An MN9 antigenic molecule, equatorin, is required for successful sperm-oocyte fusion in mice

Unresolved Issues in Mammalian Fertilization

This review considers the role of the sperm in fertilization, addressing areas of misunderstanding and unfounded assumptions and taking particular advantage of the large body of data resulting from work with rodent species in vitro. Considerable attention is given to the appropriate use and interpretation of assays for capacitation, acrosomal exocytosis, hyperactivation, and sperm protein phosphorylation, as well as tests for sperm-zona and sperm-oocyte membrane interactions. The lack of general agreement on the means of sperm adhesion to and penetration of the zona pellucida is addressed, and the need for new approaches to this problem is pointed out. Some molecular advances in our understanding of specific steps in the process of fertilization are discussed in the context of intact cell-matrix and cell-cell interaction. This review should provide practical information for researchers just beginning the study of fertilization and interesting but not widely known observations to stimulate new ideas in experienced scientists.

Cell adhesion and fertilization: steps in oocyte transport, sperm-zona pellucida interactions, and sperm-egg fusion

Fertilization in mammals requires the successful completion of many steps, starting with the transport of gametes in the reproductive tract and ending with sperm-egg membrane fusion. In this minireview, we focus on three adhesion steps in this multistep process. The first is oocyte "pick-up," in which the degree of adhesion between the extracellular matrix of the cumulus cells and oviductal epithelial cells controls the successful pick-up of the oocyte-cumulus complex and its subsequent transfer into the oviduct. The second part of this review is concerned with the interaction between the sperm and the zona pellucida of the egg. Evidence is discussed that a plasma membrane form of galactosyltransferase on the surface of mouse sperm binds to ZP3 in the zona pellucida and initiates an acrosome reaction. Additional evidence raises the possibility that initial sperm binding to the zona pellucida is independent of ZP3. Last, we address the relationship between sperm adhesion to the egg plasma membrane and membrane fusion, especially the role of ADAM family proteins on the sperm surface and egg integrins.

Identification of the 48-kDa G11 protein from guinea pig testes as sperad

A protein found specifically in the membrane of spermatozoa called G11 has been implicated in sperm-egg binding and fusion. This study describes purification and identification of the G11 antigen. The G11 protein was purified using anion exchange chromatography, immunoaffinity chromatography and preparative SDS-PAGE and was subjected to amino acid microsequencing by tandem mass spectrometry. Internal amino acid sequence data derived from the 48-kDa G11 protein revealed that G11 is the recently discovered guinea pig sperm protein, sperad. Sperad is a transmembrane protein present in the periacrosomal plasma membrane of guinea pig sperm. The cytoplasmic domain of sperad was amplified from a guinea pig testes cDNA expression library by polymerase chain reaction and cloned into a prokaryotic gene expression vector, pGEX-2T. The recombinant glutathione S-transferase fusion protein was immunoblotted with monoclonal antibody G11. The results obtained from this study confirmed the monoclonal antibody G11 epitope location on the cytoplasmic domain of sperad.

Identification and characterization of cystatin-related epididymal spermatogenic protein in human spermatozoa: localization in the equatorial segment

Our earlier studies in mouse have shown that the cystatin-related epididymal spermatogenic (CRES) protein is highly expressed in elongating spermatids in the testis and is present in mouse sperm acrosomes, suggesting specific roles in sperm function, fertilization, or both. However, whether the human CRES gene is similar to that of the mouse and is expressed in germ cells has not yet been determined. Therefore, the present study was undertaken to characterize the human ortholog of mouse CRES: Northern blot and in situ hybridization experiments showed that CRES is highly expressed in the human testis, specifically within clusters of round spermatids. Furthermore, reverse transcription-polymerase chain reaction detected CRES mRNA in the epididymis. Western blot analysis of protein lysates prepared from human testis and ejaculated spermatozoa showed a predominant 19-kDa protein and a minor 14-kDa protein. However, in contrast to the acrosomal localization of CRES protein in mouse spermatozoa, indirect immunofluorescence of human spermatozoa treated with methanol/acetic acid using anti-human CRES antibodies revealed that CRES was strictly localized to the equatorial segment. Furthermore, the same staining was observed in both capacitated and acrosome-reacted spermatozoa. To determine whether CRES was associated with the plasma membrane, live spermatozoa were incubated with CRES antibody after capacitation and acrosome reaction. Only acrosome-reacted spermatozoa showed a weak but specific equatorial staining. Taken together, these studies show that CRES protein is present in the sperm equatorial segment and becomes accessible to the extracellular environment during fertilization.

