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.     

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).     

Is sperm capacitation analogous to early phases of Ca2+‐triggered membrane fusion in somatic cells and viruses?

An important feature of male fertility is the physiological priming of spermatozoa by a multifaceted process collectively referred to as capacitation. The end point of this evasive process is the hyperactivated spermatozoa capable of binding to terminal sugar residues on the egg's extracellular coat, the zona pellucida (ZP), and undergoing acrosomal exocytosis (i.e., induction of the acrosome reaction). The hydrolytic action of acrosomal enzymes released at the site of zona binding, along with the enhanced thrust generated by the hyperactivated beat pattern of the bound spermatozoa, are important factors that regulate the penetration of ZP and fertilization of the egg. Despite many advances in identifying sperm components that promote capacitation, the mechanism underlying the calcium-triggered process remains elusive. The purpose of this review article is to focus on new advances that have enhanced our understanding of in vivo/in vitro capacitation, a prerequisite event resulting from a dramatic modification and reorganization of the sperm membrane molecules. Special emphasis has been laid on accumulating evidence suggesting potential similarities between the sperm capacitation and early phases of calcium-triggered membrane fusion (i.e., tethering and docking) during secretory and endocytotic pathways among eukaryotes.     

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.     

The role of F-actin cytoskeleton-associated gelsolin in the guinea pig capacitation and acrosome reaction

The acrosomal reaction (AR) is a regulated sperm exocytotic process that involves fusion of the plasma membrane (PM) with the outer acrosomal membrane (OAM). Our group has described F-actin cytoskeletons associated to these membranes. It has been proposed that in regulated exocytosis, a cortical cytoskeleton acts as a barrier that obstructs membrane fusion, and must be disassembled for exocytosis to occur. Actin-severing proteins from the gelsolin family have been considered to break this barrier. The present study attempted to determine if gelsolin has a function in guinea pig sperm capacitation and AR. By indirect immunofluorescence (IIF), gelsolin was detected in the apical and postacrosomal regions of the head and in the flagellum in both capacitated and non-capacitated guinea pig spermatozoa. By Western blotting, gelsolin was detected in isolated PM and OAM of non-capacitated spermatozoa. Gelsolin and actin were detected in a mixture of PM-OAM obtained by sonication, and both proteins were absent in membranes of capacitated spermatozoa. Inhibition of three different pathways of PIP2 hydrolysis during capacitation did not cancel gelsolin loss from membranes. Gelsolin was detected by Western blotting associated to membrane cytoskeletons obtained after phalloidin F-actin stabilization and Triton-X treatment; additionally, by immunoprecipitation, it was shown that gelsolin is associated with actin. By electron microscopy we observed that skeletons disassemble during capacitation, but phalloidin prevents disassembly. A three-dimensional skeleton was observed that apparently joins PM with OAM. Exogenous gelsolin stimulates AR assayed in a permeabilized spermatozoa model. Results suggest that gelsolin disassembles F-actin cytoskeletons during capacitation, promoting AR.     

VLA-6 integrin distribution and calcium signalling in capacitated boar sperm.

Previous investigations showed that VLA-6 integrin present on boar sperm membrane can induce acrosome reaction upon exposure to laminin accumulated in expanded cumuli (Mattioli et al., 1998. To further investigate this novel sperm egg-recognition system, the authors studied the distribution of VLA-6 integrin on the membrane of boar sperm throughout capacitation and following acrosome reaction, and analyzed intracellular Ca(2+) changes occurring in spermatozoa exposed to laminin. Immunofluorescent localisation of VLA-6 revealed a low proportion (nearly 22%) of positive cells in freshly ejaculated sperm, with integrin mainly concentrated in clustered spots. After 3 hr incubation most of the spermatozoa showed integrin molecules on the membrane, with three different labeling patterns: fluorescence localised on the edge of the acrosome (58.2 +/- 14.2% of the cells); fluorescence uniformly spread over the whole sperm head (5.0 +/- 1.9%) and finally fluorescence concentrated in clustered spots (7.6 +/- 5.6%), as recorded in freshly ejaculated sperm. Twenty-nine percent of cells did not show any distinct fluorescence. Following acrosome reaction sperm with fluorescence on the acrosomal region virtually disappeared and the proportion of unstained cells rose from 29.2 +/- 9.2 to 69.0 +/- 10.1%. Electron microscopy demonstrated that VLA-6 integrin was exclusively located on the sperm membrane of intact spermatozoa. Confocal analysis showed that laminin triggers distinct Ca(2+) raises, and that sperm exposed and kept in the presence of laminin fully retained their ability to rise intracellular Ca(2+) in response to zona pellucida proteins. These data indicate that boar sperm accumulate VLA-6 integrin on the membrane and concentrate it on the acrosomal region as capacitation progresses. Probably due to this compartmentalisation, sperm exposed to laminin experience a Ca(2+) raise that originates in the anterior sperm head where it is more adequate for the induction of acrosome reaction. Mol. Reprod. Dev. 59:322-329, 2001.     

