Changes in calmodulin compartmentalization throughout capacitation and acrosome reaction in guinea pig spermatozoa

Calmodulin has been postulated as a mediator in the calcium-dependent processes that culminate in the acrosome reaction. Changes in calmodulin compartmentalization as a consequence of the increased permeability to extracellular calcium during capacitation and acrosome reaction have been suggested. In the present study the temporal localization of calmodulin in guinea pig spermatozoa was studied during in vitro capacitation and acrosome reaction by indirect immunofluorescence. Capacitation was achieved by incubation in Tyrode medium supplemented with pyruvate, lactate, and glucose in the presence and in the absence of calcium. Acrosome reaction was elicited in three different conditions: 1) by transfer to minimal culture medium containing pyruvate and lactate (MCM-PL) after in vitro capacitation 2) by 0.003% Triton-X 100 treatment, and 3) by A 23187 addition to sperm samples incubated in MCM-PL. During capacitation, calmodulin was observed both in the acrosome and in the flagellum; this localization seemed to be independent of the presence of extracellular calcium and of exogenous substrates. Throughout the acrosome reaction, different stages of calmodulin compartmentalization were observed. It became clustered around the equatorial region just before or a little after the acrosome reaction had occurred. Later, it was observed around the postacrosomal region in the acrosome-reacted sperm. The changes in calmodulin distribution were found to be dependent on the stage in the acrosome reaction.     

Stimulation of hamster sperm capacitation and acrosome reaction in vitro by glucose and lactate and inhibition by the glycolytic inhibitor α-chlorohydrin

Studies were made of the effects of D(+)-glucose, L-lactate and pyruvate on in vitro capacitation and acrosome reactions (AR) of hamster sperm using a more “defined” medium that that used in previous similar studies. In the absence of glucose or lactate, sperm underwent very few AR and activation (whiplash-like motility characteristic of capacitated hamster sperm) was reduced compared to those events in sperm preincubated in the presence of glucose plus lactate plus pyruvate. Glucose and pyruvate supported more AR than glucose alone, but less than glucose, lactate, and pyruvate. The glycolytic inhibitor α-chlorohydrin (10 μm) inhibited AR by 50% and reduced activation by less. When glucose was added to sperm incubated 2 hr with pyruvate and lactate, the number of AR observed after 4 hr was the same as that obtained when glucose was present throughout the incubation. When glucose was added after 3.5 hr, AR were delayed for 1 hr and lower numbers of sperm underwent AR. In the presence of lactate and pyruvate, 0.38 mM glucose was able to support activation and AR as well as 3.24 mM glucose. These results indicate that exogenous glucose and lactate are necessary for in vitro capacitation and AR of hamster sperm; only low levels of exogenous glucose are required; exogenous glucose is not required during the first 2 hr of capacitation; and glycolytic activity is necessary for capacitation and the AR.     

Effects of the purified IGF-I complex on the capacitation and acrosome reaction of rabbit spermatozoa

A protein complex containing IGF-I, purified from rabbit seminal plasma, was used to investigate its effects on the capacitation and acrosome reaction of rabbit spermatozoa. Uncapacitated sperm (Pattern F), capacitated sperm (Pattern B), and acrosome-reacted sperm (Pattern AR) were determined by CTC staining, and the results were validated by PSA-staining. The addition of the IGF-I complex to the capacitative medium directed the spermatozoa to spontaneous acrosome reaction. On the other hand, IGF-I complex, added to capacitated spermatozoa, acted as inducer of the acrosome reaction. Results of IVF experiments showed high rates of fertilization with capacitated spermatozoa, acrosome-reacted by either A23187 or IGF I complex, whereas significantly lower rates were obtained with spermatozoa capacitated in the presence of IGF-I complex.     

