Identification of sperm-specific proteins that interact with A-kinase anchoring proteins in a manner similar to the type II regulatory subunit of PKA.

The cAMP-dependent protein kinase (PKA) is targeted to specific subcellular compartments through its interaction with A-kinase anchoring proteins (AKAPs). AKAPs contain an amphipathic helix domain that binds to the type II regulatory subunit of PKA (RII). Synthetic peptides containing this amphipathic helix domain bind to RII with high affinity and competitively inhibit the binding of PKA with AKAPs. Addition of these anchoring inhibitor peptides to spermatozoa inhibits motility (Vijayaraghavan, S., Goueli, S. A., Davey, M. P., and Carr, D. W. (1997) J. Biol. Chem. 272, 4747-4752). However, inhibition of the PKA catalytic activity does not mimic these peptides, suggesting that the peptides are disrupting the interaction of AKAP(s) with proteins other than PKA. Using the yeast two-hybrid system, we have now identified two sperm-specific human proteins that interact with the amphipathic helix region of AKAP110. These proteins, ropporin (a protein previously shown to interact with the Rho signaling pathway) and AKAP-associated sperm protein, are 39% identical to each other and share a strong sequence similarity with the conserved domain on the N terminus of RII that is involved in dimerization and AKAP binding. Mutation of conserved residues in ropporin or RII prevents binding to AKAP110. These data suggest that sperm contains several proteins that bind to AKAPs in a manner similar to RII and imply that AKAPs may have additional and perhaps unique functions in spermatozoa.

Gene duplication gives rise to a new 17-kilodalton lipocalin that shows epididymal region-specific expression and testicular factor(s) regulation.

Using transgenic mice, we have recently shown that 5 kb of the 5'-flanking region of the mouse epididymal retinoic acid-binding protein (mE-RABP) gene contains all of the information required for spatial and temporal gene expression in the epididymis. To identify the important cis-DNA regulatory element(s) involved in the tissue-, region-, and cell-specific expression of the mE-RABP gene, the 5-kb DNA fragment was sequenced. A computer analysis of the nucleotide sequence showed the presence of a new gene located 1.7 kb upstream from the mE-RABP gene transcription initiation site. The analysis of the open reading frame showed that the new gene encoded a putative 17-kDa lipocalin (named mEP17) related to mE-RABP. A 600-bp complementary DNA encoding mEP17 was cloned by rapid amplification of 3'-cDNA ends from epididymal total RNA. Two mEP17 RNA species (1 and 3.1 kb in size) were detected by Northern blot in the epididymis, but not in other tissues tested. In situ hybridization analyses showed that, unlike mE-RABP messenger RNA (mRNA), which is expressed in the distal caput epididymidis, mEP17 mRNA was detected only in the principal cells of the initial segment. The spatial expression and homology with mE-RABP suggest that mEP17 may act as a retinoid carrier protein within the epididymis. mEP17 mRNA expression disappeared 5 days postcastration. Four days after unilateral castration, mEP17 mRNA had nearly disappeared in the epididymis from the castrated side, but not from the intact side. In addition, testosterone replacement to bilaterally castrated mice failed to restore gene expression. We conclude that mEP17 gene expression is dependent on testicular factors circulating in the luminal fluid. Together our results suggest that mE-RABP and mEP17 genes were generated by duplication and that evolution led to a different region-specific gene expression and regulation in the epididymis.

Identification of a hamster epididymal region-specific secretory glycoprotein that binds nonviable spermatozoa.

