cDNA cloning and functional analysis of ascidian sperm proacrosin

cDNA cloning and functional analysis of proacrosin from the ascidian Halocynthia roretzi were undertaken. The isolated cDNA of the ascidian preproacrosin consists of 2367 nucleotides, and an open reading frame encodes 505 amino acids, which corresponds to the molecular mass of 55,003 Da. The mRNA of proacrosin was found to be specifically expressed in the gonad by Northern blotting and in the spermatocytes or spermatids by in situ hybridization. The amino acid sequences around His(76), Asp(132), and Ser(227), which make up a catalytic triad, showed high homology to those of the trypsin family. Ascidian acrosin has paired basic residues (Lys(56)-His(57)) in the N-terminal region, which is one of the most characteristic features of mammalian acrosin. This region seems to play a key role in the binding of (pro)acrosin to the vitelline coat, because the peptide containing the paired basic residues, but not the peptide substituted with Ala, was capable of binding to the vitelline coat. Unlike mammalian proacrosin, ascidian proacrosin contains two CUB domains in the C-terminal region, in which CUB domain 1 seems to be involved in its binding to the vitelline coat. Four components of the vitelline coat that are capable of binding to CUB domain 1 in proacrosin were identified. In response to sperm activation, acrosin was released from sperm into the surrounding seawater, suggesting that ascidian acrosin plays a key role in sperm penetration through the coat. These results indicate that ascidian sperm contains a mammalian acrosin homologue, a multi-functional protein working in fertilization.     

Benzamidine as an inhibitor of proacrosin activation in bull sperm.

Epididymal and ejaculated sperm contain a zymogen form of acrosin (acrosomal proteinase, EC 3.4.21.10) which is converted to active enzyme prior to fertilization. Benzamidine at concentrations greater than 10 mM has been shown to inhibit the conversion of proacrosin to acrosin. Based on this inhibition, a procedure was developed for extracting and quantitating the proacrosin content of bull sperm. Sperm were isolated from semen and washed by centrifugation through 1.3 M sucrose and the outer acrosomal membrane removed by homogenization. When 25 mM benzamidine was added to the semen and wash solutions, 98% or more of the acrosin activity in the sperm homogenate was present as proacrosin. Proacrosin can be extracted from the sperm homogenate by dialysis at pH 3, which solubilized the proenzyme and removed benzamidine. Benzamidine has been useful in isolating proacrosin and provides a new method for studying the activation of proacrosin in intact sperm. Neutralization of sperm extracts, after removal of benzamidine, resulted in rapid activation of proacrosin with a pH optimum of 8.5, and activation was complete within 15 min over a pH range of 7.0 to 9.5. Rapid activation also occurred during the washing of sperm in the absence of benzamidine, and this activation correlated with a swelling of the acrosomal membrane. This rapid activation appears to result from a small amount of acrosin activity consistently present in the sperm extract. These results indicate an autocatalytic conversion of proacrosin to acrosin and suggest that disruption of the acrosomal membrane may trigger this activation.     

Activation and subsequent degradation of proacrosin is mediated by zona pellucida glycoproteins, negatively charged polysaccharides, and DNA

Boar proacrosin (E.C. 3.4.21.10, Mw 53 kD) was isolated by a modified method and subjected to autoactivation. Previously described molecular intermediates of 49 and 43 kD and a stable form (beta-acrosin, 35 kD) were identified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Autoactivation was expedited in the presence of either zona pellucida glycoproteins, fucoidan, or DNA. The end point of this accelerated conversion was the complete degradation of otherwise stable beta-acrosin via the formation of a characteristic active intermediate protein of 30 kD. All intermediate molecular forms observed during proacrosin activation/conversion exhibited the N-terminal sequence of the boar acrosin heavy chain, indicating a C-terminal processing mechanism. Hence zona pellucida glycoproteins stimulate proacrosin activation as well as acrosin degradation. Such a mechanism of proenzyme activation and degradation is to our knowledge described here for the first time and points to a previously unrecognized role of zona pellucida during gamete interaction.     

