Acrosome Reaction-inducing Activity Research Articles

Analysis of terminal sugar moieties and species‐specificities of acrosome reaction‐inducing substance in Xenopus (ARISX)

The acrosome reaction of Xenopus sperm is triggered by the acrosome reaction-inducing substance in Xenopus (ARISX), an oviductal pars recta-derived, sugar-rich substance decorated on the entire surface of the vitelline envelope (VE) during ovulation. Here we addressed the functional importance of the sugar moiety in ARISX. Among various lectins examined, soybean agglutinin and Dolichos biflorus agglutinin were shown to abolish the acrosome reaction-inducing activity of ARISX present in pars recta extract or on the VE, indicating the importance of the terminal alpha-N-acetylgalactosamine residue for the function of ARISX. Consistently, the acrosome reaction-inducing activity was not affected by proteinase K digestion, in spite of the simultaneous shift of ARISX to a smaller molecular weight. Indirect immunofluorescence microscopic examinations showed that ARISX was distributed as two types of structures on VE; thick fiber-like materials and thin filamentous materials, and that a new structure appeared on the fertilization envelope instead of the thin filamentous materials. Sperm from several amphibian species were subjected to an in vitro assay during induction of the acrosome reaction with ARISX. The resulting limited population of sperm from a non-Xenopus species underwent acrosome reaction, implying a weak species-specificity of ARISX.

Characterization of the acrosome reaction-inducing substance in Xenopus (ARISX) secreted from the oviductal pars recta onto the vitelline envelope

We previously demonstrated that Xenopus sperm undergo an acrosome reaction on the vitelline envelope (VE) in response to the materials secreted from the oviductal pars recta [Dev. Biol. 243 (2002), 55]. A monoclonal antibody against the acrosome reaction-inducing substance in Xenopus (ARISX) was obtained by immunizing mice with pars recta extract (PRE). The acrosome reaction by PRE or on the VE was effectively inhibited by the intact anti-ARISX antibody as well as its Fab fragment, indicating that the antibody recognizes the epitopes localized on the acrosome reaction-inducing substance. On Western blots, the anti-ARISX antibody recognized a molecule with an apparent molecular mass of 300 kDa in PRE and in the VE, but this molecule was not detected in the coelomic envelope. The amount of ARISX in PRE was increased by the treatment of females with pregnant mare serum gonadotropin. Periodate oxidation of PRE completely abolished the acrosome reaction-inducing activity, indicating the involvement of the carbohydrate moieties of ARISX in inducing the acrosome reaction. On immunofluorescence observation, ARISX was localized in the epithelial cells in the posterior region of the pars recta and on the VE as fibrous structures.

Acrosome Reaction in Sperm of the Frog, Xenopus laevis: Its Detection and Induction by Oviductal Pars Recta Secretion

Previous electron microscopic observations have shown that the acrosome of the sperm of the frog, Xenopus laevis, comprises a membrane-bounded vesicle covering the anterior-most position of the head. We obtained a sperm suspension from the testes and stained it with LysoSensor Green for observation under a confocal laser scanning microscope and found a bright fluorescence reflecting the presence of the acrosomes at the top of the sperm head in about 64% of the sperm, with no deterioration of their capacity to fertilize. About 40% of the sperm with an acrosome underwent an acrosome reaction in response to Ca2+ ionophore A23187, as evidenced by a loss of LysoSensor Green stainability, accompanied by breakdown of the acrosomal vesicle. About 53% of the sperm bound to isolated vitelline envelopes underwent an acrosome reaction, whereas both jelly water and solubilized vitelline envelopes weakly induced an acrosome reaction. When the sperm were treated with an oviductal extract obtained from the pars recta, but not the pars convoluta region, about 40% of the sperm with acrosomes underwent an acrosome reaction. The substance containing acrosome reaction-inducing activity in the pars recta extract seemed to be a heat-unstable substance with a molecular weight of greater than 10 kDa. The activity was not inhibited by protease inhibitors but required extracellular Ca2+ ions. These results indicate that the acrosome reaction occurs on the vitelline envelopes in response to the substance deposited from the pars recta during the passage of the oocytes through the oviduct.

Structure and function of asterosaps, sperm-activating peptides from the jelly coat of starfish eggs.