Even though the epididymis produces an environment promoting sperm maturation and viability, some sperm do not survive transit through the epididymal tubule. Mechanisms that segregate the epididymal epithelium and/or the viable sperm population from degenerating spermatozoa are poorly understood. We report here the identification and characterization of HEP64, a 64-kDa glycoprotein secreted by principal cells of the corpus and proximal cauda epididymidis of the hamster that specifically binds to and coats dead/dying spermatozoa. The HEP64 monomer contains approximately 12 kDa carbohydrate and, following chemical deglycosylation, migrates as a approximately 52-kDa polypeptide. Both soluble (luminal fluid) and sperm-associated HEP64 are assembled into disulfide-linked high molecular weight oligomers that migrate as a doublet band of 260/280 kDa by nonreducing SDS-PAGE. In the epididymal lumen, HEP64 is concentrated into focal accumulations containing aggregates of structurally abnormal or degenerating spermatozoa, and examination of sperm suspensions reveals that HEP64 forms a shroudlike coating surrounding abnormal spermatozoa. The HEP64 glycoprotein firmly binds degenerating spermatozoa and is not released by either nonionic detergent or high salt extraction. Electron microscopic immunocytochemistry demonstrates that HEP64 localized to an amorphous coating surrounding the abnormal spermatozoa. The potential mechanisms by which this epididymal secretory protein binds dead spermatozoa as well as its possible functions in the sperm storage function of the cauda epididymidis are discussed.

Reproductive characteristics of the african pygmy hedgehog, atelerix albiventris.

To obtain further perspective on reproduction and particularly gamete function among so-called primitive mammals presently grouped in the Order Insectivora, we have examined the African hedgehog, Atelerix albiventris, in light of unusual features reported in shrews and moles. Atelerix proves to share many but not all of the characteristics seen in these other insectivores. The penis of Atelerix has a 'snail-like' form, but lacks the surface spines common in insectivores and a number of other mammals. Hedgehog spermatozoa display an eccentric insertion of the tail on the sperm head, and they manifest the barbs on the perforatorium that, in shrews, probably effect the initial binding of the sperm head to the zona pellucida. As a possible correlate, the structural matrix of the hedgehog acrosome comprises only two main components, as judged by immunoblotting, rather than the complex of peptides seen in the matrix of some higher mammals. The Fallopian tube of Atelerix is relatively simple; it displays only minor differences in width and in the arborized epithelium between the isthmus and ampulla, and shows no evidence of the unusual sperm crypts that characterize the isthmus or ampulla, depending on the species, in shrews and moles. In common with other insectivores, Atelerix appears to be an induced ovulator, as judged by the ovulation of some 6-8 eggs by about 23 h after injection of hCG. The dense cumulus oophorus appeared to have little matrix, in keeping with the modest dimensions of the tubal ampulla and, while it was not quite as discrete as that of soricids, it did show the same insensitivity to 0.5% (w/v) ovine or bovine hyaluronidase.

Isolation and molecular characterization of AKAP110, a novel, sperm-specific protein kinase A-anchoring protein.

Agents that increase intracellular cAMP are potent stimulators of sperm motility. Anchoring inhibitor peptides, designed to disrupt the interaction of the cAMP-dependent protein kinase A (PKA) with A kinase-anchoring proteins (AKAPs), are potent inhibitors of sperm motility. These data suggest that PKA anchoring is a key biochemical mechanism controlling motility. We now report the isolation, identification, cloning, and characterization of AKAP110, the predominant AKAP detected in sperm lysates. AKAP110 cDNA was isolated and sequenced from mouse, bovine, and human testis libraries. Using truncated mutants, the RII-binding domain was identified. Alignment of the RII-binding domain on AKAP110 to those from other AKAPs reveals that AKAPs contain eight functionally conserved positions within an amphipathic helix structure that are responsible for RII interaction. Northern analysis of eight different tissues detected AKAP110 only in the testis, and in situ hybridization analysis detected AKAP110 only in round spermatids, suggesting that AKAP110 is a protein found only in male germ cells. Sperm cells contain both RI, located primarily in the acrosomal region of the head, and RII, located exclusively in the tail, regulatory subunits of PKA. Immunocytochemical analysis detected AKAP110 in the acrosomal region of the sperm head and along the entire length of the principal piece. These data suggest that AKAP110 shares compartments with both RI and RII isoforms of PKA and may function as a regulator of both motility- and head-associated functions such as capacitation and the acrosome reaction.

Reproductive features of the eastern mole (Scalopus aquaticus) and star-nose mole (Condylura cristata).