Capacitation and acrosome reaction in buffalo bull spermatozoa assessed by chlortetracycline and Pisum sativum agglutinin fluorescence assay

Studies on buffalo sperm capacitation have been limited because of the non-availability of a direct assay system. We describe two methods for detecting the acrosomal status of buffalo spermatozoa, namely chlortetracycline (CTC) fluorescence assay and Pisum sativum agglutinin (FITC-PSA) stain. We also test them under various treatment regimens and simultaneously standardize and calibrate them with transmission electron microscopy. An initial comparison of three physiological media, such as Krebs-Ringer bicarbonate buffer, Tyrode solution and Brackett & Oliphant medium (having different calcium concentrations and osmolality) used for studying the capacitation of buffalo spermatozoa and assessed by CTC, FITC-PSA, Giemsa stain and TEM, revealed Brackett & Oliphant medium to be marginally better than the other two media. When stained with chlortetracycline, three distinct fluorescent patterns were visible in buffalo spermatozoa under capacitating conditions. These were 'F' with fluorescence in the post acrosomal region characteristic of uncapacitated acrosome-intact cells; 'B' with fluorescence on the anterior portion of the sperm head and a dark band in the post-acrosomal region, characteristic of capacitated, acrosome intact cells and 'AR' with a fluorescent band on the posterior portion of the head, characteristic of acrosome-reacted cells. The FITC-PSA intensely labels the acrosomal region of acrosome intact buffalo sperm. Acrosome reacted sperms had diminished acrosomal labelling by both the probes used. Buffalo spermatozoa was not capacitated when calcium was either omitted from the medium or chelated with EGTA. In the presence of Ca2+ ionophore, A23187, 68% at 4 h and 85% at 8 h completed the acrosome reaction. Time course studies revealed a 4 h incubation period at 1.71 mM Ca2+ concentration to be necessary before transformation of 'F' to 'B' cells could take place. Spontaneous acrosome reaction induced at 6 and 8 h incubation of buffalo spermatozoa in KRB medium resulted in conversion of 'B' cells to 'AR' cells while 'F' cells remained unchanged. A simultaneous evaluation of acrosome intact and acrosome-reacted cells using FITC-PSA, Giemsa and TEM gave results similar to examination by CTC stain. Both the assays are rapid, reproducible, reliable and they detect an increase or decrease in physiological acrosome reactions. They thus can be used to study effects of calcium and prove to be good monitoring systems to identify buffalo sperm capacitation and acrosome reaction in individual buffalo bulls for fertility studies.     

Capacitation and the acrosome reaction in squirrel monkey (Saimiri sciureus) spermatozoa evaluated by the chlortetracycline fluorescence assay

Capacitation and the acrosome reaction in squirrel monkey seminal spermatozoa diluted in Tyrode's medium (TALP) and TC-199 were monitored by a chlortetracycline (CTC) fluorescence assay. Four CTC patterns, similar to those found in human sperm, were readily characterized by fluorescent staining on the heads of the spermatozoa. The appearance of the capacitated (CP) pattern was dependent on the concentration of the bovine serum albumin. Acrosomal loss was observed in a maximum of 15% of the sperm in the populations studied here. Calcium ionophore A23187 (5 μM to 20μM) induced acrosomal loss in 60–70% of capacitated spermatozoa. However in freshly ejaculated sperm incubated under capacitating conditions or in spermatozoa incubated in Ca^{+ +}-free medium, A23187 failed to induce acrosomal loss. Furthermore, spermatozoa incubated in the presence of seminal plasma or spermatozoa obtained following a 1-hour “swim-up” procedure showed an identical timecourse of appearance of the CP pattern, indicating the lack of effect of seminal plasma on capacitation in the squirrel monkey.     

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.     

In vitro capacitation of dog spermatozoa as assessed by chlortetracycline staining

We developed an assay for detecting capacitation and acrosome status in dog spermatozoa using chlortetracycline (CTC) as a fluorescent probe. Sperm cells were stained after incubation in modified canine capacitation medium (mCCM). Calcium ionophore A23187 permitted the induction of acrosomal exocytosis of capacitated sperm cells. Spermac staining and transmission electron microscopy were used as control tests to detect acrosome-reacted spermatozoa. Three different patterns of CTC distribution in the spermatozoa were found. These patterns were similar to those observed in other mammalian species. The CTC test was used to monitor the time course of the capacitation process in dogs. It was found that the kinetics of capacitation in canine sperm cells are similar to those observed in other mammals.     