Jelly coat of starfish eggs has the capacity to activate homologous spermatozoa and induce the acrosome reaction. We have isolated 12 sperm-activating peptides (SAPs) from the egg jelly of the starfish, Asterias amurensis. Eleven SAPs were structurally identified by sequence analysis and electro-spray ionisation mass spectrometry. All of them are glutamine-rich tetratriacontapeptides with an intramolecular disulphide linkage between Cys8 and Cys32. They are much larger than sea urchin SAPs and do not show any significant sequence similarities to known proteins. Thus we have collectively named them asterosaps. The amino terminal region, where structural diversity of asterosaps is observed, is not important for their activity, whereas the disulphide linkage is essential. Asterosaps do not induce the acrosome reaction by themselves, but are able to induce the acrosome reaction in combination with an egg jelly glycoconjugate named ARIS. Furthermore, anti-asterosap rabbit antibody significantly decreased the acrosome reaction-inducing activity of the jelly solution and the activity was restored by addition of excess asterosap. These results support our hypothesis that the main physiological role of SAPs is the induction of the acrosome reaction in cooperation with two other jelly components, ARIS and Co-ARIS.

Characterization of mouse ZP3-derived glycopeptide, gp55, that exhibits sperm receptor and acrosome reaction-inducing activity in vitro.

During fertilization, free-swimming mouse sperm bind to mZP3 (approximately 83 000 Mr), one of three zona pellucida glycoproteins, and once bound undergo the acrosome reaction, a type of cellular exocytosis [Wassarman, P. M., & Litscher, E. S. (1995) Curr. Top. Dev. Biol. 30, 1-19]. Sperm recognize and bind to specific serine/threonine-linked oligosaccharides located at the mZP3 combining site for sperm. Here, we examined certain characteristics of gp55, a approximately 55 000 Mr glycopeptide derived from the carboxy-terminal half of mZP3 polypeptide to which sperm bind [Rosiere, T. K., & Wassarman, P. M. (1992) Dev. Biol. 154, 309-317]. gp55 is heterogeneous with respect to Mr (approximately 47 000-62 000 Mr) and has a relatively low pI (approximately 4.3-4.5) compared to the polypeptide portion of the glycopeptide (pI approximately 6.5). gp55 inhibits binding of sperm to eggs (i.e., exhibits sperm receptor activity) and induces sperm to undergo the acrosome reaction in vitro at about the same concentrations required for intact mZP3 (approximately 50-200 nM). Each of three different size-fractions of gp55, separated by SDS-PAGE, also exhibits bioactivity in vitro. Removal of asparagine-linked (N-linked) oligosaccharides from gp55, by extensive digestion with N-glycanase, reduces its Mr to approximately 21 000 and increases it pI to approximately 5.3, but does not significantly affect its ability to inhibit binding of sperm to eggs or to induce sperm to undergo the acrosome reaction. Similarly, digestion of gp55 with either endo-beta-galactosidase or neuraminidase alters its Mr and/or pI, but does not significantly affect either of its bioactivities. These observations are consistent with the proposal that neither N-linked oligosaccharides nor sialic acid is an essential element of the mZP3 combining site for sperm. They also indicate that a relatively small mZP3 glycopeptide is able to induce sperm to undergo the acrosome reaction (i.e., cellular exocytosis) in vitro.

N-Linked Oligosaccharides of Sea Urchin Egg Jelly Induce the Sperm Acrosome Reaction: (fertilization/acrosome reaction/sea urchin/sperm/N-linked oligosaccharides).

The sea urchin egg jelly coat (EJ) induces the acrosome reaction (AR) of sperm. We previously demonstrated that a fraction of EJ containing two glycoproteins of 82- and 138-kDa possess the AR inducing activity (8). Here we show that Peptide-N-Glycosidase-F treatment of EJ followed by precipitation and washing in 70% ethanol results in a substantial loss of AR inducing activity in the ethanol insoluble material. When a PNGase-F digest of EJ is chromatographed on a Sepacryl-200 gel filtration column, an AR inducing fraction elutes within the partitioning volume. Acrosome reaction inducing activity of undigested EJ does not elute within the partitioning volume. The chromatographed AR inducing fraction of the PNGase-F digest reacts strongly in the phenol-sulfuric assay demonstrating carbohydrate is present; silver stained gels do not detect the presence of protein. Harsh alkaline hydrolysis of EJ in an excess of NaBH4 , preserves a substantial amount of AR inducing activity. These data show that N-linked oligosaccharides released from EJ by PNGase-F digestion are capable of inducing the sperm acrosome reaction.