Since moles are closely related to shrews, the gametes and reproductive tracts of the star-nose mole (Condylura cristata) and the eastern mole (Scalopus aquaticus) were examined to gain further insight into unusual reproductive traits of the Soricidae. Moles display many of these soricid traits, but with some important differences. The cumulus oophorus of Scalopus, ovulated about 16 h after hCG injection, was largely dispersed by hyaluronidase and, though quite dense, was nevertheless more similar to that of higher mammals than to the compact 'ball of the soricid cumulus. Within the female tract in these moles, approximately 85% of the length of the oviduct comprises a narrow ampulla with numerous differentiated crypts that, in shrews, house spermatozoa. However, in contrast to shrews, moles produce considerably larger numbers of spermatozoa, which challenges the proposal that, in shrews, oviductal sperm crypts specifically permit lower sperm production by the males. In the sperm head of these two moles, the acrosome displays the long rostrum that is typical of other Insectivora, and the perforatorium has the barbs by which soricid spermatozoa probably bind to the zona pellucida. Perhaps allied to this, immunoblots indicated that the immunoreactive acrosomal matrix of Scalopus spermatozoa is simpler than the polypeptide complex of the bovine and hamster acrosomal matrix.

Blastocyst-dependent upregulation of metalloproteinase/disintegrin MDC9 expression in rabbit endometrium.

Blastocyst attachment to mammalian uteri at implantation involves the adhesion of the trophoblast to the uterine epithelial surface. In the rabbit, fusion between adjacent epithelial cells precedes the initial attachment phase and is followed by fusion between the trophoblast and the epithelium. The reverse transcription/polymerase chain reaction method has been used to prepare a partial cDNA (rbMDC9) from periimplantation-stage endometrium; this represents the rabbit ortholog of MDC9, a member of the cellular metalloproteinase/disintegrin (ADAM) gene family. We demonstrate here the reproductive stage-specific expression of rbMDC9 mRNA in uterine epithelium during the periimplantation period. Furthermore, this expression is upregulated at implantation sites, and in situ hybridization analysis has revealed that the epithelial cells with the most prominent signal are those apposed to blastocysts. Immunostaining with E-cadherin has been used to trace lateral membranes of epithelial cells and, together with nuclear staining, has enabled the identification of cells fusing to become multinucleated cells, and later, to become an epithelial syncytium (symplasma). These fusing cells express the highest level of rbMDC9 mRNA. The results suggest that MDC9, a transmembrane modular protein with domains having potential integrin-binding, metalloproteinase, and fusogenic functions, is probably critical for the cellular interactions accompanying blastocyst implantation.

Targeting of the domain-specific integral membrane protein PM52 to the periacrosomal plasma membrane during guinea pig spermiogenesis.

The sperm plasma membrane is segregated into functionally, biochemically, and structurally distinct domains yet the protein sorting pathways and assembly mechanisms that assemble these domains during spermiogenesis are incompletely understood. We previously characterized two structurally related size-variant, integral membrane proteins of 52 kDa (PM52) and 35 kDa localized to the periacrosomal plasma membrane of guinea pig cauda epididymal spermatozoa (Westbrook-Case et al., 1994). In this study we used light and electron microscopic immunocytochemistry to define the expression pattern and sorting pathway that establishes the domain-specific distribution of PM52 during spermiogenesis. The PM52 is first expressed in acrosome-phase spermatids and it localizes exclusively to the cytoplasmic lobe. Immunoelectron microscopy revealed that both cytoplasmic vesicles and the plasma membrane of the cytoplasmic lobe labeled with anti-PM52. During early stages of expression, PM52 appeared to be absent from the head region, but significant PM52 accumulation over the spermatid head was noted in late acrosomal phase spermatids. Throughout spermiogenesis PM52 extended posteriorly to the annulus, which represents a barrier preventing PM52 diffusion into the posterior tail. Following the migration of the annulus to the midpiece-principal piece junction, PM52 began to disappear from the flagellar region and at the completion of spermiogenesis most of the PM52 was restricted to the acrosomal segment. Spermatids and epididymal sperm PM52 exhibited identical sizes by SDS-PAGE and immunoblotting, indicating that they are not proteolytically modified during epididymal maturation. The PM52 antibodies were also used to screen a guinea pig testis cDNA library, and sequence determination of full-length PM52 clones demonstrated identity of a sperm membrane protein recently termed "sperad" (Quill and Garbers, 1996). Membrane barriers and potential mechanisms establishing the domain-specific residence of PM52 are discussed.