Intracellular Ca(2+)-Mg(2+)-ATPase regulates calcium influx and acrosomal exocytosis in bull and ram spermatozoa.

Calcium influx is required for the mammalian sperm acrosome reaction (AR), an exocytotic event occurring in the sperm head prior to fertilization. We show here that thapsigargin, a highly specific inhibitor of the microsomal Ca(2+)-Mg(2+)-ATPase (Ca(2+) pump), can initiate acrosomal exocytosis in capacitated bovine and ram spermatozoa. Initiation of acrosomal exocytosis by thapsigargin requires an influx of Ca(2+), since incubation of cells in the absence of added Ca(2+) or in the presence of the calcium channel blocker, La(3+), completely inhibited thapsigargin-induced acrosomal exocytosis. ATP-Dependent calcium accumulation into nonmitochondrial stores was detected in permeabilized sperm in the presence of ATP and mitochondrial uncoupler. This activity was inhibited by thapsigargin. Thapsigargin elevated the intracellular Ca(2+) concentration ([Ca(2+)](i)), and this increase was inhibited when extracellular Ca(2+) was chelated by EGTA, indicating that this rise in Ca(2+) is derived from the external medium. This rise of [Ca(2+)](i) took place first in the head and later in the midpiece of the spermatozoon. However, immunostaining using a polyclonal antibody directed against the purified inositol 1,4,5-tris-phosphate receptor (IP(3)-R) identified specific staining in the acrosome region, in the postacrosome, and along the tail, but not in the midpiece region. No staining in the acrosome region was observed in sperm without acrosome, indicating that the acrosome cap was stained in intact sperm. The presence of IP(3)-R in the anterior acrosomal region as well as the induction, by thapsigargin, of intracellular Ca(2+) elevation in the acrosomal region and acrosomal exocytosis, implicates the acrosome as a potential cellular Ca(2+) store. We suggest here that the cytosolic Ca(2+) is actively transported into the acrosome by an ATP-dependent, thapsigargin-sensitive Ca(2+) pump and that the accumulated Ca(2+) is released from the acrosome via an IP(3)-gated calcium channel. The ability of thapsigargin to increase [Ca(2+)](i) could be due to depletion of Ca(2+) in the acrosome, resulting in the opening of a capacitative calcium entry channel in the plasma membrane. The effect of thapsigargin on elevated [Ca(2+)](i) in capacitated cells was 2-fold higher than that in noncapacitated sperm, suggesting that the intracellular Ca pump is active during capacitation and that this pump may have a role in regulating [Ca(2+)](i) during capacitation and the AR.     

Acrosomal enzymes of human spermatozoa before and after in vitro capacitation

The effect of in vitro capacitation (events that occur before the acrosome reaction) on the acrosomal enzymes of human spermatozoa was determined. Capacitation of human spermatozoa was assessed by their ability to penetrate denuded hamster oocytes. The activities of a number of enzymes commonly associated with the sperm acrosome, including nonzymogen acrosin, proacrosin, inhibitor-bound acrosin, hyaluronidase, acid phosphatase, beta-glucuronidase, beta-glucosidase, beta-N-acetylglucosaminidase, beta-galactosidase and beta-N-acetylgalactosaminidase were assessed. With the exception of acid phosphatase, no alteration in enzyme activity occurred after 4 h of incubating the spermatozoa under capacitation conditions although gamete fusion took place. The acid phosphatase levels decreased twofold, presumably due to the loss of seminal (prostatic acid phosphatase that loosely adheres to spermatozoa. After 8 h of capacitation, a large decrease in sperm enzyme levels took place only in the case of hyaluronidase, although small decreases were also noted in total acrosin, proacrosin and inhibited acrosin. No new electrophoretically migrating forms of acrosin were observed. Decreases in total acrosin and proacrosin, but not in inhibited acrosin, also occurred when spermatozoa were incubated under noncapacitating conditions for 8 h, indicating that capacitation may specifically cause the release of some acrosin inhibitor from human spermatozoa. It is concluded that, with the possible exception of hyaluronidase, the in vitro capacitation of human spermatozoa does not cause a major change in its acrosomal enzyme content so that these hydrolases are fully present before the acrosome reaction takes place during gamete fusion. Serum albumin appears to protect against the loss of some of these enzymes since the activity of several glycosidases was significantly reduced when the spermatozoa were incubated for 8 h in human serum albumin-free medium.     