Immunoglobulins from human follicular fluid induce the acrosome reaction in human sperm.

The ability of human follicular fluid (hFF), retrieved from women undergoing IVF to induce the acrosome reaction (AR) in human sperm has been documented by several laboratories. However, the nature of the active factors in the hFF and the physiological meaning of the AR induction are highly controversial. We performed a three step purification scheme for hFF and all the fractions were screened for the AR-inducing activity. AR activity was associated with a protein fraction of M(r) > 180 kD that on further analysis under PAGE was found to be composed by subunits of apparent M(r) 50,000 and 29,000. The N-terminal sequences of these bands showed a 100% homology with the heavy and light chains of human IgG. A polyclonal antibody raised against the purified protein and anti-human IgG were both able to suppress the acrosome reaction-inducing activity of crude hFF. However, neither normal human serum nor a purified preparation of human IgG were able to mimic the AR-inducing activity of hFF. We concluded that the AR-inducing activity of hFF is, at least in part, due to the presence of antisperm antibodies.

Activation of a Gi protein in mouse sperm membranes by solubilized proteins of the zona pellucida, the egg's extracellular matrix.

Zona pellucida (ZP)-induced acrosomal exocytosis in mammalian spermatozoa is thought to be mediated by signal transduction cascades similar to those found in hormonally responsive cells. In order to characterize this process further, we have examined the role of GTP-binding regulatory proteins (G proteins) in coupling sperm-ZP interaction to intracellular second messenger systems in mouse sperm. An in vitro signal transduction assay was developed to assess ZP-G protein dynamics in sperm membrane preparations. Guanosine 5'-3-O-(thio)triphosphate (GTP gamma S), a poorly hydrolyzable analogue of GTP, bound to these membranes in a specific and concentration-dependent fashion which reached saturation at 100 nM. Incubation of the membrane preparations with heat-solubilized ZP resulted in a significant increase in specific GTP gamma S binding in a concentration-dependent fashion with a half-maximal response at 1.25-2 ZP/microliters. Solubilized ZP also caused a significant increase in high affinity GTPase activity in the membranes over basal levels. Mastoparan increased specific GTP gamma S binding to the sperm membranes and stimulated high-affinity membrane GTPase activity to levels consistently greater than that seen with the solubilized ZP. Mastoparan, together with solubilized ZP, gave the same level of stimulation of GTP gamma S binding as mastoparan alone. Pertussis toxin completely inhibited the ZP-stimulated GTP gamma S binding, but only decreased mastoparan-stimulated GTP gamma S binding by 70-80%. Purified ZP3, the ZP component which possesses quantitatively all of the acrosomal exocytosis-inducing activity of the intact ZP, stimulated GTP gamma S binding to the same level as solubilized ZP; ZP1 and ZP2 did not stimulate GTP gamma S binding. ZP from fertilized eggs (ZPf), which does not possess acrosome reaction-inducing activity, also failed to stimulate GTP gamma S binding to sperm membranes. These data demonstrate the direct activation of a Gi protein in sperm membrane preparations in response to the ZP glycoprotein, ZP3, that induces the acrosome reaction. These data imply that Gi protein activation is an early event in the signal sequence leading to sperm acrosomal exocytosis.

Embryonal carcinoma cells transfected with ZP3 genes differentially glycosylate similar polypeptides and secrete active mouse sperm receptor.