Acrosome biogenesis in the hamster: ultrastructurally distinct matrix regions are assembled from a common precursor polypeptide.

The hamster sperm acrosome contains a stable matrix complex that binds specific hydrolases and appears to regulate their release during the acrosome reaction. This complex comprises two contiguous but ultrastructurally distinct regions that are segregated to specific sites within the acrosome. In this study, we define the temporal expression, processing, and localization of major matrix proteins of 29 kDa (AM29) and 22 kDa (AM22) during spermiogenesis and post-testicular sperm maturation in the epididymis. Peptide mapping, N-terminal microsequence analysis, immunoblotting, and immunocytochemistry were used to demonstrate that AM29 and AM22 of mature spermatozoa are structurally related and appear to arise from a common 40-kDa precursor protein expressed in round spermatids. A monoclonal antibody that recognized only the mature forms of the matrix proteins and a polyclonal antibody that recognized both the precursor and fully processed matrix proteins were prepared and used to demonstrate that the precursor protein is present in the acrosome of round spermatids and that it undergoes size processing during the terminal stages of spermiogenesis so that the mature matrix polypeptides are evident in epididymal spermatozoa. Finally, using light and electron microscopic immunocytochemistry, we demonstrated that the matrix polypeptides are excluded from the equatorial segment and are localized to both structurally distinct matrix domains of the mature acrosome. These data show that processing of the major proteins of the acrosomal matrix occurs in a temporally regulated fashion after their transport to the acrosome and that the processed products can assemble into ultrastructurally distinct matrix elements.

Progesterone and implanting blastocysts regulate Muc1 expression in rabbit uterine epithelium.

Mammalian uteri are unreceptive to blastocyst implantation except during a relatively brief period. The transmembrane, cell surface mucin, Muc1, is present on epithelial cells of nonreceptive uteri in various species and has been demonstrated to have antiadhesive properties. These activities of Muc1 may prevent interaction of the embryonic trophoblast cells with the uterine epithelium. A previous study indicated that Muc1 expression in the rabbit, as in primates, is up-regulated by progesterone. This response would be expected to create a nonadhesive uterine surface during the progesterone-dominated receptive phase. In the current study, Northern blot analysis was used to evaluate Muc1 messenger RNA expression in the endometrium of estrous and progesterone-treated estrous rabbits and in endometrium from different stages of pregnancy or pseudopregnancy. Steady state levels of Muc1 messenger RNA were increased 10-fold when estrous animals were treated with progesterone for 5 days. Muc1 message was elevated 2- to 6-fold over estrous levels in endometrium of pseudopregnant females and 30-fold in preimplantation stage (6.75 days postcoitum) uteri. During implantation (7.25 day postcoitum), the high level of Muc1 expression continued in nonimplantation regions, but was dramatically reduced in endometrium from implantation sites. Using immunofluorescence localization, Muc1 protein was present on the apical surface of epithelial cells of estrous, pseudopregnant (4 and 6.75 days), preimplantation (6.75 days), and implantation (7.25 day) stage uteri. At the latter stage, luminal epithelium apposed to blastocysts had a marked reduction or absence of Muc1 immunostaining. Muc1-immunoreactive cells included luminal and cryptal epithelium in pregnant/pseudopregnant uteri, whereas the glandular cells stained weakly. Short term coculture of uterine epithelial cells with trophoblastic vesicles derived from 6.75-day blastocysts also resulted in a local reduction in apical epithelial Muc1 staining. These findings demonstrate that Muc1 expression is up-regulated by progesterone in the rabbit uterine epithelium and increases incrementally during pre- and periimplantation stages. Removal of Muc1 from the epithelial surface at implantation sites is accomplished locally via signals apparently produced by the blastocyst.

Temporal expression and localization of protein farnesyltransferase during spermiogenesis and posttesticular sperm maturation in the hamster.

