Shawn Zimmerman

Sperm Proteasomes Degrade Sperm Receptor on the Egg Zona Pellucida during Mammalian Fertilization

Despite decades of research, the mechanism by which the fertilizing spermatozoon penetrates the mammalian vitelline membrane, the zona pellucida (ZP) remains one of the unexplained fundamental events of human/mammalian development. Evidence has been accumulating in support of the 26S proteasome as a candidate for echinoderm, ascidian and mammalian egg coat lysin. Monitoring ZP protein degradation by sperm during fertilization is nearly impossible because those few spermatozoa that penetrate the ZP leave behind a virtually untraceable residue of degraded proteins. We have overcome this hurdle by designing an experimentally consistent in vitro system in which live boar spermatozoa are co-incubated with ZP-proteins (ZPP) solubilized from porcine oocytes. Using this assay, mimicking sperm-egg interactions, we demonstrate that the sperm-borne proteasomes can degrade the sperm receptor protein ZPC. Upon coincubation with motile spermatozoa, the solubilized ZPP, which appear to be ubiquitinated, adhered to sperm acrosomal caps and induced acrosomal exocytosis/formation of the acrosomal shroud. The degradation of the sperm receptor protein ZPC was assessed by Western blotting band-densitometry and proteomics. A nearly identical pattern of sperm receptor degradation, evident already within the first 5 min of coincubation, was observed when the spermatozoa were replaced with the isolated, enzymatically active, sperm-derived proteasomes. ZPC degradation was blocked by proteasomal inhibitors and accelerated by ubiquitin-aldehyde(UBAL), a modified ubiquitin protein that stimulates proteasomal proteolysis. Such a degradation pattern of ZPC is consistent with in vitro fertilization studies, in which proteasomal inhibitors completely blocked fertilization, and UBAL increased fertilization and polyspermy rates. Preincubation of intact zona-enclosed ova with isolated active sperm proteasomes caused digestion, abrasions and loosening of the exposed zonae, and significantly reduced the fertilization/polyspermy rates after IVF, accompanied by en-mass detachment of zona bound sperm. Thus, the sperm borne 26S proteasome is a candidate zona lysin in mammals. This new paradigm has implications for contraception and assisted reproductive technologies in humans, as well as animals.

The sperm proteasome during sperm capacitation and fertilization

The 26S proteasome is a multi-subunit protease specifically targeting ubiquitinated proteins. A consensus has emerged from studies by multiple laboratories on the role of sperm-borne proteasomes in human, mouse, pig, bovine, ascidian and echinoderm fertilization. Major findings from the studies in various mammalian and non-mammalian fertilization systems are (1) proteasomes are present in the mammalian sperm acrosome and on the acrosomal surface; (2) ubiquitinated proteins are present on the mammalian, ascidian and echinoderm egg coat; (3) proteasomal proteolytic and ubiquitin-deconjugating (deubiquitinating) activities can be detected in viable, motile mammalian spermatozoa; (4) proteasomes remain associated with the sperm head following ZP-induced acrosomal exocytosis; (5) inhibition of ubiquitination and proteasomal proteolysis blocks fertilization in mammals, ascidians and echinoderms; (6) inhibition of proteasomal proteolysis alters the course of mammalian sperm capacitation and acrosomal exocytosis induced by sperm binding to the egg coat, zona pellucida (ZP); (7) depletion of the sperm surface-associated ATP blocks porcine and echinoderm fertilization, most likely by affecting the integrity of sperm proteasomes, of which several subunits are ATPases; (8) inhibition of proteasomal proteolysis blocks sperm-ZP penetration, but does not alter the rate of sperm-ZP binding in mammals, and (9) experimental modification of sperm-associated deubiquitinating activities shifts the balance of monospermic fertilization to polyspermic fertilization in vitro. Altogether, these studies provide evidence for the involvement of the 26S proteasome in multiple steps of animal and human fertilization, offering a novel model of sperm-egg coat interactions, and identifying a range of potential new sperm quality markers and contraceptive targets.