Mouse and hamster sperm receptors, called mZP3 (approximately 83,000 Mr) and hZP3 (approximately 56,000 Mr), respectively, are glycoproteins located in the ovulated egg zona pellucida. Certain of the glycoprotein O-linked oligosaccharides are essential for sperm receptor activity. Here, we transfected mouse embryonal carcinoma (EC) cells with mZP3 and hZP3 genes placed under control of a constitutive promoter. Transfected cells synthesized and secreted large amounts of the glycoproteins, called EC-mZP3 and EC-hZP3. Although the primary structures of mZP3 and hZP3 polypeptides (44,000 Mr) are very similar to one another, EC-mZP3 (approximately 83,000 Mr) and EC-hZP3 (approximately 49,000 Mr) were glycosylated to very different extents, such that they resembled their egg counterparts. Like egg mZP3, EC-mZP3 inhibited binding of sperm to ovulated eggs and induced sperm to acrosome-react in vitro. In addition, large numbers of sperm bound to aggregates of mZP3-transfected EC cells in vitro. On the other hand, unlike egg hZP3, EC-hZP3 did not exhibit either sperm receptor or acrosome reaction-inducing activity, and sperm failed to bind to aggregates of hZP3-transfected EC cells. Thus, transfected EC cells not only express sperm receptor genes, but also discriminate between very similar polypeptides with respect to glycosylation and, in the case of mZP3, add specific oligosaccharides essential for biological activity. In addition, the results demonstrate that EC cells can serve as a source for large amounts of functional mouse sperm receptor.

Aggregation of β-1,4-galactosyltransferase on mouse sperm induces the acrosome reaction

β-1,4-Galactosyltransferase (GalTase) is present on the surface of mouse sperm, where it functions during fertilization by binding to oligosaccharide residues in the egg zona pellucida. The specific oligosaccharide substrates for sperm GalTase reside on the glycoprotein ZP3, which possesses both sperm-binding and acrosome reaction-inducing activity. A variety of reagents that perturb sperm GalTase activity inhibit sperm binding to the zona pellucida, including UDP-galactose, N-acetylglucosamine, α-lactalbumin, and anti-GalTase Fab fragments. However, none of these reagents are able to cross-link GalTase within the membrane nor are they able to induce the acrosome reaction. On the other hand, intact anti-GalTase IgG blocks sperm-zona binding as well as induces the acrosome reaction. Anti-GalTase IgG induces the acrosome reaction by aggregating GalTase on the sperm plasma membrane, as shown by the inability of anti-GalTase Fab fragments to induce the acrosome reaction unless cross-linked with goat anti-rabbit IgG. These data suggest that zona pellucida oligosaccharides induce the acrosome reaction by clustering GalTase on the sperm surface.

Protein synthesis and acrosome reaction-inducing activity of human cumulus cells

The acrosome reaction of human spermatozoa is a prerequisite to fertilization. It has been hypothesized that secretions of cumulus cells could be involved in the induction of this sperm reaction. A source of variation in the in-vitro fertilization of human oocytes could be the maturational differences in the cumulus cells which affect the acrosome reaction. In order to investigate this possibility, we have studied the capability of secretions obtained from cumulus cells of different maturational stages to induce the acrosome reaction. Capacitated spermatozoa were exposed to the culture medium containing cumulus cell secretions and their acrosomal status was evaluated using the triple stain technique. The maturational status of the cumulus or fertilization of the enclosed oocyte did not influence the percentage of acrosome-reacted live spermatozoa. In order to further document these observations, cumulus cells were submitted to [35S]methionine incorporation and total and secreted proteins were analysed by SDS-PAGE electrophoresis. Neither quantitative nor qualitative changes were detected in the electrophoretic patterns of the proteins obtained from cumulus cells of different maturational status. Thus, variation of the acrosome reaction-inducing activity of cumulus cells does not appear to be involved in the variable fertilization of oocytes obtained from follicles of differing maturity.

Immunoinhibition of human fertilization in vitro by antibodies to the cumulus oophorus intercellular matrix.

Rabbit polyvalent antiserum raised against the solubilized cumulus matrix was a powerful inhibitor of human fertilization in vitro, affecting sperm-zona pellucida interaction. Both sperm binding to, and penetration of, the zona pellucida were severely impaired by the anti-cumulus matrix antiserum, whereas no effects of this antiserum on cumulus matrix solubilization or penetration of zona-free human eggs were evident. Moreover, the anti-cumulus antiserum partly neutralized the acrosome reaction-inducing activity of the cumulus matrix. These results warrant further research into the functional specificity of different cumulus matrix components and into the effects of the respective antibodies on reproductive function as a possible lead to a new approach to contraceptive vaccine development.

