Heavy meromyosin-binding filaments in the mitotic apparatus of mammaliam cells

Guinea pig spermatozoa fail to fertilize eggs in Ca²⁺-free media primarily because of specific inhibition of the acrosome reaction and activation of the spermatozoa. In Ca²⁺-free media the spermatozoa undergo capacitation at the same rate as in Ca²⁺-containing media, but are arrested in the capacitated state. If Ca²⁺ is made available after the spermatozoa have reached the capacitated state, the spermatozoa immediately undergo the acrosome reaction and activation. The minimum concentration of Ca²⁺ necessary for the initiation of the acrosome reaction and activation is about 0.2 mM. Mg²⁺ cannot substitute for Ca²⁺ in initiating these processes. Possible mechanisms by which Ca²⁺ triggers the acrosome reaction and activation of guinea pig spermatozoa are discussed.     

Effect of Ca2+ channel antagonists on the acrosome reaction of guinea pig and golden hamster spermatozoa

The effects of Ca²⁺ channel antagonists on the motility and acrosome reaction of guinea pig spermatozoa were examined by incubating the spermatozoa continuously in Ca²⁺-containing capacitating media with 10^?6 M to 10^?4 M antagonist. Antagonists tested were four voltage-gated Ca²⁺ channel antagonists (verapamil, nifedipine, nimodipine, and FR–34235) and two ligand-gated channel antagonists (NaNO₂ and Na-nitroprusside). None of these antagonists could block the acrosome reaction. Instead, three antagonists (verapamil, nimodipine, and FR-34235, each at 10^?4 M) accelerated the onset of the acrosome reaction with a subsequent decrease in sperm motility. Nifedipine and Na-nitroprusside at the same concentration caused a complete loss of sperm motility by 4 hr of incubation with no substantial effect on the rate of acrosome reaction. The detrimental effect of antagonists on the motility of spermatozoa appears to be due to a direct, Ca²⁺-independent, membrane-perturbing action of the reagents. The acrosome reaction was not inhibited when guinea pig spermatozoa were precapacitated in Ca²⁺-free medium (with a low concentration of lysolecithin) in the continuous presence of antagonists. An acceleration of the onset of the acrosome reaction by verapamil (10^?4 M) was also demonstrated in the golden hamster. These results may be interpreted as indicating that the entry of extracellular Ca²⁺ into spermatozoa, which triggers the acrosome reaction of guinea pig and hamster spermatozoa, is not mediated by Ca²⁺ channels. This is in marked contrast with the case reported in invertebrate spermatozoa. Possible mechanisms by which some of the antagonists stimulate the acrosome reaction and affect the motility of mammalian spermatozoa are discussed.     

Induction of the acrosome reaction in guinea pig spermatozoa by calmodulin antagonist W-7

The effect of the calmodulin antagonist W-7 on the capacitation and the acrosome reaction of guinea pig spermatozoa was examined. The characteristic features of the acrosome reaction induced by W-7 were the dependence on the composition and pH of the medium and on the presence of sodium bicarbonate. The most effective concentration of W-7 for inducing the acrosome reaction was approximately 5 μM, which is far less than the Kd for calmodulin. Moreover, W-7 enhanced the ability of spermatozoa to acquire capacitation in a Ca²⁺-free medium. The spermatozoa induced to undergo the acrosome reaction by W-7 were capable of penetrating the zona-free hamster eggs. W-5, which has a lower affinity for calmodulin than W-7, also induced the acrosome reaction in the same manner as W-7. These results suggest that the naphthalenesulfonamide derivatives W-7 and W-5 can induce the acrosome reaction in guinea pig spermatozoa via capacitation in a pH-dependent, Ca²⁺-calmodulin-independent manner.     