Peroxiredoxin 2 and Peroxidase Enzymatic Activity of Mammalian Spermatozoa

Abstract Peroxiredoxin 2 (PRDX2) is a highly efficient redox protein that neutralizes hydrogen peroxide, resulting in protection of cells from oxidative damage and in regulation of peroxide-mediated signal transduction events. The oxidized form of PRDX2 is reverted back to the reduced form by the thioredoxin system. In the present study, we investigated the presence of PRDX2 in mouse and boar spermatozoa and in mouse spermatids using proteomic techniques and immunocytochemistry. Sperm and spermatid extracts displayed a 20-kDa PRDX2 band on Western blotting. PRDX2 occurred as a Triton-soluble form in spermatids and as a Triton-insoluble form in mature spermatozoa. Boar seminiferous tubule extracts were immunoprecipitated with PRDX2 antibody and separated by SDS-PAGE. Peptide mass fingerprinting by matrix-assisted laser desorption ionization-time of flight (TOF) and microsequencing by nanospray quadrupole-quadrupole TOF tandem mass spectrometry revealed the presence of PRDX2 ions in the immunoprecipitated band, along with sperm mitochondria-associated cysteine-rich protein, cellular nucleic acid-binding protein, and glutathione peroxidase 4. In mouse spermatocytes and spermatids, diffuse labeling of PRDX2 was observed in the cytoplasm and residual bodies. After spermiation, PRDX2 localization became confined to the mitochondrial sheath of the sperm tail midpiece. Boar spermatozoa displayed similar PRDX2 localization as in mouse spermatozoa. Boar spermatozoa with disrupted acrosomes expressed PRDX2 in the postacrosomal sheath region. Peroxidase enzyme activity of boar sperm extracts was evaluated by estimating the rate of NADPH oxidation in the presence or absence of a glutathione depletor (diethyl maleate) or a glutathione reductase inhibitor (carmustine). Diethyl maleate partially inhibited peroxidase activity, whereas carmustine showed an insignificant effect. These observations suggest that glutathione and glutathione reductase activity contribute only partially to the total peroxidase activity of the sperm extract. While the specific role of PRDX2 in the total peroxidase activity of sperm extract is still an open question, the present study for the first time (to our knowledge) shows the presence of PRDX2 in mammalian spermatozoa. Peroxidase activity in sperm extracts is not due to the glutathione system and therefore possibly involves PRDX2 and other peroxiredoxins.

Ubiquitin-activating enzyme (UBA1) is required for sperm capacitation, acrosomal exocytosis and sperm-egg coat penetration during porcine fertilization.

Protein ubiquitination is a stable, covalent post-translational modification that alters protein activity and/or targets proteins for proteolysis by the 26S proteasome. The E1-type ubiquitin-activating enzyme (UBA1) is responsible for ubiquitin activation, the initial step of ubiquitin-protein ligation. Proteasomal proteolysis of ubiquitinated spermatozoa and oocyte proteins occurs during mammalian fertilization, particularly at the site of sperm acrosome contact with oocyte zona pellucida. However, it is not clear whether the substrates are solely proteins ubiquitinated during gametogenesis or if de novo ubiquitination also occurs during fertilization supported by ubiquitin-activating and -conjugating enzymes present in the sperm acrosome. Along this line of inquiry, UBA1 was detected in boar sperm-acrosomal extracts by Western blotting (WB). Immunofluorescence revealed accumulation of UBA1 in the nuclei of spermatogonia, spermatocytes and spermatids, and in the acrosomal caps of round and elongating spermatids. Thiol ester assays utilizing biotinylated ubiquitin and isolated sperm acrosomes confirmed the enzymatic activity of the resident UBA1. A specific UBA1 inhibitor, PYR-41, altered the remodelling of the outer acrosomal membrane (OAM) during sperm capacitation, monitored using flow cytometry of fluorescein isothiocyanate-conjugated peanut agglutinin (FITC-PNA). Although viable and motile, the spermatozoa capacitated in the presence of PYR-41, showed significantly reduced fertilization rates during in vitro fertilization (IVF; p < 0.05). Similarly, the fertilization rate was lowered by the addition of PYR-41 directly into fertilization medium during IVF. In WB, high Mr bands, suggestive of protein ubiquitination, were detected in non-capacitated spermatozoa by antibodies against ubiquitin; WB with anti-phosphotyrosine antibodies and antibodies against acrosomal proteins SPINK2 (acrosin inhibitor) and AQN1 (spermadhesin) revealed that the capacitation-induced modification of those proteins was altered by PYR-41. In summary, it appears that de novo protein ubiquitination involving UBA1 contributes to sperm capacitation and acrosomal function during fertilization.