Spermiogenesis and posttesticular sperm maturation in the epididymis are distinct developmental processes that result in a polarized spermatozoon possessing a plasma membrane partitioned into segment-specific domains of distinct composition and function. The mechanisms that specify the distribution of intracellular organelles and target proteins to restricted membrane domains are not well understood. In this study we examined the expression pattern and distribution of protein farnesyltransferase (FTase) in hamster spermatids and epididymal spermatozoa to determine if protein lipidation may represent a potential mechanism to regulate protein association with specific organelles or the plasma membrane. Round spermatids exhibited only weak immunostaining with antibody against the beta-subunit of FTase, whereas elongating spermatids exhibited a high level of FTase expression that was segregated to the cytoplasmic lobe surrounding the anterior flagellum. Although FTase was released with the residual body, mature spermatids retained FTase within the midpiece and cytoplasmic droplet. In epididymal spermatozoa, FTase remained associated with the cytoplasmic droplet during its migration to the midpiece-principal piece junction; following release of the cytoplasmic droplet, no immunodetectable FTase was noted in the midpiece segment. Immunoblotting demonstrated the presence of both the alpha and beta subunits of FTase in sperm lysates. The temporal expression pattern and restricted distribution of FTase in spermatids and epididymal spermatozoa suggest a potential role in regulating protein association with specific organelles and/or membrane domains of the mature spermatozoon.

An antigenically related polypeptide family is a major structural constituent of a stable acrosomal matrix assembly in bovine spermatozoa.

The apical and principal segments of the bovine acrosome contain a stable matrix complex that is bound to the outer acrosomal membrane and exhibits hydrolase-binding activity. The present study was undertaken to determine whether the outer acrosomal membrane-associated matrix complex (OMC) is composed of a unique set of acrosomal proteins and to define its fate during both capacitation and the acrosome reaction. A purified OMC fraction was isolated from ejaculated spermatozoa, and one polypeptide of 32 kDa (OMC32) was purified to homogeneity and used for N-terminal sequence analysis and preparation of monospecific antisera. Immunofluorescence staining of sperm with anti-OMC32 demonstrated that the polypeptide localized specifically to the apical and principal segments of the acrosome. Immunoelectron microscopy further revealed that OMC32 was restricted to the stable matrix assembly and was not associated with the inner acrosomal membrane or the equatorial segment. Immunoblot analyses of sperm lysates and of the purified OMC fraction revealed that anti-OMC32 recognized an antigenically related family of polypeptides between 38 and 19 kDa. These polypeptides exhibited no size processing during capacitation or the acrosome reaction, and they were not released during the acrosome reaction but remained in the particulate cell subfraction, associated with the hybrid membrane complex. N-terminal sequence analysis of OMC32 indicated a structural relationship to the SP-10 polypeptide family of human and baboon spermatozoa. The potential function of the OMC complex and differences in the intraacrosomal distribution of bovine OMC32-related polypeptides from that reported for acrosomal SP-10 polypeptides in other species are discussed.

AM67, a secretory component of the guinea pig sperm acrosomal matrix, is related to mouse sperm protein sp56 and the complement component 4-binding proteins.