Signal transduction pathways in guinea pig sperm

Trifluoperazine (TFP), the antagonist of calmodulin (CaM). significantly stimulated the capacitation and acrosome reaction of guinea pig spermatozoa at the concentration of 10-100μmol/L, independent of the external Ca2+. Forskolin, dbcAMP and caffeine evidently promoted the occurrence of acrosome reaction of spermatozoa at early capacitation stage (5 h) in nonsynchronous system but not in synchronous system. If the spermatozoa were capacitated for 15 h in synchronous system, the above three drugs significantly stimulated acrosome reaction in a Ca2+-independent manner. Protein kinase C activators, i.e. phorbol 12-myristate 13-acetate (PMA) and phorbol 12,13-dibutyrate (PDB) did not influence the occurrence of acrosome reaction of spermatozoa at early capacitation stage, but significantly increased the acrosome reaction rate in capacitated spermatozoa in a Ca2+-independent manner. In contrast. PKC inhibitor staurosporine significantly inhibited the occurrence of acrosome reaction.     

Promotion of capacitation of guinea pig spermatozoa by the membrane mobility agent,A2C,and inhibition by the disulfide-reducing agent,DTT

The membrane mobility agent A₂C accelerates the onset of the acrosome reaction of guinea pig spermatozoa by promoting capacitation. Spermatozoa incubated in a suspension of A₂C particles in Ca²⁺-free medium for one hour undergo a synchronous, rapid acrosome reaction upon the addition of Ca²⁺. These acrosome-reacted spermatozoa are capable of fertilization as assessed by their ability to penetrate (fuse with) zona-free hamster eggs. The disulfide-reducing agent, dithiothreitol (DTT) inhibits A₂C-mediated capacitation. It also blocks fertilization of zone-free eggs by acrosome-reacted spermatozoa by preventing attachment of the spermatozoa to the egg plasma membrane. The mode of A₂C action on spermatozoa is compared to that of A₂C-induced fusion in somatic cells. The similarity of the molecular events in the sperm membrane during capacitation and the acrosome reaction to these in other fusion events is pointed out. Inhibition of capacitation by DTT points to the importance of membrane and/or submembrane proteins and thiol groups in this process. Oxidation of sperm membrane SH groups may play an important role in in vivo capacitation.     

A further study of lysolecithin−mediated acrosome rection of guinea pig spermatozoa

When guinea pig spermatozoa are preincubated for 1 hr in Ca²⁺?free medium containing a low concentration of lysolecithin (LC, 85 μg/ml) and then exposed to 2 mM Ca²⁺ by diluting the preincubation medium with an equal volume of LC?free, 4 mM Ca²⁺?containing medium, the majority of the spermatozoa undergo acrosome reaction promptly. On the other hand, when the preincubated spermatozoa are exposed to 2 mM Ca²⁺ without reducing the original concentration of LC in the medium, none of them undergo acrosome reaction. These spermatoza can acrosome?react if they are transferred to an LC?free medium. These results and those of some other experiments suggest that in the presistent presence of a high concentration of LC in the medium, exogenous Ca²⁺ essential for the acrosome reaction either does not penetrate the sperm plasma membrane or, if it does, it cannot alter the membrane for the acrosome reaction, at least under the experimental conditions employed. Freeze?fracture examination of the sperm plasma membrane has revealed that small areas or patches free of intramembranous paarticles (IMPs) appear in the membrance during sperm preincubation, and these IMP?free areas expand drastically in response to Ca²⁺ when the LC conccentration in the medium is reduced at the time Ca²⁺ is added to the medium. In contrast, IMP?free areas remain unchanged even after exposure of spermatozoa to Ca²⁺ if the concentration of LC remains at its original level of 85 μg/ml.     

Cytochemical localization of membrane-bound Mg2+-dependent ATPase activity in guinea pig sperm head before and during the acrosome reaction

The distribution of ATPase activity in the heads of uncapacitated, capacitated, and acrosome-reacting guinea-pig spermatozoa was examined cytochemically using the Wachstein-Meisel's technique. In uncapacitated spermatozoa, the reaction products of the enzyme activity were localized on both the inner surface of the plasma membrane and the outer surface of the outer acrosomal membrane. The activity was Mg²⁺-dependent and inhibited by both Ca²⁺ and SH-blocking agents. This Mg²⁺-dependent ATPase activity was also demonstrated at the same sites in capacitated spermatozoa, whereas it was completely absent in acrosome-reacting spermatozoa. Although we did not determine the exact time of inactivation of the enzyme, it appeared to occur before the plasma membrane fused with the underlying outer acrosomal membrane. The abrupt loss of the Mg²⁺-dependent ATPase activity in the plasma and outer acrosomal membranes immediately before the onset of the acrosome reaction seems to suggest that inactivation of this enzyme by Ca²⁺ is one of the important biochemical events involved in the acrosome reaction.     