The Biological and Functional Significance of the Sperm Acrosome and Acrosomal Enzymes in Mammalian Fertilization

The mammalian spermatozoon undergoes continuous modifications during spermatogenesis, maturation in the epididymis, and capacitation in the female reproductive tract. Only the capacitated spermatozoa are capable of binding the zona-intact egg and undergoing the acrosome reaction. The fertilization process is a net result of multiple molecular events which enable ejaculated spermatozoa to recognize and bind to the egg's extracellular coat, the zona pellucida (ZP). Sperm–egg interaction is a species-specific event which is initiated by the recognition and binding of complementary molecule(s) present on sperm plasma membrane (receptor) and the surface of the ZP (ligand). This is a carbohydrate-mediated event which initiates a signal transduction cascade resulting in the exocytosis of acrosomal contents. This step is believed to be a prerequisite which enables the acrosome reacted spermatozoa to penetrate the ZP and fertilize the egg. This review focuses on the formation and contents of the sperm acrosome as well as the mechanisms underlying the induction of the acrosome reaction. Special emphasis has been laid on the synthesis, processing, substrate specificity, and mechanism of action of the acid glycohydrolases present within the acrosome. The hydrolytic action of glycohydrolases and proteases released at the site of sperm-zona binding, along with the enhanced thrust generated by the hyperactivated beat pattern of the bound spermatozoon, are important factors regulating the penetration of ZP. We have discussed the most recent studies which have attempted to explain signal transduction pathways leading to the acrosomal exocytosis.     

Acrosome reaction in spermatozoa from hagfish (Agnatha) Eptatretus burgeri and Eptatretus stouti: acrosomal exocytosis and identification of filamentous actin

Spermatozoa of the hagfishes Eptatretus burgeri and Eptatretus stouti, caught in the sea near Japan and North America, respectively, were found to undergo the acrosome reaction, which resulted in the formation of an acrosomal process with a filamentous core. The acrosomal region of spermatozoa of E. stouti exhibited immunofluorescent labeling using an actin antibody. The midpiece also labeled with the antibody. The acrosomal region showed a similar labeling pattern when sperm were probed with tetramethylrhodamine isothyocyanate (TRITC)-phalloidin; the midpiece did not label. Following induction of the acrosome reaction with the calcium (Ca2+) ionophore ionomycin, TRITC-phalloidin labeling was more intense in the acrosomal region, suggesting that the polymerization of actin occurs during formation of the acrosomal process, as seen in many invertebrates. The potential for sperm to undergo acrosomal exocytosis was already acquired by late spermatids. During acrosomal exocytosis, the outer acrosomal membrane and the overlying plasma membrane disappeared and were replaced by an array of vesicles; these resembled an early stage of the acrosome reaction in spermatozoa of higher vertebrates in which no formation of an acrosomal process occurs. It is phylogenetically interesting that such phenomena occur in spermatozoa of hagfish, a primitive vertebrate positioning between invertebrates and high vertebrates.     

Sperm surface changes during the acrosome reaction as observed by freeze-fracture

The mammalian acrosome reaction is an exocytotic process that can be analyzed by the technique of freeze-fracture; only sperm cells capacitated in vitro or treated to elicit the acrosome reaction in vitro have been studied, and all pictures published are from material fixed before freezing. All the authors point out the appearance of particle-free areas in the plasma membrane of the acrosomal region during capacitation and before any fusion. This is interpreted as an increase in membrane fluidity as suggested by studies on membrane lipid composition in guinea-pig sperm. We have recently described the induced acrosome reaction in ram spermatozoa. Fusion starts at the limit of the anterior and equatorial segments and progresses forward in the anterior segment along ramified paths, resulting in a fenestration gradient of the acrosomal cap. Fusion propagation may be controlled by fluidity increase in the plasma membrane of the anterior segment, and it is probably inhibited in the equatorial segment by the ordered structure of the acrosomal membrane.     