Effects of various conditions of semen storage on the acrosin system of human spermatozoa

Stability of the human sperm acrosin system (major components: non-zymogen acrosin, proacrosin and acrosin inhibitor) was studied under various conditions of semen storage used clinically or in the laboratory. Freezing at -196 degrees C caused a profound decrease in total acrosin content and in the amount of this enzyme present in zymogen form (proacrosin), but resulted in some increase in non-zymogen acrosin. Acrosin inhibitor did not appear to be significantly affected by this treatment. No relationship was present between the decreases in sperm motility induced by freezing to -196 degrees C and the alterations in total acrosin, proacrosin and non-zymogen acrosin. Storage of whole semen at -20 degrees C had deleterious effects on all the components of the acrosin system measured except for non-zymogen acrosin. Major decreases in the total acrosin, proacrosin and acrosin inhibitor occurred after only 1 day at -20 degrees C and continued slowly thereafter. Whole semen kept at room temperature for up to 24 h after ejaculation did not show any significant changes in the sperm acrosin system. Seminal plasma did not have a detrimental or stabilizing effect of acrosin and proacrosin when spermatozoa were kept at room temperature. However, removal of seminal plasma and re-suspension of spermatozoa in 0.9% NaCl resulted n the liberation of a significant amount of the acrosin inhibitor from the spermatozoa and the apparent activation of some of the proacrosin to acrosin.     

Gossypol inhibition of acrosin and proacrosin, and oocyte penetration by human spermatozoa

Gossypol, a known antispermatogenic agent, was found to effectively inhibit the highly purified boar sperm proacrosin-acrosin proteinase enzyme system by irreversibly preventing the autoproteolytic conversion of proacrosin to acrosin and reversibly inhibiting acrosin activity. The agent appears to prevent the self-catalyzed by not the acrosin-catalyzed activation of proacrosin. In additional experiments, brief exposure of human semen to concentrations of gossypol, which did not visibly alter spermatozoal motility or forward progression, was found to irreversibly inhibit the conversion of proacrosin to acrosin although the activity of the nonzymogen acrosin was not decreased, and also to prevent the human spermatozoa from penetrating denuded hamster oocytes. Gossypol inhibition of proacrosin conversion to acrosin closely paralleled the decline in oocyte penetration. Racemic (+/-) gossypol was equally as effective as the enantiomer (+) gossypol. The results suggest that the inhibition of proacrosin conversion to acrosin is a mechanism by which gossypol exerts its antifertility effect at nonspermicidal concentrations and that low levels of gossypol should be tested for their contraceptive action when placed vaginally.     

Proacrosin activation in the presence of a 32-kDa protein from boar spermatozoa

A 32-kDa protein was purified from acrosomal extracts of ejaculated boar spermatozoa as a complex with 55- and 53-kDa proacrosins. In the presence of the 32-kDa protein, these proacrosins were sequentially converted by autoactivation to a 49-kDa intermediate, a 43-kDa intermediate, and then a 35-kDa mature acrosin. This activation process was consistent with that in the absence of the 32-kDa protein, but differed in producing the 49-kDa form as the predominant acrosin intermediate. Thus, the 32-kDa protein may be a regulatory protein for proacrosin activation. The 49-kDa intermediate was a two-chain polypeptide with the amino-terminal sequences corresponding to those of the light and heavy chains of mature acrosin, whereas the carboxyl-terminal sequence of its heavy chain was identical with that of the 53-kDa proacrosin. These results suggest that the 49-kDa intermediate is produced from 53-kDa proacrosin during proacrosin activation by the cleavage of the peptide bond between Arg-23 and Val-24, which results in the formation of the light and heavy chains.     