Phospholipid composition of isolated guinea pig sperm outer acrosomal membrane and plasma membrane during capacitation in vitro

After capacitation of guinea pig spermatozoa in vitro, the plasma membrane was mechanically separated from the spermatozoa in the presence or absence of HgCl₂ and subsequently isolated by density gradient centrifugation. Examination of the spermatozoa by electron microscopy after homogenization in the presence of HgCl₂ revealed that plasma membrane was removed only from the acrosomal region and remained predominately intact posterior to the equatorial segment of the sperm head, as well as the midpiece and tail. In comparison, spermatozoa homogenized under similar buffer conditions but in the absence of HgCl₂ lose the large apical segment of the acrosome and the plasma membrane is removed essentially from the entire cell. If spermatozoa were homogenized in the absence of Hg²⁺, analysis of plasma membrane phospholipid composition revealed a complete loss of lysophosphatidylcholine (LPC) from the plasma membrane after incubation of spermatozoa in minimal capacitating medium (MCM-PL) for 2 hours. Under these culture conditions the addition of Ca²⁺ (5 mM) to the capacitated spermatozoa induced approximately 78 ± 5% (n = 3) of the motile spermatozoa to undergo acrosome reactions while still maintaining sperm motility (80 ± 5%) (n = 3). If the spermatozoa were homogenized in the presence of Hg²⁺, a time course study revealed that plasma membrane LPC loss occurred between 60 and 90 minutes of incubation. This complete loss of LPC was evident when approximately half of the capacitated spermatozoa had undergone acrosome reactions. Incubation of the spermatozoa with the metabolic and acrosome reaction inhibitor, 2-deoxyglucose (10 mM) for 2 hours, maintained the plasma membrane phospholipid composition similar to that in the noncapacitated state. These data provide evidence that changes in the plasma membrane phospholipid composition may be associated with guinea pig sperm capacitation.     

Requirement of extracellular calcium ions for various stages of fertilization and fertilization-related phenomena in the hamster

Using a semi-chemically defined medium, the requirement of extracellular Ca²⁺ for survival, capacitation, and acrosome reaction of spermatozoa as well as various stages of fertilization in the hamster was studied. A Ca²⁺-deficient environment is unfavorable for long-term survival of spermatozoa. Sperm capacitation may occur in Ca²⁺-deficient media, but not as efficiently as in normal media. The acrosome reaction definitely requires extracellular Ca²⁺. Other processes or phenomena that require extracellular Ca²⁺ are initiation and maintenance of hyperactivated motility of spermatozoa, penetration of acrosome-reacted spermatozoa into the zona pellucida, fusion of the spermatozoa with eggs, and the development of pronuclear eggs into two-cell embryos. Extracellular Ca²⁺ is apparently unnecessary for the attachment of spermatozoa to the zona and egg surfaces, decondensation of the sperm nucleus, and the development of sperm and egg pronuclei within the egg. These results were compared with data obtained in other species such as the sea urchin, mouse, rat and guinea pig.     

Effects of various lipids on the acrosome reaction and fertilizing capacity of guinea pig spermatozoa with special reference to the possible involvement of lysophospholipids in the acrosome reaction