C-kit receptor and its possible function in human spermatozoa

The presence and role of the c-kit proto-oncogene protein was investigated in the mature sperm of the human. A polyclonal antibody against the c-kit peptide was used to perform immunohistochemical (IHC) staining, electron microscopy (EM) studies, and Western blot analysis. The acrosomal region of fresh sperm specifically stained with the antibody. No acrosomal staining or staining limited to the equatorial region was noted in the acrosome-reacted (AR) sperm. EM studies demonstrated immunogold label on the plasma membrane (PM) of the acrosome, and confirmed the lack of binding following the acrosome reaction. A 150 kDa band was detected by Western blot analysis. This protein was released from the sperm surface during sperm capacitation and the acrosome reaction. Antibody against the c-kit receptor significantly inhibited the acrosome reaction and increased sperm agglutination, but did not significantly inhibit sperm motility. These results suggest that the c-kit receptor protein is present in mature human sperm and is released during capacitation and/or the acrosome reaction. The assessment of the c-kit receptor may also be a useful assay for sperm function in male infertility.     

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.     

Estrous sheep serum as a potent agent for ovine IVF: effect on cholesterol efflux from spermatozoa and the acrosome reaction

The aim of the present study was to evaluate the effect of heat-inactivated estrous sheep serum (ESS) on sheep IVF. When the capacitation and the fertilization media contained 20% ESS, a fertilization rate of 85% was achieved. The beneficial effect of ESS on sheep IVF was further demonstrated since the fertilization rate was null when ESS was omitted during sperm capacitation and fertilization. Estrous sheep serum supported both sperm capacitation and fertilization as shown by the results of experiments in which it was omitted during one of these steps: sperm capacitation in serum-free medium resulted in delayed sperm-oocyte penetration, while fertilization in serum-free medium significantly decreased the percentage of fertilized oocytes. To investigate the influence of serum on sperm ability to undergo the acrosome reaction, salt-stored follicular sheep oocytes were inseminated, and the acrosomal status of spermatozoa attached to zonae was examined by electron microscopy after a 4-h period of coincubation. Quantitative analysis on thin sections demonstrated that fewer acrosome-reacted spermatozoa were observed when the capacitation and insemination steps were carried out in DM-H medium without serum than in DM-H-SS supplemented with 20% ESS (0.08, [0; 0.34], (median, range)/100mum zona vs 1.32, [0.90; 2.28]/100mum zona; P < 0.01). Since a higher number of spermatozoa attached to the zona surface in DM-H medium, the proportion of acrosome-reacted spermatozoa was much lower (0.7%, [0%; 2.2%], (median, range) vs 54%, [25%; 100%]; P < 0.01) in the absence of serum. These results indicate that in our IVF system the development of the acrosome reaction depended on serum. Sperm cholesterol efflux during in vitro capacitation was measured on [(3)H] cholesterol labeled spermatozoa resuspended in DM-H or DM-H-SS medium. A time-dependent cholesterol removal was observed in the presence of serum (60 +/- 5%, mean +/- SD, after 5 h), whereas it was limited to 14 +/- 3 % in DM-H medium; hence addition of serum to the capacitation medium efficiently supports cholesterol efflux, which is thought to be a key-event in the capacitation process.     