Interference with the 19S proteasomal regulatory complex subunit PSMD4 on the sperm surface inhibits sperm-zona pellucida penetration during porcine fertilization

Proteolysis of ubiquitinated sperm and oocyte proteins by the 26S proteasome is necessary for the success of mammalian fertilization, including but not limited to acrosomal exocytosis and sperm-zona pellucida (ZP) penetration. The present study examined the role of PSMD4, an essential non-ATPase subunit of the proteasomal 19S regulatory complex responsible for proteasome-substrate recognition, in sperm-ZP penetration during porcine fertilization in vitro (IVF). Porcine sperm-ZP penetration, but not sperm-ZP binding, was blocked in the presence of a monoclonal anti-PSMD4 antibody during IVF. Inclusion in the fertilization medium of mutant ubiquitins (Ub+1 and Ub5+1), which are refractory to processing by the 19S regulatory complex and associated with Alzheimer’s disease, also inhibited fertilization. This observation suggested that subunit PSMD4 is exposed on the sperm acrosomal surface, a notion that was further supported by the binding of non-cell permeant, biotinylated proteasomal inhibitor ZL3VS to the sperm acrosome. Immunofluorescence localized PSMD4 in the sperm acrosome. Immunoprecipitation and proteomic analysis revealed that PSMD4 co-precipitated with porcine sperm-associated acrosin inhibitor (AI). Ubiquitinated species of AI were isolated from boar sperm extracts by affinity purification of ubiquitinated proteins using the recombinant UBA domain of p62 protein. Some proteasomes appeared to be anchored to the sperm head inner acrosomal membrane, as documented by co-fractionation studies. In conclusion, the 19S regulatory complex subunit PSMD4 is involved in the sperm-ZP penetration during fertilization. The recognition of substrates on the ZP by the 19S proteasomal regulatory complex is essential for the success of porcine/mammalian fertilization in vitro.

Discovery of putative oocyte quality markers by comparative ExacTag proteomics

Purpose: Identification of the biomarkers of oocyte quality, and developmental and reprogramming potential is of importance to assisted reproductive technology in humans and animals.

Identification and characterization of RING-finger ubiquitin ligase UBR7 in mammalian spermatozoa

The ubiquitin-proteasome system (UPS) controls intracellular protein turnover in a substrate-specific manner via E3-type ubiquitin ligases. Mammalian fertilization and particularly sperm penetration through the oocyte vitelline coat, the zona pellucida (ZP), is regulated by UPS. We use an extrinsic substrate of the proteasome-dependent ubiquitin-fusion degradation pathway, the mutant ubiquitin UBB+1, to provide evidence that an E3-type ligase activity exists in sperm-acrosomal fractions. Protein electrophoresis gels from such de novo ubiquitination experiments contained a unique protein band identified by tandem mass spectrometry as being similar to ubiquitin ligase UBR7 (alternative name: C14ORF130). Corresponding mRNA was amplified from boar testis and several variants of the UBR7 protein were detected in boar, mouse and human sperm extracts by Western blotting. Genomic analysis indicated a high degree of evolutionary conservation, remarkably constant purifying selection and conserved testis expression of the UBR7 gene. By immunofluorescence, UBR7 was localized to the spermatid acrosomal cap and sperm acrosome, in addition to hotspots of proteasomal activity in spermatids, such as the cytoplasmic lobe, caudal manchette, nucleus and centrosome. During fertilization, UBR7 remained with the ZP-bound acrosomal shroud following acrosomal exocytosis. Thus, UBR7 is present in the acrosomal cap of round spermatids and within the acrosomal matrix of mature boar spermatozoa. These data provide the first evidence of ubiquitin ligase activity in mammalian spermatozoa and indicate UBR7 involvement in spermiogenesis.