Egg-induced modifications of the zona pellucida of mouse eggs: Effects of microinjected inositol 1,4,5-trisphosphate

Mouse eggs microinjected with physiological concentrations of inositol 1,4,5-trisphosphate (IP 3) do not emit the second polar body, form a pronucleus, or display a fertilization-associated set of changes in the pattern of protein synthesis. IP 3-injected eggs, however, display a conversion of the zona pellucida glycoprotein ZP2 to ZP2 f. The effect is concentration-dependent with an EC 50 (effective concentration, 50%) of 5–10 n M and also occurs in the presence of reduced levels of extracellular calcium. The egg-induced zona pellucida modification is not elicited by several other inositol phosphates that are not able to release calcium from intracellular stores in other systems. Analysis of individual eggs microinjected with IP 3 reveals a strong correlation between a reduced binding of sperm to the zona pellucida and the ZP2 to ZP2 f conversion. In addition, solubilized zonae pellucidae isolated from IP 3-injected eggs possess reduced levels of acrosome reaction-inducing activity. These egg-induced modifications of the zona pellucida—reduced sperm receptor and acrosome reaction-inducing activities and the ZP2 to ZP2 f conversion—elicited by microinjected-IP 3 are similar to those that occur following fertilization. Results of these experiments suggest that IP 3 generated in response to fertilization may play a role in the egg-induced modifications of the zona pellucida that result in the polyspermy block.

Zona Pellucida-Induced Acrosome Reaction in Boar Sperm1

Induction of the acrosome reaction in boar sperm by the zona pellucida (ZP) was investigated. A modified cytochemical staining method for measuring the acrosome reaction in boar sperm gave equivalent results to those obtained with transmission electron microscopy. Isolated heat-solubilized ZP effectively induced the acrosome reaction in boar sperm at a concentration of 25 micrograms/ml. Electrophoretically purified ZP components were also tested for acrosome reaction-inducing activity; both the 55,000 and 90,000 components of the ZP were effective. The carbohydrate moiety of the 55,000 component was necessary for activity because the polypeptides derived by chemical deglycosylation of the two glycoproteins did not induce the acrosome reaction.

Effects of a phorbol ester on mouse eggs: Dissociation of sperm receptor activity from acrosome reaction-inducing activity of the mouse zona pellucida protein, ZP3

Biologically active phorbol esters or a diacylglycerol induce mouse eggs to modify the zona pellucida such that sperm receptor activity is retained but the ability of bound sperm to undergo a complete acrosome reaction is lost (Y. Endo, R. M. Schultz, and G. S. Kopf. 1987. Dev. Biol. 119, 199–209). We now show that purified ZP3 from 12- O-tetradecanoyl phorbol-13-acetate (TPA)-treated eggs possesses full sperm receptor activity but has lost its ability to induce a complete acrosome reaction. The modification of the acrosome reaction-inducing activity of ZP3 from these TPA-treated eggs differs from ZP3 isolated from two-cell embryos, which cannot initiate the acrosome reaction. These results demonstrate the dissociation of the two biological activities of ZP3 and may provide a system to assess the components of ZP3 involved in the acrosome reaction.

Nature of the mouse egg's receptor for sperm.

The zona pellucida is an extracellular coat that surrounds all mammalian eggs. Sperm must penetrate the zona pellucida in order to reach and fuse with the plasma membrane of unfertilized eggs. Penetration is accomplished by a sequence of events involving both egg and sperm. First, sperm must bind to the outer margin of the zona pellucida. Such binding is mediated in a relatively species-specific manner by "sperm receptors" in the zona pellucida. Second, sperm must undergo the "acrosome reaction", a membrane fusion event, in order to traverse the zona pellucida. Here we review results from our own laboratory which demonstrate that, during the course of sperm-egg interaction in mice, zona pellucida glycoprotein ZP3 serves as both receptor for sperm and inducer of the acrosome reaction. Furthermore, we review evidence from our laboratory indicating that the sperm receptor activity of ZP3 is dependent only on its 0-linked carbohydrate components, whereas acrosome reaction-inducing activity is dependent on the polypeptide portion of ZP3 as well.