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.     

大熊猫精子获能和顶体反应过程中钙分布变化规律的研究

应用焦锑酸钾原位定位法对大熊猫精子获能和顶体反应过程中进行钙定位研究,发现未获能精子的 Ｃａ２＋主要结合于顶体前区和赤道段质膜外侧和顶体内膜内侧（核膜侧）;随着获能的进行,Ｃａ２＋进入精子内部并主要结合于顶体区质膜内侧和顶体外膜外侧;顶体反应的精子,Ｃａ２＋结合于顶体内膜外侧、顶体后区质膜外侧和分散存在于释放的顶体内容物中,有些顶体反应精子的顶体内膜外侧结合的Ｃａ２＋特别丰富。精子尾部的Ｃａ２＋主要分布于中段线粒体内,且其内所含Ｃａ２＋含量随着获能和顶体反应而增加。另外尾部致密纤维和轴丝处也有少量Ｃａ２＋分布。     

Specific labelling by peanut agglutinin of the outer acrosomal membrane of the human spermatozoon

Experiments to bind fluorescein-conjugated Arachis hypogea (peanut) agglutinin (FITC-PNA) to washed human spermatozoa demonstrated that this lectin binds to the acrosome region in air-dried preparations. Since there was no binding when labelling was performed in suspension, and comparable labelling to that seen in air-dried preparations was seen when spermatozoa treated with saponin (to lyse the plasma membrane) were labelled in suspension, the lectin must bind to an intracellular structure, probably the outer acrosomal membrane. This was confirmed by ultrastructural localization of colloidal gold-conjugated lectin in saponin-treated spermatozoa. Treatment of spermatozoa with the detergent Nonidet P-40 caused a marked change in the binding pattern: more spermatozoa showed binding in the equatorial segment of the acrosome with no binding in the anterior cap region. A comparable, less marked, change was seen when spermatozoa were incubated overnight under conditions known to support the capacitation and spontaneous acrosome reactions. Treatment with the calcium ionophore A23187 for 1 h to induce acrosome reactions artificially in uncapacitated spermatozoa resulted in the appearance of patchy acrosome fluorescence. From these experiments it is concluded that PNA binds specifically to the outer acrosomal membrane, and that FITC-PNA-labelling may be used to monitor the human sperm acrosome reaction.     

Assessment of acrosomal status in rat spermatozoa: studies on carbohydrate and non-carbohydrate agonists

In the mouse and several other species, including man, capacitated acrosome-intact spermatozoa interact with natural [soluble zona pellucida (ZP) and progesterone (P4)] and synthetic [neoglycoproteins (ngps) and calcium (Ca(2+)) ionophore] agonists, prior to the initiation of a Ca(2+)-dependent signal transduction cascade. The net result is the fusion of the sperm plasma membrane overlying the outer acrosomal membrane at multiple sites and exocytosis of acrosomal contents [i.e., induction of the acrosome reaction (AR)]. This step is believed to be a prerequisite that enables the acrosome-reacted spermatozoon to penetrate the ZP and fertilize the egg. Although the rat is one of the most commonly used laboratory animals, very little is known about the chemical nature of agonists that induce the AR in this species. The lack of this information is primarily due to the fact that the rat sperm acrosome is a relatively thin structure. Thus, it is difficult to assess the status of the sperm acrosome in this species. In this report, we describe the use of a Coomassie brilliant blue dye staining procedure to assess the status of the rat sperm acrosome by light microscopy. The procedure is highly reproducible and has allowed us to determine the effects of carbohydrate (ngps and mouse ZP) and noncarbohydrate (P4 and Ca(2+) ionophore) agonists on capacitated spermatozoa. In addition, we have used a pharmacological approach to examine the functional significance of calmodulin (CaM), a Ca(2+)-binding protein, in induction of the AR in spermatozoa. Data presented in this report demonstrate that several ngps, solubilized mZP, P4, and Ca(2+) ionophores induce the AR in rat spermatozoa. Furthermore, we demonstrate that, whereas CaM antagonists blocked P4-induced AR, most of the inhibitors used had no significant effect on the Ca(2+) ionophore-induced (nonphysiological) AR.     

