The Limulus sperm motility-initiating peptide initiates acrosome reactions in sea water lacking potassium

During fertilization in Limulus, the spermatozoa first attach to the egg and then undergo an acrosomal reaction. In this reaction, the acrosomal vesicle exocytoses, and a long, preformed acrosomal filament is extruded (and subsequently penetrates the egg chorion). The egg surface component that triggers the acrosome reaction has not yet been solubilized; therefore, previous studies have examined either spontaneous acrosome reactions or acrosome reactions that were triggered by eggs (or insoluble egg fragments), elevated extracellular Ca2+, or Ca2+ ionophores. In this study, we report a new method for initiating acrosome reactions in Limulus sperm. When the Limulus sperm motility-initiating peptide (SMI) is added to sperm in K+-free sea water, greater than 90% acrosome reactions are initiated within 5 min. However, less than 5% acrosome reactions occur either in K+-free sea water lacking SMI or when SMI is added to sperm in either normal sea water or K+- and Ca2+-free sea water. Experiments with K+ ionophores (nigericin and valinomycin), a K+ channel blocking agent (tetraethyl ammonium), an Na+ ionophore (monensin), and reagents that increase the intracellular pH (monensin, nigericin, and NH4Cl) indicate that changes in intracellular K+, Na+, or H+ do not mediate SMI-initiated acrosome reactions. The K+/Ca2+ ratio determines whether or not SMI will initiate acrosome reactions, with greater than 50% acrosome reactions being initiated when this ratio is below 0.3. In that K+ movement does not appear to be the critical event, possibly the K+/Ca2+ ratio either determines the rate of Ca2+ entry or controls the conformation of sperm surface molecules to allow SMI to initiate acrosome reactions in low K+.     

Cross fertilization between sea urchin eggs and oyster spermatozoa

Interphylum crossing was examined between sea urchin eggs (Temnopleurus hardwicki) and oyster sperm (Crassostrea gigas). The eggs could receive the spermatozoa with or without cortical change. The fertilized eggs that elevated the fertilization envelope began their embryogenesis. Electron microscopy revealed that oyster spermatozoa underwent acrosome reaction on the sea urchin vitelline coat, and their acrosomal membrane fused with the egg plasma membrane after the appearance of an intricate membranous structure in the boundary between the acrosomal process and the egg cytoplasm. Oyster spermatozoa penetrated sometimes into sea urchin eggs without stimulating cortical granule discharge and consequently without fertilization envelope formation. The organelles derived from oyster spermatozoa seemed to be functionally inactive in the eggs whose cortex remained unchanged.     

Labelling of living mammalian spermatozoa with the fluorescent thiol alkylating agent, monobromobimane (MB): immobilization upon exposure to ultraviolet light and analysis of acrosomal status

Living spermatozoa of seven mammalian species were treated with the thiol-alkylating fluorescent labelling compound, monobromobimane (MBBR). MB-labelling alone had no effect on sperm motility, nor on the time course or ability of golden hamster spermatozoa to undergo the acrosome reaction when capacitated in vitro. Exposure of MB-labelled spermatozoa to ultraviolet (UV) light and excitation of the MB fluorochrome resulted in virtually immediate immobilization of the spermatozoa without affecting acrosomal status. UV exposure of unlabelled spermatozoa for up to 30 sec had no effect upon motility. Immobilization of MB-labelled spermatozoa depended on the midpiece being irradiated, as irradiation of the head alone, or of the more distal parts of the principal piece, had little or no effect upon motility. Labelling with MB followed by immobilization of individually selected spermatozoa was most useful for detailing the course and site of occurrence of the acrosome reaction during penetration of the cumulus oophorus by golden hamster spermatozoa in vitro. In these often hyperactivated spermatozoa, precise determination of the acrosomal status could not often otherwise be made due to the difficulty in visualizing the acrosomal region of a vigorously thrashing, hyperactivated spermatozoon. This technique should prove valuable in a variety of studies on sperm motility, capacitation and fertilization, and could also be extended to other cell systems.     

Induction of the acrosome reaction in human spermatozoa by a fraction of human follicular fluid

Human ejaculated spermatozoa were washed through a Percoll gradient, preincubated for 10 hr in a defined medium containing serum albumin, and then induced to undergo rapid acrosome reactions by addition of human follicular fluid or a Sephadex G-75 column fraction of the fluid. Induction by follicular fluid did not occur when the spermatozoa were preincubated for only 0 or 5 hr. The reactions were detected by indirect immunofluorescence using a monoclonal antibody directed against the human sperm acrosomal region. The percentage of acrosomal loss counted by transmission electron microscopy agreed with that counted by immunofluorescence. The apparent molecular weight of the Sephadex G-75 fraction containing the peak of acrosome reaction-inducing activity was 45,000 ± 4,200 (SD). The occurrence of physiological acrosome reactions was supported by: assessing motility (no significant loss of motility occurred during the treatment period when sperm were preincubated with bovine serum albumin), transmission electron microscopy (the ultrastructural criteria for the acrosome reaction were met), and zona-free hamster oocyte binding and penetration (spermatozoa pretreated with the active fraction of follicular fluid, then washed and incubated with oocytes, showed significantly greater binding to and penetration of oocytes). The stimulation of the acrosome reaction by follicular fluid is apparently not due to blood serum contamination; treatment of preincubated spermatozoa with sera from the follicular fluid donors had no effect on the spermatozoa. The nature of the active component(s) in that fraction is currently being investigated.     

Role of intra-acrosomal antigenic molecules acrin 1 (MN7) and acrin 2 (MC41) in penetration of the zona pellucida in fertilization in mice

In this study the role of two intra-acrosomal molecules, acrin 1 (MN7) and acrin 2 (MC41), during in vitro fertilization (IVF) was examined. The pertinent monoclonal antibodies mMN7 and mMC41 specifically recognize a 90 kDa protein (acrin 1) localized to the entire acrosome and a 200 kDa protein (acrin 2) localized to the cortex region of the anterior acrosome, respectively. Experiments were designed to assess the effects of mMN7 and mMC41 on fertilization in mice using TYH medium containing mMN7 or mMC41 at 0.0, 0.025, 0.05 and 0.1 mg ml-1. Under these conditions, capacitated spermatozoa inseminated the cumulus-invested oocytes. Acrosome-reacted spermatozoa inseminated the zona pellucida-free oocytes. The antibodies had no effect on sperm motility and primary binding to the zona pellucida, but significantly inhibited the rate of fertilization of zona pellucida-intact oocytes in a dose-dependent manner. A significantly small number of spermatozoa remained attached to the zona pellucida at 5 h after insemination in the presence of mMC41. mMC41 and mMN7 antibodies did not affect the fertilization rate of zona pellucida-free oocytes. Confocal laser scanning microscopy with indirect immunofluorescence traced the effect of the monoclonal antibodies on the zona pellucida-induced acrosome reaction, and revealed that mMN7 prevented completion of acrosomal matrix dispersal, whereas mMC41 did not affect the acrosome reaction. mMC41 appeared to inhibit secondary binding or some biochemical steps on the zona pellucida after the acrosome reaction but before penetration of the zona pellucida. Thus, the intra-acrosomal antigenic molecules acrin 1 and acrin 2 are essential for distinct events before sperm penetration of the zona pellucida in mice.     

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.     

The composition, protein genesis and significance of the inner acrosomal membrane of eutherian sperm

As a consequence of the acrosomal reaction during fertilization, the inner acrosomal membrane (IAM) becomes exposed and forms the leading edge of the sperm for adhesive binding to and subsequent penetration of the zona-pellucida (ZP) of the metaphase-II-arrested oocyte. A premise of this review is that the IAM of spermatozoa anchors receptors and enzymes (on its extracellular side) that are required for sperm attachment to and penetration of the ZP. We propose a sperm cell fractionation strategy that allows for direct access to proteins bound to the extracellular side of the IAM. We review the types of integral and peripheral IAM proteins that have been found by this approach and that have been implicated in ZP recognition and lysis. We also propose a scheme for the origin and assembly of these proteins within the developing acrosome during spermiogenesis. During development, the extravesicular side of the membrane of the acrosomic vesicle is coated by peripheral proteins that transport and bind this secretory vesicle to the spermatid nucleus. The part of the membrane that binds to the nucleus becomes the IAM, while its extravesicular protein coat, which is retained between the IAM and the nuclear envelope of spermatozoa becomes the subacrosomal layer of the perinuclear theca (SAL-PT). Another premise of this review is that the IAM of spermatozoa is bound with proteins (on its intracellular side), namely the SAL-PT proteins, which hold the clue to the mechanism of acrosomal-nuclear docking. We propose a sperm cell fractionation strategy that allows for direct access to SAL-PT proteins. We then review the types of SAL-PT proteins that have been found by this approach and that have been implicated in transporting and binding the acrosome to the sperm nucleus.     