Changes in the distribution of lectin receptors during capacitation and acrosome reaction in boar spermatozoa

Sperm glycocalyx modifications are known to occur during capacitation and the acrosome reaction (AR). These changes are very important for gamete recognition and fertilization in mammals but are not fully understood. The purpose of this study was to determine the distribution of surface carbohydrates in boar spermatozoa during capacitation and the AR. These processes may be associated with specific changes in the content and distribution of surface carbohydrates. Thirty-nine ejaculates from fertile boars of various breeds were analyzed. N-Acetylglucosamine and sialic acid, mannose and fucose residues were detected by fluorescence microscopy and flow cytometry using FITC-conjugated lectins. Triticum vulgaris agglutinin (WGA) bound on the head and tail of fresh sperm, and fluorescence intensity (FI) decreased in capacitated sperm (6751 to 5621 fluorescence units (FU), P<0.05), and decreased further in acrosome-reacted sperm (5240 FU, P<0.05). Concanavalia ensiformis agglutinin (Con-A) bound homogeneously on the head and the midpiece of fresh sperm with a FI of 5335 FU, and increased in capacitated sperm (5957 FU, P<0.05) mainly on the acrosomal region. In acrosome-reacted sperm, fluorescence was concentrated on the border of the acrosomal region (5608 FU, P<0.05). It was not possible to detect Ulex europaeus agglutinin (UEA) by fluorescence microscopy. However, flow cytometry revealed UEA receptors (187 FU), with a nonsignificant decreased number in capacitated (142 FU) and AR sperm (142 FU). Labeling patterns were similar in all breeds. Sperm glycocalyx modifications observed in this study provide insights to the molecular modifications accompanying capacitation and the AR. This kind of study could improve the diagnosis of reproductive problems of subfertile boars and males of other species.     

Calmodulin signals capacitation and triggers the agonist-induced acrosome reaction in mouse spermatozoa

Capacitated acrosome-intact spermatozoa interact with specific sugar residues on neoglycoproteins (ngps) or solubilized zona pellucida (ZP), the egg's extracellular glycocalyx, prior to the initiation of a signal transduction cascade that results in the fenestration and fusion of the sperm plasma membrane and the outer acrosomal membrane at multiple sites and exocytosis of acrosomal contents (i.e., induction of the acrosome reaction (AR)). The AR releases acrosomal contents at the site of sperm-zona binding and is thought to be a prerequisite event that allows spermatozoa to penetrate the ZP and fertilize the egg. Since Ca(2+)/calmodulin (CaM) plays a significant role in several cell signaling pathways and membrane fusion events, we have used a pharmacological approach to examine the role of CaM, a calcium-binding protein, in sperm capacitation and agonist-induced AR. Inclusion of CaM antagonists (calmodulin binding domain, calmidazolium, compound 48/80, ophiobolin A, W5, W7, and W13), either in in vitro capacitation medium or after sperm capacitation blocked the npg-/ZP-induced AR. Purified CaM largely reversed the AR blocking effects of antagonists during capacitation. Our results demonstrate that CaM plays an important role in priming (i.e., capacitation) of mouse spermatozoa as well as in the agonist-induced AR. These data allow us to propose that CaM regulates these events by modulating sperm membrane component(s).     

Cholesterol efflux promotes acrosome reaction in goat spermatozoa

Cholesterol efflux and membrane destabilization play an important role in sperm capacitation and membrane fusion in the acrosome reaction (AR). In this study we establish the effect of cholesterol removal from spermatozoa on acrosomal responsiveness. Mature goat spermatozoa were incubated in BSA-free medium in the presence of beta-cyclodextrin (betaCD) as cholesterol acceptor. After incubation with 8 mM betaCD, 50-60% of cholesterol was released from sperm membranes with no loss in the phospholipid content, and 35% of AR was induced. However, when 30% of cholesterol was lost, this moderate cholesterol decrease was unable to initiate AR. Cholesterol desorption was very rapid, following an exponential kinetics with a half-time of around 10 min, which is in contrast with the slow sigmoidal kinetics of acrosomal responsiveness: around 2 h was required for maximal AR. Our results suggest that cholesterol efflux has a direct influence on the onset of the AR, that is, merely removing cholesterol would trigger the AR.     

Glucose effect on respiration: possible mechanism for capacitation in guinea pig spermatozoa.