The Multi-PDZ domain protein MUPP1 as a lipid raft-associated scaffolding protein controlling the acrosome reaction in mammalian spermatozoa

The success of acrosomal exocytosis, a complex process with a variety of interrelated steps, relies on the coordinated interaction of participating signaling molecules. Since scaffolding proteins are known to spatially organize sequential signaling pathways, we examined whether the Multi-PDZ domain protein MUPP1, recently identified in mammalian spermatozoa, is functionally active in controlling acrosomal secretion in mammalian sperm cells. To address this question, permeabilized mouse sperm were loaded with inhibitory antibodies against MUPP1 as well as with a photosensitive Ca(2+) chelator which allows a controlled release of acrosomal Ca(2+). The results revealed that MUPP1 controls initial tethering and docking of the acrosomal vesicle, whereas syntaxin 2, a t-SNARE protein also expressed in the acrosomal cap of mammalian spermatozoa, appears to take part in the final process of acrosomal fusion. Interestingly, using immunogold electron microscopy, it was found that MUPP1 is detectable in the region of the periacrosomal membrane. Furthermore, in isolated detergent-insoluble glycolipid-enriched membrane domains from epididymal spermatozoa, MUPP1 was found to show a striking association with the Triton X-100 insoluble membrane fraction, which did not change significantly upon sperm capacitation or partial chemical extraction of cholesterol. This evidence points to a role of MUPP1 as a membrane raft-associated molecular organizer, and suggests that mammalian spermatozoa may use a scaffolding protein and distinct membrane subdomains to spatially organize components involved in the process of acrosomal exocytosis.     

The use of anti-VDAC2 antibody for the combined assessment of human sperm acrosome integrity and ionophore A23187-induced acrosome reaction

Voltage-dependent anion channel (VDAC) is mainly located in the mitochondrial outer membrane and participates in many biological processes. In mammals, three VDAC subtypes (VDAC1, 2 and 3) have been identified. Although VDAC has been extensively studied in various tissues and cells, there is little knowledge about the distribution and function of VDAC in male mammalian reproductive system. Several studies have demonstrated that VDAC exists in mammalian spermatozoa and is implicated in spermatogenesis, sperm maturation, motility and fertilization. However, there is no knowledge about the respective localization and function of three VDAC subtypes in human spermatozoa. In this study, we focused on the presence of VDAC2 in human spermatozoa and its possible role in the acrosomal integrity and acrosome reaction using specific anti-VDAC2 monoclonal antibody for the first time. The results exhibited that native VDAC2 existed in the membrane components of human spermatozoa. The co-incubation of spermatozoa with anti-VDAC2 antibody did not affect the acrosomal integrity and acrosome reaction, but inhibited ionophore A23187-induced intracellular Ca(2+) increase. Our study suggested that VDAC2 was located in the acrosomal membrane or plasma membrane of human spermatozoa, and played putative roles in sperm functions through mediating Ca(2+) transmembrane transport.     

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.     

Elucidation of the involvement of p14, a sperm protein during maturation, capacitation and acrosome reaction of caprine spermatozoa

Mammalian sperm capacitation is an essential prerequisite to fertilization. Although progress is being made in understanding the physiology and biochemistry of capacitation, little has been yet explored about the potential role(s) of individual sperm cell protein during this process. Therefore elucidation of the role of different sperm proteins in the process of capacitation might be of great importance to understand the process of fertilization. The present work describes the partial characterization of a 14-kDa protein (p14) detected in goat spermatozoa using an antibody directed against the purified protein. Confocal microscopic analysis reveals that the protein is present in both the intracellular and extracellular regions of the acrosomal and postacrosomal portion of caudal sperm head. Though subcellular localization shows that p14 is mainly cytosolic, however it is also seen to be present in peripheral plasma membrane and soluble part of acrosome. Immuno-localization experiment shows change in the distribution pattern of this protein upon induction of capacitation in sperm cells. Increased immunolabeling in the anterior head region of live spermatozoa is also observed when these cells are incubated under capacitating conditions, whereas most sperm cells challenged with the calcium ionophore A23187 to acrosome react, lose their labeling almost completely. Intracellular distribution of p14 also changes significantly during acrosome reaction. Interestingly, on the other hand the antibody raised against this 14-kDa sperm protein enhances the forward motility of caprine sperm cells. Rose-Bengal staining method shows that this anti-p14 antibody also decreases the number of acrosome reacted cells if incubated with capacitated sperm cells before induction of acrosome reaction. All these results taken together clearly indicate that p14 is intimately involved and plays a critical role in the acrosomal membrane fusion event.