The guinea pig sperm acrosomal matrix is the dense core of the acrosome and is likely to be important in acrosome biogenesis and fertilization. Isolated acrosomal matrices are composed of a limited number of major bands when analyzed by SDS-polyacrylamide gel electrophoresis, among which is a Mr 67,000 protein that we have termed AM67. Indirect immunofluorescence demonstrated that AM67 is localized to the apical segment of the cauda epididymal sperm acrosome. Immunoelectron microscopy further refined the localization of AM67 to the M1 (dorsal bulge) domain within the acrosome. Using a polymerase chain reaction product based upon tryptic peptide sequences from AM67, a lambdagt11 guinea pig testis cDNA library was screened to yield two cDNA clones that encode the AM67 peptides. Northern analysis revealed that AM67 is transcribed as a 1. 9-kilobase testis-specific mRNA. The complete AM67 sequence encodes a prepropolypeptide of 533 amino acids with a calculated Mr of 59, 768. Following cleavage of a probable signal sequence, the polypeptide was predicted to have a Mr of 56,851 and seven consensus sites for asparagine-linked glycosylation. The deduced amino acid sequence of AM67 is most similar to those of the mouse sperm protein sp56 and the alpha-subunits of complement component 4-binding proteins from various mammalian species. Although mouse sp56 has been reported to be a cell-surface receptor for the murine zona pellucida glycoprotein ZP3, standard immunoelectron microscopy using the anti-sp56 monoclonal antibody 7C5 detected sp56 within the mouse sperm acrosome, but failed to detect sp56 on the surface of acrosome-intact mouse sperm. Furthermore, acrosomal labeling was detected in mouse sperm prepared for immunofluorescence using paraformaldehyde fixation, but was not observed with live unfixed sperm. Thus, the finding that sp56 is present within the acrosome provides further support that sp56 and AM67 are orthologues and suggests that sp56 may function in acrosomal matrix-zona pellucida interactions during and immediately following the acrosome reaction in the mouse.

Specific expression of haptoglobin mRNA in implantation-stage rabbit uterine epithelium.

A glycoprotein, termed GP42, was previously identified in uterine fluid obtained from peri-implantation-stage rabbits. N-terminus amino acid sequencing of purified GP42 demonstrated identity through the first 13 amino acids with the beta subunit of liver haptoglobin. The present study was undertaken to determine if GP42 is indeed identical to haptoglobin and, if so, to determine whether it is expressed in the uterus as opposed to being present as a transudate from plasma. Reverse transcription-PCR amplification of poly(A)+ RNA prepared from implantation-stage rabbit endometrium with GP42- and haptoglobin-specific primers yielded a predicted 667 bp cDNA product. Sequence analysis of the cloned cDNA confirmed the identity of GP42 with beta-haptoglobin. Northern blot analysis demonstrated the specific expression of haptoglobin mRNA in the peri-implantation-stage endometrium and the absence of its expression in the estrous or day 4 pseudopregnant endometrium. Non-isotopic in situ hybridization revealed that the haptoglobin mRNA was restricted to the epithelium lining the luminal surface and mucosal folds of day 6(3/4) pregnant or pseudo-pregnant uteri and that no haptoglobin mRNA was detectable in the epithelium of the deep glands or cells of the stroma or myometrium. Similarly, in situ hybridization revealed no expression of haptoglobin mRNA in any cell types of the estrous uterus. These data establish the identity of GP42 with beta-haptoglobin and demonstrate that it is expressed in a stage-specific manner just prior to implantation, correlating with uterine receptivity to blastocyst implantation. Endometrial GP42 mRNA expression is not dependent on the presence of blastocysts.

Subcellular localization of the regulatory subunits of cyclic adenosine 3',5'-monophosphate-dependent protein kinase in bovine spermatozoa.

Cyclic AMP (cAMP) is a regulator of sperm flagellar activity. The action of this cyclic nucleotide is presumably mediated by cAMP-dependent protein kinase (PKA). PKA is localized or targeted to specific subcellular sites through the interaction of PKA regulatory subunits with A-kinase anchoring proteins (AKAPs). We have recently shown that the addition of PKA anchoring inhibitor peptides to spermatozoa leads to the complete arrest of motility. A knowledge of the subcellular localization of PKA and AKAPs is essential for an understanding of how cAMP acts in spermatozoa. In this report, monospecific, affinity-purified, antipeptide antibodies were used to determine the distribution of the regulatory (R) subunit isoforms. Immunocytochemistry staining revealed that RIalpha and RIbeta subunits are both localized predominantly in the acrosomal segment of the head, although they have distinct staining patterns within this region. In addition to the head, RIbeta was observed in the midpiece of the tail while RIalpha was detected in the connecting piece. RIIalpha is prominent in the axonemal region of the flagellum but was not observed in the head region. These data suggest distinct roles for each of these isoforms in sperm functions such as motility and the acrosome reaction.

Identification of hydrolase binding activities of the acrosomal matrix of hamster spermatozoa.