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.     

Mouse gamete interactions: The zona pellucida is the site of the acrosome reaction leading to fertilization in vitro

The question of whether the acrosome reaction, which leads to fertilization, occurs in intact sperm bound to the zona pellucida of the egg or in intact sperm before contact with the egg, was addressed by assessing the effect of 3-quinuclidinyl benzilate (QNB) on the two types of acrosome reaction. QNB is a specific inhibitor of the fertilization of zona-intact mouse eggs by mouse sperm. Mouse spermatozoa in suspension underwent acrosome reactions at a low rate, which could be accelerated by addition of 5 μM divalent cation ionophore A23187; the occurrence of such acrosome reactions was not inhibited by QNB. The rate at which acrosome reactions occurred in sperm bound to the zona pellucida of cumulus-free eggs, bound to isolated zonae, or exposed to acid-solubilized zona components, was greatly accelerated relative to that observed in the absence of zonae. These acrosome reactions were strongly inhibited by QNB at concentrations which inhibit the fertilization of zona-intact mouse eggs in vitro. These data suggest that the zona pellucida can induce acrosome reactions in mouse spermatozoa and that these acrosome reactions are the ones which lead to the fertilization of zona-intact eggs. In contrast, the acrosome rection in sperm which are not in contact with the zona is not associated with fertilization of zona-intact eggs.     

ELECTRON MICROSCOPE STUDIES OF EARLY STAGES OF SPERM PENETRATION IN HYDROIDES HEXAGONUS (ANNELIDA) AND SACCOGLOSSUS KOWALEVSKII (ENTEROPNEUSTA)

1. The early events of sperm entry in Saccoglossus and Hydroides are described and examined in relation to present knowledge of the acrosome reaction and of egg membrane lysins. In Saccoglossus and several other species these events occur in two phases. First. The acrosome filament of the spermatozoön spans the egg membrane barriers, reaches the reactive egg protoplasm, and causes the egg to begin its fertilization reaction. Second. The filament and its connected sperm head move through the egg membrane barriers and enter the egg proper. The first phase is completed in a matter of seconds but the second phase usually requires several minutes. 2. The peripheral areas of the eggs of the two species differ as seen in sections. In Hydroides, but not in Saccoglossus, the vitelline membrane is bounded by a distinct outer border layer of small concentrically differentiated bodies and penetrated by microvilli from the egg. 3. The acrosome filament, seen in the living condition as a delicate thread in Hydroides and as an exceedingly tenuous thread in Saccoglossus, appears to be tubular in both species when seen in electron micrographs of thin sections. 4. The acrosomal region of Hydroides appears to consist of two components—a peripheral one, which may collapse during the acrosome reaction, and a central one related to the acrosome filament. 5. Deliberately induced polyspermic material was used to increase the probability of finding examples of sperm penetration in thin sections. 6. As seen in sections, areas of low electron density, interpreted as spaces or pits from which the material of the membrane is absent, surround the attached or penetrating spermatozoa. (a) In Hydroides the spaces vary greatly in many characteristics including shape, position in the membrane, and size with relation to the enclosed sperm head. In one specimen a portion of the membrane is missing from border to border; no spermatozoön is seen but immediately beneath the space is the apex of a fertilization cone. (b) In every case in which a determination could be made, the spermatozoön in the membrane has undergone its acrosome reaction. (c) In Saccoglossus some pits are found with which several spermatozoa are associated. Generally, where the spermatozoa are more numerous the pit is larger. (d) Pits similar to those seen in Saccoglossus sections are observed in living eggs. They remain in Membrane I after sperm entry. (e) From the above and other considerations it is suggested that the pits and spaces are formed by local action of a lysin or lysins emanating from the individual spermatozoön at the site of sperm entry. 7. It is considered that the suggested lysin would participate in sperm entry by eroding the membrane barrier in the vicinity of the sperm head, thus permitting the sperm head to pass through the membrane. Since the acrosome filament much earlier stimulates the egg's initial fertilization response, this lysin would facilitate the second phase of the early events of sperm entry.     