Is sperminogen a modified proacrosin? Isolation, purification, and partial characterization of low-molecular-mass boar proacrosin

Low-molecular-mass zymogen was extracted from boar spermatozoa together with proacrosin using 10% acetic acid supplemented with 10% glycerol, and was purified by the sequential use of gel filtration on Sephadex G-75 and (FPLC) reversed-phase chromatography. LMM zymogen represented approximately 5% of the latent trypsin-like activity present in the sperm extract. SDS-PAGE indicated a molecular mass of 33 kDa. The zymogen reacted with both mouse monoclonal and rabbit polyclonal antibodies to boar acrosin. Determination of the N-terminal sequence of 34 amino-acid residues revealed its identity with the known N-terminal sequence of boar proacrosin.     

Proacrosin activation and acrosin release during the guinea pig acrosome reaction

The kinetics of proacrosin activation and release from guinea pig spermatozoa during the nonsynchronous acrosome reaction were studied. Epididymal spermatozoa were incubated at 37 degrees C in a defined medium (pH 7.8) containing 1.7 mM Ca2+. After 195 min, 78% of the motile spermatozoa had undergone the acrosome reaction as determined by light microscopy. Acrosin and proacrosin levels in the spermatozoa and medium were measured at the beginning of the incubation period. Most of the total acrosin activity (78%) was associated with the spermatozoa, of which greater than 90% was in the form of proacrosin. Proacrosin represented a small, stable fraction (23%) of the total acrosin in the medium; it did not activate to acrosin while in the medium. After 195 min, a decrease in sperm-associated total acrosin (42%; p less than 0.05) was accompanied by an increase in the total acrosin level in the medium (115%; P less than 0.05). No change in the relative proacrosin content (percent of total acrosin) was evident in either medium or spermatozoa. Additional experiments quantified acrosin and proacrosin during the progression of the acrosome reaction. Both the loss of sperm-associated total acrosin and the increase in total acrosin levels in the medium were highly correlated with the fraction of acrosome-reacted spermatozoa (r = 0.954 and 0.922, respectively; P less than 0.001). However, the rate of acrosin appearance in the medium was only 60% (P less than 0.001) of the rate of acrosin loss from the spermatozoa. The fractional proacrosin content of spermatozoa (94%) and medium (31%) remained unchanged during the acrosome reaction (r = 0.15 and 0.30, respectively; P greater than 0.1).(ABSTRACT TRUNCATED AT 250 WORDS)     

Proacrosin/acrosin activity during spermiohistogenesis of the bull

Abstract. Acrosin and its zymogen form, proacrosin, were extracted from early and late spermatids, from ejaculated and epididymal spermatozoa ( caput, corpus , and cauda ) of the bull. Activity of proacrosin/acrosin and the time course of proacrosin activation were studied. It turned out that proacrosin/acrosin activity is first demonstrable in haploid spermatids, increases during spermiohistogenesis in the testis, and remains nearly constant in epididymal and ejaculated spermatozoa.     

Proacrosin/acrosin activity during spermiohistogenesis of the bull

Acrosin and its zymogen form, proacrosin, were extracted from early and late spermatids, from ejaculated and epididymal spermatozoa (caput, corpus, and cauda) of the bull. Activity of proacrosin/acrosin and the time course of proacrosin activation were studied. It turned out that proacrosin/acrosin activity is first demonstrable in haploid spermatids, increases during spermiohistogenesis in the testis, and remains nearly constant in epididymal and ejaculated spermatozoa.     

Comparative activation studies with extracted and purified human proacrosin

Proacrosin was purified from acid extracts of human spermatozoa by concanavalin A precipitation and Bio-Gel P-100 chromatography. Two molecular weight forms of proacrosin were obtained, a major one with a Mr of 70,000-71,000 and a minor one with a Mr of 47,000-53,000. In contrast to sperm extracts, the purified forms of proacrosin were free of acrosin inhibitor(s) and nonzymogen acrosin. By modulating pH, ionic strength and temperature, the activation of proacrosin in sperm extracts was compared to only the major form of purified proacrosin, since it seemed to be the source of the lower molecular weight form of proacrosin. In both preparations, proacrosin activation occurred maximally over a broad pH range (7.6-8.8 for purified proacrosin and 7.6-9.6 for extract). Additionally, an ionic strength of 0.1 and above caused a decrease in proacrosin activation in both preparations. Similarly, proacrosin was sensitive to short incubation periods at 45 degrees C and above which caused a decrease in the amount of proacrosin found in both preparations.     