The effects of lipids on the survival, acrosome reaction, and fertilizing capacity of guinea pig spermatozoa were studied by incubating the spermatozoa in media containing various concentrations of the lipids. Lipids tested were: phosphatidyl-choline (PC), -ethanolamine (PE), -inositol (PI), -serine (PS), sphingomyelin (S), cholesterol (C), lysophosphatidyl-choline (LC), -ethanolamine (LE), -inositol (LI), -serine (LS), and glyceryl monooleate (M). When spermatozoa were incubated in a regular medium (containing 2 mM Ca²⁺) with M, the majority underwent the acrosome reaction within 1 hour. None of the other lipids were as effective as M, and some were totally ineffective under the same conditions. However, when spermatozoa were preincubated in Ca²⁺-free medium containing LC, LE, or LI, they gained the ability to undergo the acrosome reaction. One hour of preincubation in Ca²⁺-free medium with LC, LE, or LI was enough to render the vast majority of spermatozoa capable of undergoing the acrosome reaction in response to Ca²⁺. The optimum concentrations for LC, LE, and LI were approximately 85 μg/ml, 210 μg/ml, and 140 μg/ml, respectively. Spermatozoa that had undergone the acrosome reaction by pretreatment with LC, LE, or LI remained actively motile and were capable of fertilizing eggs. LS was totally ineffective in rendering the spermatozoa capable of undergoing the acrosome reaction, and in fact it inhibited the acrosome reaction by itself and also inhibited the LC-, LE-, or LI-mediated acrosome reaction. LS did not prevent acrosome-reacted spermatozoa from penetrating the zona pellucida, but did prevent sperm-egg fusion. Based on these findings, it is suggested that lysophospholipids are intricately involved in the sperm acrosome reaction and perhaps in sperm-egg fusion.     

Regulation of proacrosin conversion in isolated guinea pig sperm acrosomal apical segments

Following sodium dodecyl sulfate-polyacrylamide gel electrophoresis, proacrosin has been identified in extracts of intact guinea spermatozoa as a major silver staining band which reacted immunologically with antibodies made against purified proacrosin from guinea pig testis. Proacrosin exhibited an approximate Mr of 50,000 and was rapidly converted to an Mr 45,000 protein following induction of the acrosome reaction with 2.0 mM CaCl2 and 1 micrograms/ml A23187. Apical segments isolated at pH 6.0 from guinea pig spermatozoa also contained a major silver staining band of Mr 50,000 which cross-reacted with antibodies to guinea pig testis proacrosin. Subcellular fractionation of spermatozoa indicated that proacrosin remained in the particulate fraction of homogenized spermatozoa and was enriched within the isolated acrosomal apical segment. When apical segments isolated at pH 6.0 were incubated at pH 7.5, proacrosin was rapidly converted to the Mr 45,000 form observed in spermatozoa undergoing the acrosome reaction. The conversion process in isolated apical segments was inhibited by leupeptin and was accelerated in the presence of calcium, magnesium, and manganese. Zinc completely inhibited the conversion of proacrosin to the Mr 45,000 protein. Neither proacrosin nor the Mr 45,000 protein were released into the supernatant fluid during the incubation of apical segments at pH 7.5. Furthermore, the proteins were resistant to solubilization by 150 mM NaCl and 1% Triton X-100 but were solubilized by treatment of apical segments with 1 M NaCl. These results provide evidence as to the identity and subcellular distribution of proacrosin in intact guinea pig sperm prior to zymogen conversion and suggest that isolated apical segments exhibit a subset of the exocytotic reactions leading to completion of the acrosome reaction.     