Localization of a syntaxin isoform, syntaxin 2, to the acrosomal region of rodent spermatozoa

The acrosome reaction includes a membrane fusion event that is a prerequisite for sperm penetration through the zona pellucida and subsequent fertilization. Since SNARE (soluble N-ethylmaleimide-sensitive factor attachment protein receptor) proteins have been shown to be key players in membrane fusion during regulated exocytosis in nerve terminals and secretory cells, and since the acrosome reaction has some features in common with regulated exocytosis, we hypothesized that SNARE proteins might also regulate acrosomal exocytosis. RT-PCR analysis demonstrated the expression of SNARE proteins, three isoforms of syntaxin 2 (2A, 2B, and 2C) and syntaxin 4A, in rat testes. Immunoblot analysis with anti-syntaxin 2 antibody showed that the protein was expressed in rodent spermatozoa, and that it was associated with membrane components of spermatozoa prepared by sucrose density gradient centrifugation. Confocal laser scanning microscopy with double immunolabeling revealed that syntaxin 2 was colocalized with acrin 1, a 90 kDa acrosomal protein, over the acrosomal region of spermatozoa but was not associated with the posterior half of head or tail. Localization of syntaxin 2 over the acrosomal region was supported by the finding that it was shed from sperm heads during an acrosome reaction induced by calcium ionophore A23187 in vitro. In view of the putative role of syntaxin proteins in other membrane fusion systems, these data suggest that syntaxin 2 may be involved in regulating the acrosomal reaction in rodent spermatozoa.     

Mammalian sperm acrosome: formation, contents, and function

Sperm-egg interaction is a carbohydrate-mediated species-specific event which initiates a signal transduction cascade resulting in the exocytosis of sperm acrosomal contents (i.e., the acrosome reaction). This step is believed to be a prerequisite which enables the acrosome-reacted spermatozoa to penetrate the zona pellucida (ZP) and fertilize the egg. Successful fertilization in the mouse and several other species, including man, involves several sequential steps. These are (1) sperm capacitation in the female genital tract; (2) binding of capacitated spermatozoa to the egg's extracellular coat, the ZP; (3) induction of acrosome reaction (i.e., sperm activation); (4) penetration of the ZP; and (5) fusion of spermatozoon with the egg vitelline membrane. This minireview focuses on the most important aspects of the sperm acrosome, from its formation during sperm development in the testis (spermatogenesis) to its modification in the epididymis and function following sperm-egg interaction. Special emphasis has been given to spermatogenesis, a complex process involving multiple molecular events during mitotic cell division, meiosis, and the process of spermiogenesis. The last event is the final phase when a nondividing round spermatid is transformed into the complex structure of the spermatozoon containing a well-developed acrosome. Our intention is also to briefly discuss the functional significance of the contents of the sperm acrosome during fertilization. It is important to mention that only the carbohydrate-recognizing receptor molecules (glycohydrolases, glycosyltransferases, and/or lectin-like molecules) present on the surface of capacitated spermatozoa are capable of binding to their complementary glycan chains on the ZP. The species-specific binding event starts a calcium-dependent signal transduction pathway resulting in sperm activation. The hydrolytic and proteolytic enzymes released at the site of sperm-zona interaction along with the enhanced thrust of the hyperactivated beat pattern of the bound spermatozoon, are important factors in regulating the penetration of the zona-intact egg.     