The interior of the mammalian sperm acrosome contains a structural framework, the acrosomal matrix, that may regulate both the distribution of hydrolases within the acrosome and their release during the acrosome reaction. To define the biochemical basis of this interaction, we examined the binding of two acrosomal hydrolase, proacrosin and N-acetylglucosaminidase (NAGA), to a purified acrosomal matrix fraction of hamster spermatozoa. Proacrosin-acrosin was chromatographically purified from acid extracts of hamster spermatozoa and consisted of four size variants of 50 kDa, 49 kDa, 45 kDa, and 43 kDa. Each of the four isoforms exhibited the same N-terminal amino acid sequence through 16 residues, suggesting that they may be modified by cleavage at the C-terminus. Polyclonal antiserum against the proacrosin isoforms specifically binds the acrosomal cap as shown by immunofluorescence microscopy. Neither proacrosin nor NAGA were solubilized when sperm were permeabilized with Triton X-100 under low ionic strength conditions; however, both hydrolases were releases by extraction with Triton X-100 containing 0.5 M NaCl. An acrosomal matrix fraction isolated under low ionic strength conditions retained bound proacrosin-acrosin and NAGA, and both hydrolases were released from the matrix by subsequent high-salt extraction. After high-salt treatment, the acrosomal matrix retained specific binding sites for both proacrosin and NAGA. In a blot overlay assay, a set of acrosomal matrix polypeptides between 29 kDa and 24 kDa specifically bound proacrosin. These data suggest that specific interactions between acrosomal matrix polypeptides and hydrolases represent a mechanism to sequester hydrolases within the acrosome and to regulate their release during the acrosome reaction.

Studies on [3H]palmitate-binding proteins of rat spermatozoa: a post-translational modification of membrane proteins by fatty acid acylation.

The purpose of the present study was to demonstrate the post-translational modifications of sperm plasma membrane proteins by fatty acid acylation during sperm maturation in the epididymis. Rat epididymal spermatozoa were incubated at 37 degrees C with various concentrations (100 microCi and 1 mCi) of [9-10(n)3H]palmitic acid in a medium containing Tyrode's solution supplemented with sodium bicarbonate, sodium pyruvate and sodium lactate. The incorporation of [3H]palmitate in vitro was determined in epididymal spermatozoa and an attempt was made to identify the lipid-linked proteins of purified plasma membranes of maturing epididymal spermatozoa by autoradiography. The studies demonstrated that [3H]palmitate was covalently linked to a subset of membrane cytoskeleton proteins of maturing rat spermatozoa. The pattern of incorporation of lipid was a maturation-associated phenomenon as caput spermatozoa incorporated more radioactivity than did caudal spermatozoa. The labelled proteins appeared to be membrane-bound since 82% of radioactivity was associated with membrane fractions. Autoradiograms of SDS-PAGE gels of labelled caput sperm extract showed three prominent palmitate-incorporating protein bands of about 70, 56 and 36 kDa and few minor bands. Most of these proteins were present in the membrane fraction of caput spermatozoa. Labelled gels of both the sperm extracts and of purified membranes showed resistance to hydroxylamine treatment, suggesting that there are amide bonds between lipid and proteins. The higher incorporation of labelled palmitate by immature spermatozoa of the caput epididymis compared with mature spermatozoa from the cauda epididymis and the addition of palmitate to plasma membrane proteins of caput epididymal spermatozoa suggest that fatty acylation is a post-translational modification of sperm membrane proteins.

A haptoglobin-like glycoprotein is produced by implantation-stage rabbit endometrium.