Exposure of sperm head equatorin after acrosome reaction and its fate after fertilization in mice

Equatorin is a sperm head equatorial protein, possibly involved in sperm-oocyte fusion (Toshimori et al., Biol Reprod 1998; 59:22-29). In the present work, we have shown that equatorin contained in the posterior acrosome is detectable only after spontaneous or induced acrosome reactions following fixation and permeabilization, but not in intact spermatozoa. The presence of protease inhibitors during sonication or ionophore treatments does not inhibit the exposure of the antigenic epitope. The zona-penetrated spermatozoa lying in the perivitelline space display equatorin, similar to those of the acrosome-reacted ones. After sperm-egg fusion during in vitro fertilization (IVF), the equatorin dissociates from the sperm head equatorial region and remains at the vicinity of the decondensing male pronuclei. During pronuclear apposition stage, it is pushed away from the pronuclei, possibly by the perinuclear microtubules. After first cleavage, equatorin is inherited by one of the proembryonic cells. The residual equatorin disappears after the second cleavage. Microinjected whole spermatozoa or sperm heads into the MII stage oocytes display equatorin similar to those of the perivitelline sperm. After activation, it dissociates from the sperm nuclei in a similar manner as during IVF. The mode of equatorin degeneration during fertilization is similar to those of the sperm tail components or mitochondria, but different from those of the membrane associated proteins.

Isolation and characterisation of two sperm membrane proteins recognised by sperm-associated antibodies in infertile men

Antisperm antibodies eluted from the surface of spermatozoa obtained from infertile men recognised several common epitopes. We tested whether these epitopes were relevant to fertility by isolating the immunodominant 37/36 and 19/18 protein zones. These protein zones were cut out of preparative slab gels and electro-eluted. The isolated proteins, P36 and P18, were used for biochemical characterisation and to produce specific antibodies in rabbits. The specific reactivity of P36 and P18 with WGA and AAL lectins, respectively, indicated the presence of lactosaminyl structures with sialic acid termini in P36 and of fucosylated residues in P18. Isoelectric focusing showed that the two proteins consist of several polypeptides. Some of these polypeptides were recognised by both human and rabbit antibodies: the pl of these epitopes was around 5.5 for P36 and 8.3-10.3 for P18. Rabbit antibodies detected the corresponding proteins on the sperm heads of methanol-fixed and of live acrosome-reacted spermatozoa. Anti-P36 antibodies bound mainly to the equatorial segment. They reduced the binding and, consequently, the penetration of zona-free hamster oocytes by human spermatozoa. Anti-P18 antibodies gave more diffuse staining of the acrosomal and post-acrosomal regions and reduced sperm-oocyte penetration without a significant effect on sperm binding. These results suggest that P36 and P18 antigens located in different compartments of the sperm head may participate in the sperm-oolemma interaction. We are currently investigating the physiological role of these antigens by sequencing the proteins isolated from the gels.

Mammalian sperm-egg fusion: evidence that epididymal protein DE plays a role in mouse gamete fusion

Rat epididymal protein DE associates with the sperm surface during epididymal maturation and is a candidate molecule for mediating gamete membrane fusion in the rat. Here, we provide evidence supporting a role for DE in mouse sperm-egg fusion. Western blot studies indicated that the antibody against rat protein DE can recognize the mouse homologue in both epididymal tissue and sperm extracts. Indirect immunofluorescence studies using this antibody localized the protein on the dorsal region of the acrosome. Experiments in which zona-free mouse eggs were coincubated with mouse capacitated sperm in the presence of DE showed a significant and concentration-dependent inhibition in the percentage of penetrated eggs, with no effect on either the percentage of oocytes with bound sperm or the number of sperm bound per egg. Immunofluorescence experiments revealed specific DE-binding sites on the fusogenic region of mouse eggs. Because mouse sperm can penetrate zona-free rat eggs, the participation of DE in this interaction was also investigated. The presence of the protein during gamete coincubation produced a significant reduction in the percentage of penetrated eggs, without affecting the binding of sperm to the oolemma. These observations support the involvement of DE in an event subsequent to sperm-egg binding and leading to fusion in both homologous (mouse-mouse) and heterologous (mouse-rat) sperm-egg interaction. The lack of disintegrin domains in DE indicates that the protein interacts with its egg-binding sites through a novel mechanism that does not involve the reported disintegrin-integrin interaction.