Guinea pig sperm respiration was determined in minimal capacitation medium (MCM) with different energy sources. The ZO2 observed for spermatozoa suspended in media containing pyruvate and lactate was 35.7 +/- 5.9, pyruvate alone, 27.9 +/- 3.8 and D-glucose alone 3.4 +/- 1.1. When D-glucose was added to spermatozoa rapidly respiring in media containing pyruvate as the only exogenous energy source, an immediate suppression in respiration was observed. Further reduction was caused by continued addition of D-glucose. Fructose and mannose also produced a suppression in respiratory rate. However, lactose, fucose, sucrose, L-glucose, and galactose did not alter the respiratory rate. The suppression of respiration by metabolizable sugars is paralleled by a suppression of acrosome reaction in guinea pig spermatozoa. The possibility that suppression of respiration is the mechanism for retardation of capacitation and the subsequent acrosome reaction by D-glucose and other metabolizable sugars is suggested.     

Intracellular signaling cascades induced by relaxin in the stimulation of capacitation and acrosome reaction in fresh and frozen-thawed bovine spermatozoa

Relaxin is one of the 6-kDa peptide hormones, which acts as a pleiotropic endocrine and paracrine factor. Our previous studies revealed that sperm capacitating medium containing relaxin induced capacitation and acrosome reaction (AR) in fresh and frozen-thawed porcine or bovine spermatozoa. However, the intracellular signaling cascades involved with capacitation or AR induced by relaxin was unknown. Therefore, the present study was designed to investigate the intracellular signaling cascades involved with capacitation and AR induced by relaxin in fresh and frozen-thawed bovine spermatozoa. Spermatozoa were incubated in sperm Tyrode's albumin lactate pyruvate (Sp-TALP) medium supplemented with (40 ng ml(-1)) or without relaxin, and subjected to evaluation of chlortetracycline staining pattern, cholesterol efflux, Ca(2+)-influx, intracellular cyclic adenosine monophosphate (cAMP) and protein tyrosine phosphorylation. Capacitation and AR were increased (P<0.05) in both fresh and frozen-thawed spermatozoa incubated with relaxin. Cholesterol effluxes were greater in the fresh (P<0.01) and frozen-thawed (P<0.05) spermatozoa incubated with relaxin than the spermatozoa incubated without relaxin. Ca(2+)-influxes were also significantly stimulated by relaxin in the fresh (P<0.01) and frozen-thawed (P<0.05) spermatozoa. The Sp-TALP medium containing relaxin influenced the generation of intracellular cAMP in the fresh (P<0.01) and frozen-thawed (P<0.05) spermatozoa, and exhibited higher exposure of protein tyrosine phosphorylation in both sperm types than the medium devoid of relaxin. Therefore, the results postulate that relaxin exerts the intracellular signaling cascades involved with capacitation and AR through accelerating the cholesterol efflux, Ca(2+)-influx, intracellular cAMP and protein tyrosine phosphorylation in fresh and frozen-thawed bovine spermatozoa.     

Influence of a capacitation period on human sperm acrosome loss.

The present study investigates whether a 5 hour capacitation period modifies the ability of human spermatozoa to undergo induced acrosomal loss. Human sperm acrosomal loss was induced by treatment with either the calcium ionophore A23187, low concentrations of the phospholipid dilauroylphosphatidylcholine (PC12), or 2 hours incubation in conditioned medium prepared from human cumulus cells (CM/CC). The use of a dual staining method (FITC-ConA and Hoechst 33258) for simultaneous assessment of acrosomal status and viability demonstrated that induction of acrosomal loss with calcium ionophore was not dependent on a capacitation period. A short (5 hour) incubation period was not sufficient to induce acrosomal loss with CM/CC above spontaneous acrosome reaction rates in medium alone. A significant capacitation-dependent increase (P < 0.05) in acrosomal loss was observed when human spermatozoa were incubated with PC12. Induction of acrosomal loss of capacitated human spermatozoa with PC12 therefore provides a simple assay for the simultaneous assessment of human sperm capacitation and the acrosome reaction in vitro.     

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.     