Functional interactions between sulphated polysaccharides and proacrosin: implications in sperm binding and digestion of zona pellucida.

Acrosin is a serine protease located within mammalian acrosome as inactive proacrosin. Sulphated polymers bind to proacrosin and acrosin, to a domain different from the active site. Upon binding, these polymers induce proacrosin activation and some of them, such as fucoidan, inhibit sperm binding to the zona pellucida. In this work we have studied the interaction of solubilised zona pellucida glycoproteins (ZPGs), heparin and ARIS (Acrosome Reaction Inducing Substance of Starfish) with boar and human acrosin. We have found that ARIS, solubilised ZPGs and fucoidan, but not heparin, inhibit the binding of the monoclonal antibody against human acrosin C5F10 to boar or human proacrosin. These results suggest that fucoidan, solubilised ZPGs and ARIS bind to a related domain on the proacrosin surface. Moreover, ARIS was able to induce human proacrosin activation. On the other hand, neither ARIS nor heparin from porcine intestinal mucosa or bovine lung induced hamster sperm acrosome reaction or sperm motility. Recent data showed that acrosin is involved in dispersal of the acrosomal matrix after acrosome reaction. Thus, the control of the ZPG glycan chains over proacrosin activation may regulate both sperm penetration rate and limited proteolysis of zona pellucida proteins.     

The zymogen form of acrosin in testicular,epididymal, and ejaculated spermatozoa from ram

The sperm-specific proteinase acrosin (EC 3.4.21.10) is found in spermatozoa as a zymogen. We have looked for different forms of this zymogen in testicular, epididymal, and ejaculated spermatozoa from ram and have compared total sperm extracts made immediately after cell disruption with extracts made later from isolated sperm heads. We have concluded that the autoactivatable zymogen form, known generally as proacrosin, is the only form of acrosin within intact mature ram spermatozoa; no other zymogen form was detected, although lower levels of proacrosin were found in some samples of testicular spermatozoa. From studies of the activation process, it appears that ram proacrosin is truly autoactivatable; no evidence could be found for the involvement of any auxiliary enzyme. Estimations of the molecular weight of proacrosin using gel chromatography (60,000) and SDS-polyacrylamide gel electrophoresis (51,300) indicated that the zymogen is monomeric. Comparison with the molecular weight of ram acrosin (44,000 or 40,000, using the two respective methods) indicated that a single acrosin molecule is derived from each zymogen molecule. The sperm acrosin inhibitor (molecular weight 11,000 or 8,000) was present in testicular spermatozoa as well as in ejaculated spermatozoa; there was no evidence that it was produced as a result of zymogen activation.     

Ultrastructural localization of proacrosin and acrosin in ram spermatozoa

Proacrosin and acrosin were localized immunocytochemically at the electron microscope level in ram spermatozoa undergoing an ionophore-induced acrosome reaction. Antigenicity was preserved after fixation with 0.5% w/v ethyl-(dimethylaminopropyl)-carbodimide, and an antibody preparation was used that reacted with all major forms of ram acrosin. All stages of the acrosome reaction could be observed in a single preparation. At the earliest stage, labeling was observed throughout the acrosomal contents, which were just beginning to disperse. As dispersal proceeded, labeling diminished, being associated only with visible remnants of the acrosomal matrix. By the time the acrosome had emptied, almost no labeling could be detected on the inner acrosomal membrane. The relationship between matrix dispersal and proacrosin activation was studied in isolated ram sperm heads. While proacrosin was prevented from activating, the acrosomal matrix remained compact; but as activation proceeded, the matrix decondensed and dispersed in close parallel. By the time proacrosin activation was complete, the acrosomal contents had almost entirely disappeared. We conclude that proacrosin is distributed throughout the acrosomal contents as an intrinsic constituent of the acrosomal matrix. During the acrosome reaction, proacrosin activation occurs, resulting directly in decondensation of the matrix. All the contents of the acrosome including acrosin disperse and, by the time the acrosome is empty and the acrosomal cap is lost, only occasional traces of acrosin remain on the inner acrosomal membrane. Since the acrosomal cap is normally lost during the earliest stages of zona penetration, acrosin's role in fertilization is unclear: it does not appear to be a zona lysin bound to the inner acrosomal membrane.     