Paternal contributions to the mammalian zygote: fertilization after sperm-egg fusion

Mammalian fertilization has traditionally been regarded as a simple blending of two gametes, during which the haploid genome of the fertilizing spermatozoon constitutes the primary paternal contribution to the resulting embryo. In contrast to this view, new research provides evidence of important cytoplasmic contributions made by the fertilizing spermatozoon to the zygotic makeup, to the organization of preimplantation development, and even reproductive success of new forms of assisted fertilization. The central role of the sperm-contributed centriole in the reconstitution of zygotic centrosome has been established in most mammalian species and is put in contrast with strictly maternal centrosomal inheritance in rodents. The complementary reduction or multiplication of sperm and oocyte organelles during gametogenesis, exemplified by the differences in the biogenesis of centrosome in sperm and oocytes, represents an intriguing mechanism for avoiding their redundancy during early embryogenesis. New studies on perinuclear theca of sperm revealed its importance for both spermatogenesis and fertilization. Remodeling of the sperm chromatin into a male pronucleus is guided by oocyte-produced, reducing peptide glutathione and a number of molecules required for the reconstitution of the functional nuclear envelope and nuclear skeleton. Although some of the sperm structures are transformed into zygotic components, the elimination of others is vital to early stages of embryonic development. Sperm mitochondria, carrying potentially harmful paternal mtDNA, appear to be eliminated by a ubiquitin-dependent mechanism. Other accessory structures of the sperm axoneme, including fibrous sheath, microtubule doublets, outer dense fibers, and the striated columns of connecting piece, are discarded in an orderly fashion. The new methods of assisted fertilization, represented by intracytoplasmic sperm injection and round spermatid injection, bypass multiple steps of natural fertilization by introducing an intact spermatozoon or spermatogenic cell into oocyte cytoplasm. Consequently, the carryover of sperm accessory structures that would normally be eliminated before or during the entry of sperm into oocyte cytoplasm persist therein and may interfere with early embryonic development, thus decreasing the success rate of assisted fertilization and possibly causing severe embryonic anomalies. Similarly, foreign organelles, proteins, messenger RNAs, and mitochondrial DNAs, which may have a profound impact on the embryonic development, are propagated by the nuclear transfer of embryonic blastomeres and somatic cell nuclei. This aspect of assisted fertilization is yet to be explored by a focused effort.

The potential use of sperm antigens as targets for immunocontraception; past, present and future

Immunocontraception, and in particular the targeting of antibodies to gamete-specific antigens implicated in sperm egg binding and fertilisation, offers an attractive approach to the growing global problem of overpopulation. Such an idea is not new; indeed several immunocontraception trials, using animal model systems, have been reported in recent years and a number are reviewed here. However, the results of these studies have been largely disappointing. We believe that two fundamental flaws attribute to the poor success of most of these preliminary immunocontraceptive trials. Firstly, loss of fertility has invariably been used as the assay. This presupposes that immuno-neutralisation of a single, gamete-specific antigen will be sufficient to cause a significant reduction in fertility; however, recent data suggests that such a premise may not be well-founded for a number of reasons. Secondly, and arguably the most important flaw, is the almost universal, but largely inappropriate, use of systemic immunisation as the sole route of antigen delivery. Whilst systemic immunisation regimes may lead to high serum IgG levels, these levels do not correlate with specific antibody levels in the reproductive tract or with contraceptive efficacy. Hence, an alternative antigen delivery approach is required which will induce an effective local immune response in the reproductive tract. Here we discuss the ways in which this might be achieved.