EARLY STEPS OF SPERM—EGG INTERACTIONS DURING MAMMALIAN FERTILIZATION

Mammalian eggs are surrounded by two egg coats: the cumulus oophorus and the zona pellucida, which is an extracellular matrix composed of sulfated glycoproteins. The first association of the spermatozoon with the zona pellucida occurs between the zona glycoprotein, ZP3 and sperm receptors, located at the sperm plasma membrane, such as the 95kDa tyrosine kinase-protein. This association induces the acrosome reaction and exposes the proacrosin/acrosin system. Proacrosin transforms itself, by autoactivation, into the proteolytical active form: acrosin. This is a serine protease that has been shown to be involved in secondary binding of spermatozoa to the zona pellucida and in the penetration of mammalian spermatozoa through it. The zona pellucida is a specific and natural substrate for acrosin and its hydrolysis and fertilization can be inhibited by antiacrosin monoclonal antibodies. Moreover, inin vitrofertilization experiments, trypsin inhibitors significantly inhibits fertilization. The use of the silver-enhanced immunogold technique has allowed immunolocalization of the proacrosin/acrosin system in spermatozoa after the occurrence of the acrosome reaction. This system remains associated to the surface of the inner acrosomal membrane for several hours in human, rabbit and guinea-pig spermatozoa while in the hamster it is rapidly lost. In the hamster, the loss of acrosin parallels the capability of the sperm to cross the zona pellucida. Rabbit perivitelline spermatozoa can fertilize freshly ovulated rabbit eggs and retain acrosin in the equatorial and postacrosomal region. These spermatozoa also show digestion halos on gelatin plates that can be inhibited by trypsin inhibitors. This evidence strongly suggests the involvement of acrosin in sperm penetration through the mammalian zona. Recently it was shown, however, that acrosin would not be essential for fertilization. It is likely, then, that such an important phenomenon in the mammalian reproductive cycle would be ensured though several alternative mechanisms.     

Egg jelly of the newt, Cynops pyrrhogaster contains a factor essential for sperm binding to the vitelline envelope

The acrosome reaction of newt sperm is induced at the surface of egg jelly and the acrosome-reacted sperm acquire the ability to bind to the vitelline envelope. However, because the substance that induces the acrosome reaction has not been identified, the mechanism by which the acrosome-reacted sperm bind to the vitelline envelope remains unclear. We found here that a Dolichos biforus agglutinin (DBA) specifically mimicked the acrosome reaction immediately upon its addition in the presence of milimolar level Ca(2+). Fluorescein isothiocyanate-labeled DBA bound specifically to the acrosomal cap of the intact sperm in the presence of a Ca(2+)-chelating agent, EDTA, suggesting that binding of DBA to the native receptor for the egg jelly substance on the acrosomal region took the place of the egg jelly substance-induced acrosome reaction. In contrast, the sperm that had been acrosome reacted by DBA treatment did not bind to the vitelline envelope of the egg whose jelly layers were removed. Subsequent addition of jelly extract caused the sperm binding to vitelline envelope, indicating that the egg jelly of the newt contains substances that are involved in not only inducing the acrosome reaction but also binding to the vitelline envelope. This is the first demonstration of the involvement of egg jelly substance in the binding of acrosome-reacted sperm to the vitelline envelope.     

Isolation and proteomic characterization of the mouse sperm acrosomal matrix

A critical step during fertilization is the sperm acrosome reaction in which the acrosome releases its contents allowing the spermatozoa to penetrate the egg investments. The sperm acrosomal contents are composed of both soluble material and an insoluble material called the acrosomal matrix (AM). The AM is thought to provide a stable structure from which associated proteins are differentially released during fertilization. Because of its important role during fertilization, efforts have been put toward isolating the AM for biochemical study and to date AM have been isolated from hamster, guinea pig, and bull spermatozoa. However, attempts to isolate AM from mouse spermatozoa, the species in which fertilization is well-studied, have been unsuccessful possibly because of the small size of the mouse sperm acrosome and/or its fusiform shape. Herein we describe a procedure for the isolation of the AM from caput and cauda mouse epididymal spermatozoa. We further carried out a proteomic analysis of the isolated AM from both sperm populations and identified 501 new proteins previously not detected by proteomics in mouse spermatozoa. A comparison of the AM proteome from caput and cauda spermatozoa showed that the AM undergoes maturational changes during epididymal transit similar to other sperm domains. Together, our studies suggest the AM to be a dynamic and functional structure carrying out a variety of biological processes as implied by the presence of a diverse group of proteins including proteases, chaperones, hydrolases, transporters, enzyme modulators, transferases, cytoskeletal proteins, and others.     