THE IMPORTANCE OF HYDROLYTIC ENZYMES TO AN EXOCYTOTIC EVENT, THE MAMMALIAN SPERM ACROSOME REACTION

The mammalian sperm acrosome reaction is a unique form of exocytosis, which includes the loss of the involved membranes. Other laboratories have suggested the involvement of hydrolytic enzymes in somatic cell exocytosis and membrane fusion, and in the invertebrate sperm acrosome reaction, but there is no general agreement on such an involvement. Although reference was made to such work in this review, the focus of the review was on the evidence (summarized below) that supports or fails to support the importance of certain hydrolytic enzymes to the mammalian sperm acrosome reaction. Because the events of capacitation, the prerequisite for the mammalian acrosome reaction, and of the acrosome reaction itself are not fully understood or identified, it is not yet always possible to determine whether the role of a particular enzyme is in a very late step of capacitation or part of the acrosome reaction. (1) The results of studies utilizing inhibitors of trypsin-like enzymes suggest that such an enzyme has a role in the membrane events of the golden hamster sperm acrosome reaction. The enzyme involved may be acrosin, but it is possible that some as yet unidentified trypsin-like enzyme on the sperm surface may play a role in addition to or instead of acrosin. Results obtained by others with guinea pig, ram and mouse spermatozoa suggest that a trypsin-like enzyme is not involved in the membrane events of the acrosome reaction, but only in the loss of acrosomal matrix. Such results, which conflict with those of the hamster study, may have been due to species differences or the presence of fusion-promoting phospholipase-A or lipids contaminating the incubation media components, and in one case to the possibly damaging effects of the high level of calcium ionophore used. The role of the trypsin-like enzyme in the membrane events of the hamster sperm acrosome reaction may be to activate a putative prophospholipase and/or to hydrolyse an outer acrosomal or plasma membrane protein, thus promoting fusion. A possible role of the enzyme in the vesiculation step rather than the fusion step of the acrosome reaction cannot be ruled out at present. (2) Experiments utilizing inhibitors of phospholipase-A₂, as well as the fusogenic lysophospholipid and cis-unsaturated fatty acid hydrolysis products that would result from such enzyme activity, suggests that a sperm phospholipase-A₂ is involved in the golden hamster sperm acrosome reaction. Inhibitor and LPC addition studies in guinea pig spermatozoa have led others to the same conclusion. The fact that partially purified serum albumin is important in so many capacitation media may be explained by its contamination with phospholipase-A and/or phospholipids. Serum albumin may also play a role, at least in part, by its removal of inhibitory products released by the action of phospholipase-A₂ in the membrane. The demonstration of phospholipase-A₂ activity associated with the acrosome reaction vesicles and/or the soluble component of the acrosome of hamster spermatozoa, and the fact that exogenous phospholipase A₂ can stimulate acrosome reactions in hamster and guinea pig spermatozoa, also support a role for the sperm enzyme. The actual site or the sites of the enzyme in the sperm head are not yet known. The enzyme may be on the plasma membrane as well as, or instead of, in the acrosomal membranes or matrix. A substrate for the phospholipase may be phosphatidylcholine produced by phospholipid methylation. It is possible that more than one type of ‘fusogen’ is released by phospholipase activity (LPC and/or cis-unsaturated fatty acids, which have different roles in membrane fusion and/or vesiculation. In addition to acting as a potential ‘fusogen’, arachidonic acid released by sperm phospholipase-A₂ probably serves as precursor for cyclo-oxygenase or lipoxygenase pathway metabolites, such as prostaglandins and HETES, which might also play a role in the acrosome reaction. Although much evidence points to a role for phospholipase-A₂, phospholipase-C found in spermatozoa could also have a role in the acrosome reaction, perhaps by stimulating events leading to calcium gating, as suggested for this enzyme in somatic secretory cells. (3) A Mg²⁺-ATPase H⁺-pump is present in the acrosome of the golden hamster spermatozoon. Inhibition of this pump by certain inhibitors of ATPases (but not by those that only inhibit mitochondrial function) leads to an acrosome reaction only in capacitated spermatozoa and only in the presence of external K⁺. The enzyme is also inhibited by low levels of calcium, and such inhibition, combined with increased outer membrane permeability to H⁺ and K⁺, and possibly plasma membrane permeability to H⁺ (perhaps by the formation of channels), may be part of capacitation and/or the acrosome reaction. The pH of the hamster sperm acrosome has been shown to become more alkaline during capacitation, and such a change may result in the activation of hydrolytic enzymes in the acrosome or perhaps in a change in membrane permeability to Ca²⁺. A similar Mg²⁺-ATPase has not been found in isolated boar sperm head membranes. However, that conflicting result could have been due to the use of noncapacitated boar spermatozoa for the preparation of the membranes or to protease modification of the boar sperm enzyme during assay. (4) Inhibition of Na⁺, K⁺-ATPase inhibits the acrosome reaction of golden hamster spermatozoa, and the activity of this enzyme increases relatively early during capacitation. A late influx of K⁺ is important for the acrosome reaction. However, this late influx may not be due to Na⁺, K⁺-ATPase, but instead may be due to a K⁺ permeability increase (possibly via newly formed channels) in the membranes during capacitation. It is suggested in this review that Na⁺, K⁺-ATPase has a role early in capacitation rather than directly in the acrosome reaction (although such a role cannot yet be completely ruled out). One possible role for the enzyme in capacitation might be to stimulate glycolysis (which appears to be essential for capacitation and/or the acrosome reaction of hamster and mouse spermatozoa). The function of the influx of K⁺ just before the acrosome reaction is probably to stimulate, directly or indirectly, the H⁺-efflux required for the increase in intraacrosomal pH occurring during capacitation. Direct stimulation of the acrosome reaction by a change in membrane potential resulting directly from K⁺-influx is not a likely explanation for the hamster results. However, the importance of an earlier membrane potential change, due to increased Na⁺, K⁺-ATPase during capacitation, and/or of later membrane potential changes resulting from the pH change, cannot be ruled out. Although K⁺ is required for the hamster acrosome reaction, other workers have reported that K+ inhibits guinea pig sperm capacitation. However, the experimental procedures used in the guinea pig sperm studies raise some questions about the interpretation of those inhibition results. (5) Ca²⁺-influx is known to be required for the acrosome reaction. Others have suggested that increased Ca²⁺-influx due to inhibition or stimulation of sperm membrane calcium transport ATPases are involved in the acrosome reaction. There is as yet no direct or indirect biochemical evidence that inhibition or stimulation of such enzymatic activity is involved in the acrosome reaction, and further studies are needed on those questions. (6) I suggest that the hydrolytic enzymes important to the hamster sperm acrosome reaction will also prove important for the acrosome reaction of all other eutherian mammals.     