Release of acrosomal enzymes following in vitro capacitation of ejaculated rabbit spermatozoa

Significant release of the acrosomal enzymes arylsulfatase, β-N-acetylhexosaminidase and hyaluronidase was observed following the treatment of ejaculated rabbit spermatozoa for 12 hours in 20% rabbit serum for inducing in vitro capacitation, and these sperm were capable of in vivo fertilization; however, the treatment of sperm for 15 minutes in high ionic strength (380 mOsm/kg) or low ionic strength medium (305 mOsm/kg) for in vitro capacitation did not result in any significant release of the above enzymes nor were the sperm capable of in vivo fertilization. Serum-treated spermatozoa remained significantly motile following the 12 hour treatment, 51% underwent the acrosome reaction and were capable of fertilizing 66% of the ova in vivo. Identical serum treatment of lysosomes from rabbit liver resulted in a comparable release of the lysosomal enzymes. Serum treatment for in vitro capacitation resulted in vesiculation of the anterior margin of half the spermatozoa, but left their inner acrosomal membranes and equatorial segments intact. A biochemical relationship between the release of acrosomal enzymes and capacitation is suggested.     

Surface alterations during the capacitation of mammalian spermatozoa

Capacitation is the process by which mammalian sperm acquire the ability to undergo the acrosome reaction which, in turn, is a prerequisite for sperm-egg fusion and penetration. Until recently, it was thought that capacitation involved subtle physiological and chemical changes which had no morphological counterparts even at the electron microscopic level. However, it has now been shown by a number of investigators that material associated with the plasma membrane surface is either lost or extensively redistributed during in vitro or in vivo capacitation. We have made use of lectins and antibodies as probes of the sperm surface during capacitation and the acrosome reaction. Concanavalin A (Con A), wheat germ agglutinin (WGA) and soybean agglutinin (SBA) have been used in conjunction with fluorescent tags (FITC) and ultrastructural markers (ferritin, hemocyanin) to study the surface of golden hamster, guinea pig, mouse and human spermatozoa. Con A and WGA label the plasma membrane overlying the acrosomal region quite uniformly on these species. After capacitation there is a specific loss (or masking) of lectin binding sites over the acrosomal region of the sperm head in all species examined. Antibodies prepared against sperm and specific antibodies to a cell surface protein (fibronectin) were also tagged with fluorescent or ultrastructural markers and used to label the surfaces of sperm before and after capacitation. These probes also indicate a specific loss of surface associated material over the acrosomal surface after capacitation. These results are consistent with the notion that there is a general removal of surface components during capacitation and that this denuding of the surface is a prerequisite for the following membrane fusion events involved in the acrosome reaction and sperm-egg fusion.     

Effect of heparin on in vitro capacitation of boar sperm

Chlortetracycline (CTC) fluorescent pattern, the ability to undergo acrosome reaction (AR) upon exposure to 10 microM calcium ionophore A23187 and vitality estimation were used to investigate the effect of the sulfated glycosaminoglycan heparin on the in vitro capacitation of porcine spermatozoa. Sperm incubation in capacitating medium (CM) supplemented with 10 mM heparin for up to 120 min, showed an increase in the number of capacitated sperm (B pattern) and acrosome reacted sperm (AR pattern), without affecting their viability. In this condition, spermatozoa were incubated in CM depleted of albumin, calcium, bicarbonate or combinations, in the presence of heparin. In either calcium or bicarbonate-free media, capacitation was only basal and did not show variations in the presence of heparin. In absence of albumin the presence of calcium and bicarbonate stimulated capacitation, which was further increased by the addition of heparin. These results suggest that heparin enhances in vitro capacitation of porcine sperm only under capacitating conditions. Additionally, when sperm were incubated with 100 microg/ml biotinylated heparin in the presence or absence of unlabeled heparin, we observed that heparin binding sites were located mostly on the acrosomal region of boar sperm in an specific and saturable manner. The in vitro effect of heparin described in this work indicates that sulfated glycosaminoglycans, which are normally present in the female reproductive tract, might play an important role in the fertilization process in porcines.