Enzymatic dissection of the functions of the mouse egg's receptor for sperm

During the course of sperm-egg interaction in mice, zona pellucida glycoprotein ZP3 (⋍80 kDa) serves as both receptor for sperm ( J. D. Bleil and P. M. Wassarman, 1980c, Cell 20, 873–882 ) and inducer of the acrosome reaction ( J. D. Bleil and P. M. Wassarman, 1983, Dev. Biol. 95, 317–324) . In this investigation, small ZP3 glycopeptides (⋍1.5–6 kDa), obtained by extensive digestion of the purified glycoprotein with insoluble Pronase, were assayed for both sperm receptor and acrosome reaction-inducing activities. While ZP3 glycopeptides were virtually as effective as intact ZP3 in inhibiting binding of sperm to eggs in vitro (“receptor activity”), unlike intact ZP3, they failed to induce sperm to undergo the acrosome reaction. The latter was determined by indirect immunofluorescence using a monoclonal antibody directed against the acrosomal cap region of sperm. These results suggest that the sperm receptor activity of ZP3 is dependent only on its carbohydrate components, whereas acrosome reaction-inducing activity is dependent on the polypeptide chain of ZP3 as well.

Induction of the acrosome reaction on the surface of de-jellied sea urchin eggs

The vitelline coat of sea urchin eggs was disrupted by DTT and trypsin after removal of the jelly layer. Thereafter the percentage of acrosome reaction was determined and the fertilization rate was estimated, employing the treated eggs. Electron microscopical investigation of these eggs showed that the vitelline coat was disrupted but no morphological difference was observed between eggs treated with DTT and those treated with trypsin. However, the fertilizability of the eggs was markedly decreased by the treatment with trypsin. In contrast, DTT treatment did not affect the fertilizability of the eggs, indicating that some surface substance(s) necessary for fertilization which were not eliminated by DTT were digested by trypsin. At the same time, the percentage of acrosome reaction of supernumerary spermatozoa in the presence of variously treated eggs was estimated as an index of the acrosome reaction-inducing activity of the egg surface. The acrosome reaction of spermatozoa actually occurred at the surface of de-jellied and DTT-treated eggs. However, the eggs treated with trypsin lost the capacity to induce the acrosome reaction. The surface substance which induces the acrosome reaction and renders the eggs fertile was removed by trypsin and found in the supernatant fraction. The necessity of an acrosome reaction for fertilization was demonstrated by the fact that the low fertilizability of trypsin-treated eggs was brought back to the control level by insemination with spermatozoa previously treated with egg water to evoke the reaction of the acrosomes.

Mammalian sperm capacitation and fertilization in vitro: A critique of methodology

Mammalian sperm capacitation and fertilization in vitro: A critique of methodology

Biochemical Studies of the in vitro Acrosome Reaction Inducing Activity of Bovine Serum Albumin

Summary It is known that the acrosome reaction, a fusion, vesiculation and loss of sperm head membranes essential for fertilization can be induced in hamster sperm by incubation with bovine serum albumin (BSA) and a low molecular weight motility factor. The present report describes biochemical studies of the in vitro acrosome reaction-inducing activity of BSA. Phase contrast microscopy was used to detect the acrosome reactions of motile hamster sperm. Sperm preincubated for several hours with motility factor and a BSA poor in acrosome reaction-inducing activity underwent a relatively high percentage of acrosome reactions 15–40 min after addition of a BSA high in acrosome reaction-inducing activity. Charcoal treatment at acid pH reduced the fatty acid content of BSA and improved the acrosome reaction-inducing ability of BSA several fold. When the charcoal-treated BSA was refatted with palmitic acid or oleic acid, the increased acrosome reaction-inducing activity was lost. Pepsin hydrolysis of a BSA purified to immunoelectrophoretic homogeneity and reduced in fatty acid content by TCA-ethanol treatment destroyed the ability of that BSA to form a precipitate with rabbit anti-BSA. However, the pepsin hydrolysate was as efficient in the induction of the acrosome reaction as the unhydrolyzed control if a small amount of BSA poor in acrosome reaction-reducing activity was present to sustain sperm viability. Most of the acrosome reaction-inducing activity of the hydrolysate was retained after dialysis and ultrafiltration with an Amicon PM-30 membrane. These results suggest that albumin does indeed play a role in the induction of the hamster sperm acrosome reaction rather than just in capacitation. The results also indicate that the intact albumin molecule is not necessary for the acrosome reaction-inducing activity; and that the ligand content of albumin can influence its effectiveness in the induction of the acrosome reaction.