Relationship between plasma membrane Ca2+-ATPase activity and acrosome reaction in guinea pig sperm

The results obtained by biochemical measurement demonstrated for the first time that significant decrease of the plasma membrane Ca²⁺-ATPase activity occurred during capacitation and acrosome reaction of guinea pig sperm. Ethaorynic acid, one kind of Ca²⁺-ATPase antagonists, inhibited the plasma membrane Ca²⁺-ATPase activity, but calmodulin (50μg/mL) and trifluoperazine (200- 500μmol/L) did not, suggesting that calmodulin is not involved in ATP-driven Ca²⁺ efflux from sperm. However, calmodulin is involved in the control of Ca²⁺ influx. TFP, one kind of calmodulin antagonists, accelerated the acrosome reaction and Ca²⁺ uptake into sperm cells significantly. Ca²⁺-ATPase antagonists, quercetin, sodium orthovandate, furosemide and ethacrynic acid promoted the acrosome reaction, but inhibited Ca2+ uptake, which cannot be explained by their inhibitory effects on the plasma membrane Ca²⁺-ATPase activity. It is speculated that this phenomenon might be caused by simultaneous inhibitions of the activities of Ca²⁺-ATPase present in the plasma membrane, the outer acrosome membrane and the outer mitochondrion membrane resulting in Ca²⁺ accumulation in the cytoplasm, which in turn blocks further Ca2+ entry through some negative feedback mechanism(s). The inhibitory effect of Ca²⁺-ATPase antagonist on glycolytic activity may also be the reason for Ca²⁺ accumulation in cytoplasm and inhibition of Ca²⁺ uptake.     

Characterization of two antigenically related integral membrane proteins of the guinea pig sperm periacrosomal plasma membrane

The periacrosomal plasma membrane of mammalian spermatozoa functions both in recognition and in binding of the egg's zona pellucida and in the acrosome reaction. This study characterizes two antigenically related proteins with molecular weights of 35 kD (PM35) and 52 kD (PM52) of the guinea pig sperm periacrosomal plasma membrane. Polyclonal antisera were prepared against electrophoretically purified PM35 or PM52. Each antiserum recognized both the 35-kD and 52-kD polypeptides on Western blots, indicating that they are structurally related. This conclusion was supported by peptide mapping experiments demonstrating comparably sized fragments of both PM35 and PM52. Both PM35 and PM52 behave as integral membrane proteins during phase-separation analysis with Triton X-114. Electron microscopic immunocytochemistry and differential fractionation of sperm membranes established that both PM35 and PM52 are exclusively localized to the periacrosomal plasma membrane. Three different antisera were used for ultrastructural studies, and each specifically bound the cytoplasmic but not the extracellular membrane surface. The electrophoretic mobilities of the PM35 and PM52 polypeptides were unchanged during sperm maturation and during the ionophore-induced acrosome reaction. The localization of PM35 and PM52 suggests a potential role for these integral plasma membrane proteins in signal transduction or membrane fusion events of the acrosome reaction. © 1994 Wiley-Liss, Inc.     