A polypeptide of 42 kDa was previously identified in rabbit uterine epithelium during the peri-implantation period as a progesterone-dependent, stage-specific protein. Binding of the lectin RCA-I to the 42-kDa band on Western blots demonstrated that it was a glycoprotein, here designated GP42. With use of a polyclonal antiserum to this glycoprotein, strong immunostaining was present on the surface of epithelial cells in implantation-stage uteri (6-7 days pregnant). Uteri of 4-day pseudopregnant females had only trace reactivity, and estrous uteri were devoid of immunostaining. Comparison of GP42 staining on immunoblots of uterine luminal samples, obtained using buffer with or without the detergent Triton X-100, demonstrated that GP42 is either loosely associated with the epithelial surface or is a secretory product. The N-terminal sequence of GP42 was identical through 13 amino acids with the beta subunit of haptoglobin, an acute-phase protein secreted by the liver. Additional immunoblot analyses were carried out after one- or two-dimensional PAGE separation of polypeptides of rabbit uterine samples and human haptoglobin. These employed anti-GP42 as well as antibodies directed against haptoglobin, and results confirmed the similarity of GP42 with beta-haptoglobin. In nonreducing gels, reactivity with anti-GP42 was present in a band of 110 kDa. This is comparable to the molecular size of serum haptoglobin, which occurs as a tetramer of two alpha (15-kDa) and two beta (38-42-kDa) chains. Cultured epithelial cells, derived from 4-day pseudopregnant uteri, released GP42 into the medium, but stromal cells appeared not to produce the glycoprotein. We conclude that GP42 is a uterine glycoprotein, related or identical to haptoglobin, and produced by rabbit uterine epithelial cells during the peri-implantation period. Possible roles for GP42 in relation to ovo-implantation are discussed in light of known functions for haptoglobin and haptoglobin-related protein.

Proacrosin-acrosomal matrix binding interactions in ejaculated bovine spermatozoa.

The mechanisms regulating hydrolase release during the mammalian sperm acrosome reaction are poorly understood. The present study demonstrates that specific domains of the acrosomal matrix of bovine spermatozoa function to maintain a particulate proacrosin pool and to regulate proacrosin/acrosin release. In sonicated sperm suspensions, 50-60% of the total proacrosin activity was sedimentable, and the amount of sedimentable proacrosin activity remained unchanged over time. Serial centrifugation and resuspension experiments demonstrated that the particulate proacrosin fraction resulted from an equilibrium binding of proacrosin to a stable sperm structure. To identify the proacrosin-binding structure of the acrosome, a purified sperm head fraction was isolated on sucrose density gradients. The sperm heads were extracted with Triton X-100, and a homogeneous acrosomal subfraction, the matrix complex associated with the outer acrosomal membrane (OMC), was isolated on Percoll density gradients. A centrifugation assay was then used to demonstrate that the OMC specifically binds proacrosin in a dose-dependent manner. These data demonstrate that the OMC represents a stable structural component of the acrosome that maintains a particulate proacrosin pool. We propose that the OMC regulates proacrosin release during the acrosome reaction and maintains elevated acrosin concentrations at the site of sperm-egg interaction.

Sorting of the domain-specific acrosomal matrix protein AM50 during spermiogenesis in the guinea pig.

We previously identified an insoluble 50-kDa acrosomal matrix protein (AM50) localized to the ventral region of the guinea pig sperm apical segment. AM50 is converted to a 42-kDa polypeptide and released during matrix dispersion in acrosome-reacting sperm. This study examines the sorting pathways and assembly processes which generate the domain-specific distribution of AM50 in the acrosome. AM50 was expressed during early acrosome development and localized to the matrix of proacrosomal granules and the acrosomal vesicle. Initial sorting of AM50 occurred in Golgi phase spermatids, where it became concentrated in the matrix surrounding the acrosomal granule. AM50 remained restricted to the apical segment of acrosome phase spermatids and was finally sorted to the ventral matrix of the apical segment in maturation phase spermatids. By reducing SDS-PAGE testicular AM50 exhibited a slightly higher M(r) of 52 kDa than the 50-kDa form of cauda epididymal spermatozoa. Nonreducing SDS-PAGE demonstrated that testicular and epididymal AM50 were assembled into homomeric complexes of 480 and 450 kDa respectively. Cauda epididymal sperm apical segments contained a second disulfide-cross-linked homomeric complex of 520 kDa composed of a 68-kDa subunit. These studies indicate that AM50 is first assembled into a disulfide-cross-linked complex and subsequently processed into mature AM50. These data also suggest that disulfide-linked complexes of different structural proteins may assemble into distinct acrosomal matrix compartments.