCCCAAC6480GAGTACCTGCAGGTCACTCTGCGAGGCCGTCGCCTGTATCTGGTCACAGACTTTGAGCTG6540GTCGTCAGCTTCAATGGAAGAAACAATGCAGTGATCGCCATGCCCAGCACCTACCTGGGG6600CTCGTGCGAGGCCTGTGCGGCAACTACGACAAGAACAAGAGGAATGACTTCATGCTGCCT6660AATGGCTCCTTCACCCAGAACCTCCTTGTCTTTGGCAACAGCTGGGAGGTAAAGGCCAAG6720GAAGGCCACCCCCGCTTCTCAAGGGCCATTCGAGAGGAGGAAGAGAAAAACGAAGAGTCA6780GGCTTTCAGAATGTGTCAGAATGCAGCCCAGAGCAGCTGGAGCTCGTCAACCACACCCAG6840GCGTGTGGGGTGCTGGTGGACCCTCAGGGCCCCTTTGCTGCCTGTCACCAGATTGTGGCC6900CCAGGGCCCTTCCAGGAGCACTGTGTGTTTGATCTCTGTGCTGCCCCGGGCCCCAAAGAG6960CAGGAGGAGTTGCGTTGCCAGGTCCTCAGCGGGTACGCCATCATCTGCCAGGAGTCGGGG7020CCCACCCTGGCCGGCTGGCGGGACCACACCCACTGCGCCTTGCCATGTCCGGCCAACACG7080GTCTATCAGAGCTGTATGACACCCTGCCCAGCCTCCTGTGCCACCCTGGCAGTCCCCCGG7140GCCTGCGACGGCCCGTGTGTGGAGGGCTGTGCCAGCCTCCCCGGTTACATCTACAGTGGT7200GCCCAGAGCCTTCCCATGGCCCACTGTGGCTGCACCAACAACGGCGTCTACTACCAGCAG7260GGTGACAGCTTCGTGACCGAGAACTGCTCTCAGCGCTGCACCTGTGCCAGCTCGGGGGTC7320CTGCTGTGTGAGCCCCTCAGCTGCCGCCCTGGGGAGATCTGCACCCTGGGGAACCTCACT7380CGTGGCTGCTTCCGAGACAGCCCATGTCTACAGAACCCCTGTCAGAATGATGGGCGGTGT7440CGGGAGCAGGGAACCCACTTCACCTGTGAGTGTGAACTTGGTTACGGGGGAGACCTCTGC7500ACGGAGCCTCGGGGTGTACCATCCCCCAAAAAGCCAGAGGCGTCCAACCGCGTGGCCATC7560CTCTTGGGGATGCTGATGCCCACAGTGCTCCTGGTGCCGGCGGTGACCAGAGTTTCCAGG7620AAGAGGAGGAGGAGGAGGAGGCCCTCTAGGGAGAGAACGCAGAGCCAGAACAGAGGCAAG7680CGGGCCGGCACAGATTGTGCTCCAGAGCAGGCCTACAAAGTGGCTTAGTTTTGAGGTGTT7740CACACAAAGGGAGAGATAAAATTATTTATTTTTGAAAAAAAAAAA7785(2) INFORMATION FOR SEQ ID NO:2:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 2476 amino acids(B) TYPE: amino acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(xi) SEQUENCE DESCRIPTION: SEQ ID NO:2:MetLeuGlyLeuProAlaLeuAlaGlyProMetAlaMetProHisPro151015ProLeuIleProSerThrProThrLeuLeuAlaPheSerPheProGly202530GlyPheTyrMetLeuLeuAspProLysAsnAlaLysProArgGlnArg354045SerAlaLeuLeuSerProLeuIleGlnSerSerGlyCysLeuSerLeu505560SerPheGlnTyrThrGlnArgGlyGlnAlaSerGlyAlaThrLeuMet65707580ValTyrAlaSerValLeuGlySerIleArgLysHisThrLeuPheSer859095GlyGlnProGlyProSerTrpGlnProValSerValAsnTyrThrSer100105110GlnGlyGlnIleGlnPheThrLeuValGlyValPheGlyLysIlePro115120125GluProAlaValAlaValAspAlaIleSerIleAlaProCysGluGlu130135140SerPheProGlnCysAspPheGluAspAsnAlaHisProPheCysAsp145150155160TrpValGlnAlaSerGlnAspGlyGlyTyrTrpArgGlnGlyAsnLys165170175AsnThrPheIleGlnProAlaGlyProPheGlyIleSerLeuAsnGly180185190GluGlyHisTyrIlePheLeuGluThrAspLysPheSerGlnAlaGly195200205GlnSerPheArgLeuValSerArgProPheCysAlaProAlaValIle210215220CysValThrPheThrTyrHisMetTyrGlyLeuGlyGlnGlyThrLys225230235240LeuArgLeuLeuLeuGlySerProAlaGlySerProProSerSerLeu245250255TrpGluArgValGlyProGlnSerProGluTrpLeuAsnThrSerVal260265270ThrIleProSerGlyHisGlnGlnProMetGlnLeuIlePheGluAla275280285ValArgGlyThrAsnThrAlaPheValValAlaLeuGlyPheValLeu290295300IleAsnHisGlyThrCysArgGlyProSerGluThrSerValSerThr305310315320GluLysProValAlaProThrGluLysProThrValProSerGluIle325330335TyrThrIleProThrGluLysProMetValHisMetGluLysProIle340345350ValHisThrGluLysProThrValProThrGluLysProThrIlePro355360365ThrGluLysSerThrValProThrLysLysProThrValPheLysGlu370375380ProThrLeuProProGluGlyProThrValProAlaGluArgProThr385390395400ThrProProGluGlyProAlaValProProLysGlyProThrValLeu405410415ThrGluTrpProThrSerHisThrGluLysSerThrValHisThrGlu420425430LysProIleLeuProThrGlyLysSerThrIleProThrGluLysPro435440445MetValProThrLysArgThrThrThrProThrGluArgThrThrIle450455460ProAlaGluLysProThrValProIleGluLysProMetValProThr465470475480GluArgThrThrIleProThrGluArgThrThrIleProThrGluLys485490495ProThrValProThrGluLysLeuThrValProThrGluLysProIle500505510ValProThrGluLysProIleValProThrGluLysHisThrIlePro515520525ThrGluLysLeuThrValLeuThrGluArgThrThrThrProThrGlu530535540ArgThrThrIleProThrGluLysProThrValProThrGluLysPro545550555560SerValProThrGluLysProThrValProThrGluGluProThrIle565570575ProThrGluLysLeuThrValProThrGluArgThrThrThrProThr580585590LysArgThrThrThrProThrIleArgThrThrThrProThrIleArg595600605ThrThrThrProThrGluArgThrThrThrProThrIleArgThrThr610615620ThrProThrGluArgThrThrIleProThrLysLysThrThrValPro625630635640ThrGluLysThrIleIleProThrGluArgThrIleAlaProThrThr645650655ProGlnProSerProThrLeuValProThrGlnProAlaAlaValVal660665670MetProSerThrSerAlaThrThrValThrProArgThrThrIleAla675680685SerCysProProAsnAlaHisPheGluArgCysAlaCysProValSer690695700CysGlnSerProThrProAsnCysGluLeuPheCysLysProGlyCys705710715720ValCysAspProGlyPheLeuPheSerGlySerHisCysValAsnAla725730735SerSerCysAspCysPheTyrAsnAspAsnTyrTyrLysLeuGlyThr740745750AspTrpPheSerProAsnCysThrGluHisCysHisCysArgProSer755760765SerArgMetGluCysGlnThrPheLysCysGlyThrHisThrValCys770775780GlnLeuLysAsnGlyGlnTyrGlyCysHisProTyrGlySerAlaThr785790795800CysSerValTyrGlyAspProHisTyrLeuThrPheAspGlyArgArg805810815PheAsnPheMetGlyLysCysThrTyrIleLeuAlaGlnProCysGly820825830AsnLeuThrGluHisPhePheArgValLeuValLysLysGluGluArg835840845GlyGlnGluGlyValSerCysLeuSerLysValTyrValThrLeuPro850855860GluSerThrValThrLeuLeuLysGlyArgHisThrLeuValGlyGly865870875880GlnArgValThrLeuProAlaIleProSerArgGlyValPheLeuAla885890895ProSerGlyArgPheValGluLeuGlnThrAlaPheGlyLeuArgVal900905910ArgTrpAspGlyAspGlnGlnLeuPheValSerValProSerThrPhe915920925SerGlyLysLeuCysGlyLeuCysGlyAspTyrAspGlyAspSerSer930935940AsnAspAsnGlnLysProAspGlySerProAlaLysAspGluLysGlu945950955960LeuGlySerSerTrpGlnThrSerGluAspAlaAspGlnGlnCysGlu965970975GluAsnGlnValSerProProSerCysAsnThrAlaLeuGlnAsnThr980985990MetSerGlyProGluPheCysGlyGlnLeuValAlaProHisGlyVal99510001005PheGluAlaCysLeuProHisLeuArgAlaSerSerPhePheLysSer101010151020CysThrPheAspMetCysAsnPheGlnGlyLeuGlnHisMetLeuCys1025103010351040AlaHisMetSerAlaLeuThrGluAsnCysGlnAspAlaGlyTyrThr104510501055ValLysProTrpArgGlyProGlnPheCysProLeuAlaCysProArg106010651070AsnSerArgTyrThrLeuCysAlaArgLeuCysProAspThrCysHis107510801085SerGluPheSerGlyArgAlaCysLysAspArgCysValGluGlyCys109010951100GluCysAspProGlyPheValLeuSerGlyLeuGlnCysValSerArg1105111011151120SerGluCysGlyCysLeuAspSerThrAlaGlyTyrValLysValGly112511301135GluArgTrpPheLysProGlyCysArgGlnLeuCysIleCysGluGly114011451150AsnAsnArgThrArgCysValLeuTrpArgCysGlnAlaGlnGluPhe115511601165CysGlyGlnGlnAspGlyIleTyrGlyCysHisAlaGlnGlySerAla117011751180ThrCysThrValSerGlyAspProHisTyrLeuThrPheAspGlyAla1185119011951200LeuHisHisPheThrGlyThrCysThrTyrThrLeuThrLysProCys120512101215TrpLeuArgSerLeuGluAsnSerPheLeuValSerAlaThrAsnGlu122012251230PheArgGlyGlyAsnLeuGluAlaSerTyrValArgAlaValGlnVal123512401245GlnValPheAsnLeuArgIleSerLeuIleLysGlyArgLysValThr125012551260LeuAspGlyArgArgValAlaLeuProLeuTrpProAlaGlnGlyArg1265127012751280ValSerIleThrSerSerGlySerPheIleLeuLeuTyrThrAspPhe128512901295GlyLeuGlnValArgTyrAspGlyAspHisLeuValGluValThrVal130013051310ProSerSerTyrAlaGlyArgLeuCysGlyLeuCysGlyAsnTyrAsn131513201325AsnAsnSerLeuAspAspIleLeuGlnProAspLysArgProAlaSer133013351340SerSerValArgLeuGlyAlaSerTrpLysIleAsnGluLeuSerGlu1345135013551360ProGlyCysPheAlaGluGlyGlyLysProProArgCysLeuGlyLys136513701375GluValAlaAspAlaTrpArgLysAsnCysAspValLeuMetAsnPro138013851390GlnGlyProPheSerGlnCysHisArgValValAlaProGlnSerSer139514001405PheSerSerCysLeuTyrGlyGlnCysAlaThrLysGlyAspThrLeu141014151420ThrLeuCysArgSerLeuGlnAlaTyrAlaSerLeuCysAlaArgAla1425143014351440GlyGlnAlaLeuThrTrpArgAsnGlyThrPheCysProLeuLysCys144514501455ProSerGlySerSerTyrSerThrCysAlaAsnProCysProAlaThr146014651470CysLeuSerLeuAsnAsnProSerTyrCysProSerThrLeuProCys147514801485AlaGluGlyCysGluCysGlnLysGlyHisIleLeuSerGlyThrSer149014951500CysValProLeuSerGlnCysGlyCysThrThrGlnArgGlySerTyr1505151015151520HisProValGlyGluSerTrpTyrThrAspAsnSerCysSerArgLeu152515301535CysThrCysSerAlaHisAsnAsnIleSerCysArgGlnAlaSerCys154015451550LysProSerGlnMetCysTrpProGlnAspGlyLeuIleArgCysArg155515601565ValAlaGlyMetGlyValCysArgIleProAspThrSerHisTyrVal157015751580SerPheAspGlySerTyrHisAlaValArgGlyAsnCysThrTyrVal1585159015951600LeuValLysIleCysHisSerThrMetAspLeuProPhePheLysIle160516101615SerGlyGluAsnGlyLysArgGluGlyGlnProProAlaPheTyrLeu162016251630ArgGlnValTyrValAspIlePheAsnThrLeuValThrLeuLysGln163516401645AspGlnValLeuIleAsnGlyThrArgValSerLeuProAlaThrThr165016551660GlnIleArgGlyValArgValIleSerArgAspGlyTyrThrValLeu1665167016751680ThrIleAsnIleGlyValGlnValLysPheAspGlyArgGlyPheLeu168516901695GluValGluIleProLysAlaTyrTyrGlyArgThrCysGlyValCys170017051710GlyAsnPheAsnAspGluGluGluAspGluLeuMetMetProSerAsp171517201725AlaLeuAlaLeuAspAspValMetTyrValAspSerTrpArgAspLys173017351740GluIleAspProAsnCysGlnGluAspAspArgLysThrGluAlaGlu1745175017551760SerGlnGluGlnProSerAlaAsnCysArgProAlaAspLeuGluArg176517701775AlaGlnGluGlnCysGlnAlaAlaPheGlnAlaProAlaTrpAlaAsn178017851790CysAlaThrArgValValLeuSerProTyrValArgSerCysThrHis179518001805LysLeuCysGluPheGlyGlyLeuAsnArgAlaPheCysGluSerLeu181018151820GlnAlaPheGlyAlaAlaCysGlnAlaGlnGlyIleLysProProVal1825183018351840TrpArgAsnSerSerPheCysProLeuAspCysSerAlaHisSerVal184518501855TyrThrSerCysValProSerCysLeuProSerCysGlnAspProGlu186018651870GlyGlnCysThrGlyAlaGlyAlaProSerThrCysGluGluGlyCys187518801885IleCysGluProGlyTyrValLeuSerGluGlnGlnCysValAlaArg189018951900SerGlnCysGlyCysArgAspAlaArgGlyThrPheLeuProValGly1905191019151920ArgPheArgLeuSerSerGlyCysSerGlnMetCysValCysThrAla192519301935GlyAlaIleGluCysArgProPheThrCysProSerGlySerGlnCys194019451950GluProAsnGluAspGlyLysAspPheCysGlnProAsnSerSerAsn195519601965LeuCysSerValPheGlyAspProHisTyrArgThrPheAspGlyLeu197019751980SerTyrArgPheGlnGlyArgMetThrTyrThrLeuValLysThrLeu1985199019952000AspValLeuProAspGlyValGluProLeuValValGluGlyArgAsn200520102015LysValTyrProSerLeuThrProValPheLeuGlnGluIleIleVal202020252030MetValTyrGlyTyrThrValGlnLeuGlnAlaGluLeuGluLeuVal203520402045ValAsnGlyGlnLysValSerIleProTyrLysProAsnGluTyrLeu205020552060GlnValThrLeuArgGlyArgArgLeuTyrLeuValThrAspPheGlu2065207020752080LeuValValSerPheAsnGlyArgAsnAsnAlaValIleAlaMetPro208520902095SerThrTyrLeuGlyLeuValArgGlyLeuCysGlyAsnTyrAspLys210021052110AsnLysArgAsnAspPheMetLeuProAsnGlySerPheThrGlnAsn211521202125LeuLeuValPheGlyAsnSerTrpGluValLysAlaLysGluGlyHis213021352140ProArgPheSerArgAlaIleArgGluGluGluGluLysAsnGluGlu2145215021552160SerGlyPheGlnAsnValSerGluCysSerProGluGlnLeuGluLeu216521702175ValAsnHisThrGlnAlaCysGlyValLeuValAspProGlnGlyPro218021852190PheAlaAlaCysHisGlnIleValAlaProGlyProPheGlnGluHis219522002205CysValPheAspLeuCysAlaAlaProGlyProLysGluGlnGluGlu221022152220LeuArgCysGlnValLeuSerGlyTyrAlaIleIleCysGlnGluSer2225223022352240GlyProThrLeuAlaGlyTrpArgAspHisThrHisCysAlaLeuPro224522502255CysProAlaAsnThrValTyrGlnSerCysMetThrProCysProAla226022652270SerCysAlaThrLeuAlaValProArgAlaCysAspGlyProCysVal227522802285GluGlyCysAlaSerLeuProGlyTyrIleTyrSerGlyAlaGlnSer229022952300LeuProMetAlaHisCysGlyCysThrAsnAsnGlyValTyrTyrGln2305231023152320GlnGlyAspSerPheValThrGluAsnCysSerGlnArgCysThrCys232523302335AlaSerSerGlyValLeuLeuCysGluProLeuSerCysArgProGly234023452350GluIleCysThrLeuGlyAsnLeuThrArgGlyCysPheArgAspSer235523602365ProCysLeuGlnAsnProCysGlnAsnAspGlyArgCysArgGluGln237023752380GlyThrHisPheThrCysGluCysGluLeuGlyTyrGlyGlyAspLeu2385239023952400CysThrGluProArgGlyValProSerProLysLysProGluAlaSer240524102415AsnArgValAlaIleLeuLeuGlyMetLeuMetProThrValLeuLeu242024252430ValProAlaValThrArgValSerArgLysArgArgArgArgArgArg243524402445ProSerArgGluArgThrGlnSerGlnAsnArgGlyLysArgAlaGly245024552460ThrAspCysAlaProGluGlnAlaTyrLysValAla246524702475(2) INFORMATION FOR SEQ ID NO:3:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 38 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(ii) MOLECULE TYPE: DNA(ix) FEATURE:(A) NAME/KEY: modified.sub.-- base(B) LOCATION: 18..30(D) OTHER INFORMATION: /mod.sub.-- base=OTHER/note= &#34;N = Inosine&#34;(xi) SEQUENCE DESCRIPTION: SEQ ID NO:3:GAATTCGAATTCGARGGNCARCCNCCNGCNTTYTAYYT38(2) INFORMATION FOR SEQ ID NO:4:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 38 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(ii) MOLECULE TYPE: DNA(ix) FEATURE:(A) NAME/KEY: modified.sub.-- base(B) LOCATION: 15..33(D) OTHER INFORMATION: /mod.sub.-- base=OTHER/note= &#34;N = Inosine&#34;(xi) SEQUENCE DESCRIPTION: SEQ ID NO:4:GGATCCGGATCCCANGCNGGNGCYTGRAANGCNGCYTG38(2) INFORMATION FOR SEQ ID NO:5:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 8 amino acids(B) TYPE: amino acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(ii) MOLECULE TYPE: peptide(xi) SEQUENCE DESCRIPTION: SEQ ID NO:5:ValThrTyrIleLeuAlaGlnPro15(2) INFORMATION FOR SEQ ID NO:6:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 6 amino acids(B) TYPE: amino acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(ii) MOLECULE TYPE: peptide(xi) SEQUENCE DESCRIPTION: SEQ ID NO:6:LeuPheValTyrValPro15(2) INFORMATION FOR SEQ ID NO:7:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 8 amino acids(B) TYPE: amino acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(ii) MOLECULE TYPE: peptide(xi) SEQUENCE DESCRIPTION: SEQ ID NO:7:XaaLeuGlySerSerTyrGlnThr15(2) INFORMATION FOR SEQ ID NO:8:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 10 amino acids(B) TYPE: amino acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(ii) MOLECULE TYPE: peptide(xi) SEQUENCE DESCRIPTION: SEQ ID NO:8:GlyGlyAsnLeuGluAlaLysTyrValArg1510__________________________________________________________________________