Carbohydrate-Mediated Binding and Induction of Acrosomal Exocytosis in a Boar Sperm-Somatic Cell Adhesion Model

The molecular basis underlying the binding of spermatozoa to their homologous eggs and the subsequent induction of acrosomal exocytosis remain a major unresolved issue in mammalian fertilization. Novel cell adhesion systems are now being explored to advance this research. Triantennary and tetraantennary N-glycans have previously been implicated as the major carbohydrate sequences that mediate the initial binding of spermatozoa to the specialized egg coat (zona pellucida) in the murine and porcine models. Mouse spermatozoa also undergo binding to rabbit erythrocytes (rRBCs), presumably via the interaction of their lectin-like egg-binding proteins with branched polylactosamine sequences present on these somatic cells. Experiments presented in this study confirm that boar spermatozoa also bind to rRBCs. However, unlike mouse spermatozoa, boar spermatozoa also undergo acrosomal exocytosis within 30 min after binding to rRBCs. Both binding and induction of acrosomal exocytosis in this system did not require the participation of terminal Galalpha1-3Gal sequences that are found on rRBCs. Pronase glycopeptides derived from rRBCs inhibited the binding of boar sperm to porcine oocytes by 91% at a final concentration of 0.3 mg/ml under standard IVF conditions. Binding in this porcine cell adhesion model was also completely blocked at this concentration of glycopeptide. Thus, adhesion results from the interaction of the egg-binding protein expressed on the surface of boar spermatozoa with the glycans presented on rRBCs. This cell adhesion model will be useful for investigating the molecular basis of gamete binding and the induction of acrosomal exocytosis in the pig.

Gamete Binding and Fusion

Successful mammalian fertilization results in the union of two gametes, a spermatozoon and a mature oocyte. Membrane fusion events are essential for at least two distinct steps of the fertilization process: (i) the vesiculation of the acrosomal surface membranes during sperm acrosomal exocytosis (AE), induced by sperm binding to the egg-coat, and (ii) fusion of the oocyte plasma membrane, the oolemma, with the sperm plasma membrane that occurs after AE and sperm-egg coat penetration. The rearrangement of sperm plasma membrane domains/membrane lipid raft formation during sperm capacitation in the female reproductive tract is a priming step that enables the fusion and vesiculation of outer acrosomal membranes during AE. The membrane fusion/vesiculation events of AE seem to share similarities with synaptic vesicle fusion, assisted by the membrane proteins of the SNARE hypothesis. The AE exposes the transmembrane receptors on the sperm head equatorial segment in preparation for sperm-oolemma adhesion and fusion. Gene ablation studies indicate that the tetraspanin family proteins CD9 and CD81 on the oolemma interact with the superglobulin family protein IZUMO on the sperm plasmalemma to mediate sperm-oolemma adhesion in mammals. The fusogenicity of IZUMO has not been established, so the involvement of this system in the actual membrane fusion part of sperm–oolemma interaction remains open. Interactions of ADAM family proteins on sperm plasma membrane with oolemma integrins appear non-essential during sperm-oolemma fusion, but integrins may play a supporting role via sustenance of the tetraspanin web in the oocyte cortex. Sperm-oolemma binding may be reinforced by a cast of other receptors found on the surface of the sperm head (e.g. CRISP and MN9). The present chapter reviews recent progress in the study of these fundamental factors of gamete membrane fusion during mammalian fertilization.