Rabbit testis proacrosin: Immunological similarities between testis,sperm proacrosins and the initially formed testis acrosin

Anti-rabbit proacrosin IgG was prepared from goat serum following immunization with a homogeneous preparation of rabbit testis proacrosin. The “auto-activation” products of purified testis proacrosin were separated into 68,000 and 34,000 molecular weight (mol wt) acrosins by Sephadex G-100 column chromatography. Immunodiffusion analysis of testis and epididymal sperm proacrosins and acrosins on agarose gel against goat anti-rabbit testis proacrosin showed immunological identity between rabbit testis and sperm proacrosins and the initial testis acrosin (mol wt 68,000). However, the 34,000 mol wt form of testis acrosin showed weaker reaction with the antibody and only partial identity with the proacrosin and the 68,000 mol wt form of acrosin. These results suggest that there is no major structural difference between testis and sperm proacrosins and between proacrosin and the 68,000 mol wt acrosin, but such a structual change occurs when the 34,000 mol wt acrosin is formed.     

Studies on the rabbit proacrosin-acrosin system

A single molecular form (Mr = 68,000 approx) of a homogeneous preparation of rabbit testis proacrosin (S. K. Mukerji and S. Meizel (1979) J. Biol. Chem. 254, 117;21-11728) was initially converted by autoactivation into an acrosin (Mr = 68,000); both gave a single activity and protein bands with similar electrophoretic mobilities (Rm = 0.25) when subjected to polyacrylamide disc gel electrophoresis on 7.5% gel at pH 4.5. Two additional bands (Rm values of 0.395-0.412 and 0.497-0.519, respectively) were noticeable only when proacrosin was activated further after attaining maximum activity. The slowest- and the fastest-moving bands were separated into two acrosin activity peaks by Sephadex G-100 gel-filtration chromatography on a calibrated column. The molecular weights of the two proteins, determined by rechromatography on the same column, was estimated to be 68,000 and 34,000, respectively. Also, sodium dodecyl sulfate-polyacrylamide disc gel electrophoresis of three acrosins gave protein bands which corresponded to molecular weights of approximately 68,000, 52,000, and 34,000, respectively. Electrophoresis data suggest that the loss of acrosin activity generally observed following prolonged activation of proacrosin is caused by self-aggregation of the Mr 34,000 form of acrosin. This property was not shown by Mr 68,000 acrosin. Initial acrosin (Mr = 68,000) was activated by divalent cations such as Ca2+ and Mg2+. The enzyme was inhibited by Zn2+, Fe2+, Hg2+, and sulfhydryl blockers such as 5,5'-dithiobis(2-nitrobenzoic acid), p-hydroxymercuribenzoate, and iodoacetate, apparently due to their reaction with one out of six titratable sulfhydryl groups per mole of acrosin. Probably Zn2+ is involved in acrosomal stabilization. The initial rabbit acrosin (Mr = 68,000) appears to be the major and most stable form, and is generated from proacrosin with little structural alteration. This may be the functionally active form which plays an essential role in mammalian fertilization.     