Effect of preincubation of cryopreserved porcine epididymal sperm

Preincubation of spermatozoa is important for capacitation and successful fertilization in vitro. The effects of preincubation time on frozen-thawed boar epididymal spermatozoa as measured by sperm motility, acrosomal integrity and fertilization ability in vitro were examined. Epididymal spermatozoa were collected from three Large White boars and frozen. The thawed spermatozoa were preincubated for 0, 15, 30, 60 and 120 min. Their motility was evaluated by a sperm motility analyzer and then the sperm motility indexes (SMIs) were calculated. The status of their acrosomal integrity was evaluated by triple-staining. Then, their fertilization ability was examined by in vitro fertilization (IVF) using porcine oocytes matured in vitro. SMIs of spermatozoa and the incidences of acrosome-intact live spermatozoa from the three boars were high (21-39 for SMI and 50-61% for acrosome-intact live spermatozoa) just after thawing, but both decreased as the duration of preincubation was prolonged (2-10 and 23-40%, respectively). The incidences of sperm penetration were high (61-89% of inseminated oocytes) when the sperm were preincubated for 0-60 min. However, sperm penetration decreased as the preincubation period was prolonged to 120 min. The degree of this decrease differed depending upon the boar from which the spermatozoa were obtained (10-72%). When the two parameters, sperm motility and acrosomal integrity, were analyzed statistically, the latter parameter rather than the former one showed a significant effect on penetration ability in vitro after each duration of preincubation. These results suggest that preincubation of frozen-thawed boar epididymal spermatozoa is not required for IVF and also that the maintenance of acrosomal integrity in unreacted status, rather than the maintenance of sperm motility, is important for fertilization ability after thawing and during preincubation of boar epididymal spermatozoa.     

Mechanism of univalent antisperm antibody inhibition of fertilization in the sea urchin, Arbacia punctulata

Univalent antisperm antibodies (IFab) markedly inhibited the fertilizing capacity of sperm when tested on intact, dejellied, and "demembranated" Arbacia punctulata eggs. Sperm motility and egg jelly penetration were not affected by IFab. Antifertilizin was excluded as the essential sperm antigen involved in the fertilization-inhibiting action. Sperm pretreated with IFab did not bind to the surfaces of either dejellied or demembranated eggs, whereas control globulin (CFab) and seawater-pretreated sperm bound to such eggs in high numbers. Electron microscopy showed that IFab-treated sperm failed to undergo the acrosome reaction. This excluded "bindin" as the essential antigen. Inhibition of fertilization by IFab was reversed or bypassed by artificial induction of the acrosome reaction with ionophore A23187. It is concluded that univalent antisperm antibody treatment inhibits the fertilizing capacity of sperm by preventing a sperm-egg interaction that results in the acrosome reaction; consequently, attachment of the sperm to the egg is prevented.     

Effect of liquid storage and cryopreservation of boar spermatozoa on acrosomal integrity and the penetration of zona-free hamster ova in vitro