Requirement of monovalent cations in the acrosome reaction of guinea pig spermatozoa

The majority of the spermatozoa precapacitated in Ca²⁺-free medium underwent the acrosome raction rapidly when they were transferred to Ca²⁺-containing medium. The presence of Na⁺ and Ca²⁺ in the medium was essential for the acrosome reaction. The vast majority of spermatozoa failed to undergo the reaction in Ca²⁺ medium lacking monovalent ions, although they remained motile. At the concentration of 140 mM, Na⁺, K⁺, Rb⁺, and Cs⁺ all supported the reaction at the maximum level, but at 50 mM the latter three ions were not as effective as Na⁺. Li⁺ was least effective in supporting the reaction. Virtually no acrosome reactions took place when precapacitated spermatozoa were first exposed to Na⁺ medium (no Ca²⁺) and then to Ca²⁺ medium (no Na⁺). On the other hand, a considerably higher proportion of spermatozoa acrosome reacted when they were exposed to these media in the reverse order. The most efficient acrosome reactions took place when the medium contained both a monovalent ion (Na⁺) and Ca²⁺ simultaneously. Possible mechanisms by which monovalent and divalent cations participate in the acrosome reaction are discussed.     

Dithiothreitol,a disulfide-reducing agent,inhibits capacitation,acrosome reaction,and interaction with eggs by guinea pig spermatozoa

Capacitation of guinea pig spermatozoa in vitro was inhibited by the disulfide-reducing agent dithiothreitol (DTT). Even a brief treatment with DTT inhibited capacitation unless an oxidizing agent (glutathione disulfide) was present in the posttreatment medium. Precapacitated spermatozoa were unable to undergo the acrosome reaction in the presence of DTT, indicating that this reagent also blocks the acrosome reaction. Acrosome-reacted spermatozoa were incapable of attaching to and penetrating the zona pellucida in the presence of DTT. Even when acrosome-reacted spermatozoa were directly brought to the surface of zona-free eggs, they were unable to bind to and fuse with the egg plasma membrane so long as DTT was present in the medium. These observations suggest that the tertiary and quaternary structures of sperm surface proteins regulated by their thioldisulfide status are of critical importance in the physiology and function of spermatozoa preliminary to and in the process of fertilization.     

Mammary gland Ca2+-binding (-dependent) proteins: Identification as calelectrins and calpactin I/p36

Calcium-binding (-dependent) proteins (CBPs) associated with the spreading of mammary epithelial cell cultures have been identified as various calelectrins and calpactins (p36). In immunoblot analysis, the CBPs of 30–36 kD and 68–70 KD variously react with different calelectrin and calpactin I monomer/p36 antisera. The same immunoreactive proteins were shown to be present in virgin mammary glands and collagen gel mouse mammary epithelial cell cultures. The mammary CBPs show extensive immunochemical relatedness; however, they fail to show cross-reaction with antiserum to calpactin II (lipocortin) antiserum. These immunoreactive CBPs comigrate in electrophoresis with ³⁵S-methionine-labeled CBPs isolated from mammary epithelial cell cultures. Unlike calmodulin, the mammary CBPs that correspond to calelectrins and calpactin I monomer/p36 are not stable to thermal denaturation. The mammary CBPs bind to epithelial cell membranes in a Ca²⁺-dependent manner and are differentially released from ruptured cells, compared with calmodulin, suggesting subcellular localization. Phenothiazineagarose and phenylagarose are equivalent in their ability to bind the mammary CBPs. Thus, mammary gland CBPs of 30–36 kD and 68–70 kD have been shown to be related or equivalent to the calelectrins and to calpactin I monomer/p36. Since these proteins are known to bind Ca²⁺, we conclude that the mammary gland CBPs are also Ca²⁺-binding proteins. The mammary gland CBPs are immunologically related and probably represent members of a larger family of related proteins.     