A basic 18-amino acid peptide contains the polysulfate-binding domain responsible for activation of the boar proacrosin/acrosin system

Proacrosin is the zymogen of acrosin, a serine protease localized in the acrosomal matrix of mammalian sperm. Proacrosin/acrosin binds to solubilized zona pellucida glycoproteins (ZPGs) and various polysulfates in a non-enzymatic mechanism. In addition, both polysulfates and ZPGs induce proacrosin activation once they bind to the polysulfate-binding domain (PSBD) of the enzyme. We show here that the peptide (43)IFMYHNNRRYHTCGGILL(60) inhibited the proacrosin activation induced by either fucoidan or ZPGs. In addition, the peptide was recognized by the monoclonal antibody C5F10, which is directed against the PSBD region. Our data suggest that the PSBD is composed of many "subsites" that may or may not interact with each other.     

The molecular transformation of rabbit testis proacrosin into acrosin.

Partially purified rabbit testis proacrosin formed only one acrosin of 73,000 ± 3000 apparent molecular weight (M_r) during the early phase of “autoactivation” at pH 8. Complete “autoactivation” then converted this acrosin to a 38,000 ± 3000 M_r, acrosin. These results suggest the existence of a proacrosin dimer (73,000) or a dimer of proacrosin and an acrosomal membrane protein which were converted first to an acrosin dimer (73,000 M_r) or to an acrosin-membrane protein dimer and then to the acrosin monomer (38,000). The formation of a 73,000 ± 3000 M_r acrosin from a 73,000 ± 3000 proacrosin is explainable by assuming that either a small activation pertide(s) is released or none at all.     

Characterization of proacrosin/acrosin system after liquid storage and cryopreservation of turkey semen (Meleagris gallopavo)

This study was designed to identify the effect of liquid storage at 4 °C for 48 h and cryopreservation on the proacrosin/acrosin system of turkey spermatozoa. Anti-acrosin I antibodies were produced and used to demonstrate Western blot analysis profile of the proacrosin/acrosin system of sperm and seminal plasma and possible changes in the proacrosin/acrosin system of turkey sperm stored for 2.5, 24, and 48 h or cryopreserved. At the same time acrosin-like activity was examined by the measurement of amidase activity of sperm extracts, sperm suspension, and seminal plasma of turkey semen. A computer-assisted sperm analysis system was used to monitor the sperm motility characteristics of turkey sperm stored for 48 h or cryopreserved. Different profiles of the sperm proacrosin/acrosin system were observed regarding the presence or absence of inhibitors (p-nitrophenyl-p'-guanidine benzoate [NPGB] and Kazal family inhibitor) during the extraction process. When NPGB was present three main bands were observed with the molecular weight ranging from 66 to 35 kDa. Bands corresponding to acrosin I and II were not observed. In sperm extract without NPGB, three or four bands were observed with the molecular weight ranging from 41 to 30 kDa. The bands corresponding to acrosin I and II were observed. During liquid storage a decrease in sperm motility and an increase in sperm-extracted amidase activity were observed. After 24 and 48 h of storage, extracted amidase activity was higher than at 2.5 h by 24% and 31%, respectively. However, no changes in the Western blot analysis profiles of sperm extract and seminal plasma were visible during liquid storage. After cryopreservation a decrease in sperm motility and all sperm motility parameters were observed. In contrast to liquid storage, cryopreservation did not increase extracted amidase activity. However, changes in Western blot analysis profiles were visible in sperm extract and seminal plasma after cryopreservation. After freezing-thawing, additional bands appeared in sperm extract and seminal plasma. These bands were of different molecular weight regarding the presence or absence of NPGB. These data suggest that the mechanism of damage to the proacrosin/acrosin system is different for liquid storage and cryopreservation. Liquid storage seems to increase in the susceptibility of the proacrosin/acrosin system to be activated during extraction. Kazal inhibitors of turkey seminal plasma are involved in the control of proacrosin activation. The disturbances of the proacrosin/acrosin system of turkey spermatozoa can be related to a disturbance in the induction of the acrosome reaction. Our results may be important for a better understanding of the proacrosin/acrosin system of turkey spermatozoa and disturbance to this system during liquid storage and cryopreservation.