The effect of liquid storage and cryopreservation of boar spermatozoa on sperm motility, acrosomal integrity, and the penetration of zona-free hamster (ZFH) ova was examined. The sperm penetration assay (SPA) provides valuable information on specific events of fertilization and is a potentially useful indicator of sperm fertility. Ejaculated semen from 4 boars was subjected to 3 treatments: fresh (FRE, no storage), liquid-stored (LIS, stored at 18°C for 3 days), and frozen (FRO, frozen by pellet method and stored at ?196°C for 3 days). A highly motile sperm population was isolated by the swim-up procedure (1 hr). FRE and LIS were incubated an additional 3 hr at 39°C in a Tris-buffered medium to elicit capacitation and the acrosome reaction. Sperm motility and acrosomal integrity were assessed before and after incubation. For the SPA, sperm and eggs were incubated at 39°C for 3 hr in Hams F-10 medium. Each egg was assessed for sperm penetration, sperm binding, and stage of development. Percentages of sperm motility and sperm with a normal apical ridge (NAR) prior to incubation were 78 and 78 (FRE), 75 and 69 (LIS), and 28 and 50 (FRO). After incubation, percentages of motility, NAR, and acrosome-reacted sperm were 34, 10, and 73 (FRE); 43, 24, and 51 (LIS); and 18, 13, and 59 (FRO). A somewhat higher (P < .05) percentage of ZFH ova was penetrated by FRE (45.8) than by LIS (42.0). Penetration of ZFH ova by FRO was markedly (P < .05) reduced (30.2). Sperm penetration was not significantly correlated with motility or acrosomal integrity before or after incubation, regardless of treatment. These data suggest that the SPA can be used in conjunction with conventional measures of semen analysis in assessing the potential fertilizing capacity of boar sperm and that liquid storage is superior to frozen storage with respect to preserving sperm fertility.     

Development of ability to penetrate the cumulus oophorus by hamster spermatozoa capacitated in vitro,in relation to the timing of the acrosome reaction

Hamster spermatozoa were tested for their ability to penetrate the intact cumulus matrix at low sperm:egg ratios (approximately 3:1). Uncapacitated spermatozoa attached to the surface of the cumulus and could not penetrate. Spermatozoa capacitated in vitro began to be able to penetrate after about 2 hr of preincubation, coincidentally with the first appearance of hyperactivation and spontaneous acrosome reactions. In all, 628 in vitro incubated spermatozoa were evaluated on and in cumuli: 270 could penetrate, but only ten of these were judged to have intact, “unmodified” acrosomes. Almost all spermatozoa capable of penetrating showed optically “modified” and swelling acrosomal caps, and this confirms previous observations on cumulus penetration in vivo. Penetration appeared limited to a phase in capacitation prior to completion of the acrosome reaction, as spermatozoa that had lost the acrosomal cap penetrated poorly and showed reduced viability. Penetration of the cumulus was inhibited by the hyaluronidase inhibitor sodium aurothiomalate. Cumulus penetrating ability could result either from a change in surface properties of the sperm at capacitation, which renders them less “sticky” to the matrix, or from release or activation of a “cumulus lysin.” We conclude that the ability to enter the cumulus matrix coincides with physiological changes in spermatozoa that occur during a terminal phase of capacitation preceding complete loss of the acrosomal cap, and that initiation of this process in vivo must precede sperm-zona contact.     

Effects of platelet activating factor on the motility and acrosome reaction of bovine spermatozoa

The effects of platelet activating factor (PAF) on motility and the acrosome reaction of ejaculated bull spermatozoa were evaluated. Washed spermatozoa (30 x 10(6)/ml) were incubated (39 degrees C) for up to 2 h with 10 to 200 muM PAF in a modified Tyrode's solution (pH 7.4) containing 3 mg/ml bovine serum albumin. Sperm motility was evaluated subjectively and by computer-assisted semen analysis. Percent acrosome-reacted spermatozoa was quantified microscopically from fixed smears following Giemsa staining. Percent fertilization by PAF-treated spermatozoa was determined using in vitro-matured bovine ova. Percent sperm motility decreased with >/= 50 muM PAF, while the rate of motility loss increased with PAF concentration (P<0.001). Percent acrosome reactions increased with PAF concentration during incubation (P<0.001). Acrosomal loss was rapid and complete with 200 muM PAF. At concentrations between 80 to 120 muM PAF, bull spermatozoa underwent acrosome reactions without a rapid loss of motility and penetrated in vitro-matured bovine ova at a rate comparable to that of heparin-capacitated spermatozoa (68 versus 54%, respectively). Incubation of bull spermatozoa with 10 to 50 muM PAF for 45 min had no effect on percent progressive motility, sperm velocity or other motility parameters. These results indicate that PAF can be used to induce acrosome reactions in bull spermatozoa and to promote in vitro fertilization of bovine ova. Under the conditions used in this study, PAF did not stimulate bovine sperm motility.