Properties and partial protein sequence of plant annexins

We have examined the characteristics of Ca²⁺-dependent phospholipid-binding proteins (annexins) in maize (Zea mays L.) coleoptiles and tip-growing pollen tubes of Lilium longiflorum. In maize, there are three such proteins, p35, p33, and p23. Partial sequence analysis reveals that peptides from p35 and p33 have identity to members of the annexin family of animal proteins and to annexins from tomato. Interestingly, multiple sequence alignments reveal that the domain responsible for Ca²⁺ binding in animal annexins is not conserved in these plant peptide sequences. Although p33 and p35 share the annexin characteristic of binding to membrane lipid, unlike annexins II and VI they do not associate with detergent-insoluble cytoskeletal proteins or with F-actin from either plants or animals. Immunoblotting with antiserum raised to p33/p35 from maize reveals that cross-reactive polypeptides of 33 to 35 kilodaltons are also present in protein extracts from pollen tubes of L. longiflorum. Immunolocalization at the light microscope level suggests that these proteins are predominantly confined to the nongranular zone at the tube tip, a region rich in secretory vesicles. Our hypothesis that plant annexins mediate exocytotic events is supported by the finding that p23, p33, and p35 bind to these secretory vesicles in a Ca²⁺-dependent manner.     

Functional properties of caltrin proteins from seminal vesicle of the guinea pig.

Caltrin proteins from seminal vesicle content of the guinea pig bind with great specificity to different regions of the spermatozoa. Indirect immunofluorescence studies with polyclonal antibodies showed that caltrin I binds to the head, on the acrosomal cup, while caltrin II binds on the principal tail and the neck. No fluorescence was detected either in the midpiece or in the post-acrosomal area of the head when sperm were exposed to either of the caltrins. Calcium-induced hyaluronidase release, which occurs during the acrosomal reaction, was dramatically inhibited by caltrin I (approximately 85% inhibition). Caltrin II was less effective in preventing the enzyme release (approximately 50% inhibition). Chemical modification of the structure modified the biological activity of the two caltrins. Reduction and carboxymethylation of the cysteine residues diminished the inhibitory activity on 45Ca2+ uptake and reduced the ability of the proteins to react with their antibodies. Removal of the carbohydrate portion by chemical deglycosylation transformed the inhibitor proteins into enhancers of calcium uptake into the spermatozoa. Caltrin proteins from the guinea pig appear to play the same physiological role as bovine caltrin, regulating specifically calcium transport across the spermatozoal membranes related with the acrosome reaction and hyperactivation process. The dual behavior of caltrins to inhibit or enhance Ca2+ uptake enables them to fulfill this function. Nevertheless, molecular mechanisms different from those described for bovine caltrin seem to be involved in the control of the functional activity of the guinea pig caltrins.     

Signal transduction pathways that regulate sperm capacitation and the acrosome reaction

Ejaculated spermatozoa must undergo physiological priming as they traverse the female reproductive tract before they can bind to the egg’s extracellular coat, the zona pellucida (ZP), undergo the acrosome reaction, and fertilize the egg. The preparatory changes are the net result of a series of biochemical and functional modifications collectively referred to as capacitation. Accumulated evidence suggests that the event that initiates capacitation is the efflux of cholesterol from the sperm plasma membrane (PM). The efflux increases permeability and fluidity of the sperm PM and causes influx of Ca²⁺ ions that starts a signaling cascade and result in sperm capacitation. The binding of capacitated spermatozoa to ZP further elevates intrasperm Ca²⁺ and starts a new signaling cascade which open up Ca²⁺ channels in the sperm PM and outer acrosomal membrane (OAM) and cause the sperm to undergo acrosomal exocytosis. The hydrolytic action of the acrosomal enzymes released at the site of sperm-egg (zona) binding, along with the hyperactivated beat pattern of the bound spermatozoon, are important factors in directing the sperm to penetrate the ZP and fertilize the egg. The role of Ca²⁺-signaling in sperm capacitation and induction of the acrosome reaction (acrosomal exocytosis) has been of wide interest. However, the precise mechanism(s) of its action remains elusive. In this article, we intend to highlight data from this and other laboratories on Ca²⁺ signaling cascades that regulate sperm functions.