Mitochondrial and mitochondrial DNA (mtDNA) is maternally inherited in humans and most animals. The degradation of sperm-borne mitochondria after fertilization assures normal preimplantation embryo development and may prevent mitochondrial diseases derived from heteroplasmy. Although it has been known that ubiquitin-proteasome system (UPS) is the major degradation pathway of post-fertilization sperm mitochondria in mammals, it is unclear how the UPS, which is able to get rid of single protein molecule at a time, can eliminate whole sperm mitochondrial organelle. We considered that the autophagy receptors [sequestosome 1(SQSTM1), microtubule-associated protein 1 light chain 3 (LC3), and gamma-aminobutyric acid receptor-associated protein (GABARAP)] and the non-traditional mitophagy pathways involving UPS and the ubiquitin-binding protein dislocase, valosin-containing protein (VCP) may act independently or in concert during post-fertilization sperm mitophagy. We found that the association of SQSTM1 with sperm mitochondria was displayed in both pig and rhesus monkey zygotes after fertilization. Sperm mitochondrial proteins [mitochondrial trifunctional enzyme subunit alpha (HADHA), mitochondrial aconitase 2 (ACO2), and mitochondrial ATP synthase H+ transporting F1 complex β-subunit (ATP5B)] co-purified with the synthetic, SQSTM1-derived, ubiquitin-binding UBA domain were identified. Also, the accumulation of GABARAP-positive protein aggregates was observed around sperm mitochondrial sheaths in fertilized oocytes, which reflects autophagosome formation. Furthermore, the inhibition of VCP delayed the process of sperm mitophagy and completely blocked it when embryos were co-injected with autophagy-targeting antibodies, such as anti-SQSTM1 and/or anti-GABARAP. Thus, both SQSTM1-dependent autophagy pathway and VCP-mediated proteasomal proteolysis facilitate post-fertilization sperm mitophagy in mammals. This explains how the proteolytic pathway can coordinate autophagy pathway to degrade the sperm mitochondrial sheath inside the fertilized oocyte.

Sperm adhesion molecule 1 (SPAM1) and Hyaluronidase 5 (HYAL5) has been well-known as assistants for sperm penetrate through the cumulus mass surrounding the ovulated eggs. However, so far their role in mammalian fertilization remain elusive, because mouse sperm lacking SPAM1 or HYAL5 were still capable of penetrating the cumulus mass despite a delayed dispersal of cumulus mass. Those data collectively demonstrated that SPAM1 or HYAL5 deficiency alone was not sufficient to cause male infertility in mice. In the present study, SPAM1 and HYAL5-simultaneous deficient male mice model was generated. Because of inhibition in sperm hyaluronidases, SPAM1 and HYAL5-deficient male mice produced significantly smaller numbers of offspring than hetero type and wild type mice. Hyaluronic acid degradation assay and cumulus oocyte complex dispersal assay as well as sperm motility assay using double knock out sperm and extracts had severe adverse effects on the dispersal of cumulus oocyte complex, which was the main reason for the impaired fertility of double knock out male sperm. Moreover, hyaluronic acid degradation assay using human sperm extracts revealed that sperm hyaluronidase has a principal role in sperm penetration through the cumulus oocyte complex. In conclusion, our results suggest that sperm hyaluronidase deficiency may be sufficient to cause male sterility in mammal because SPAM1 and HYAL5 deficiency sperm not impaired the sperm motility in hyaluronic acid but also cumulus oocyte complex penetration.

Sperm competent for fertilization can become capacitated, bind to the zona pellucida (ZP) of an egg in a specific manner, and complete acrosomal exocytosis. Failure to carry out these functions results in infertility. Although the interactions between the ZP and the plasma mem-brane overlying the sperm acrosome have been considered important for sperm-egg recognition and signalling, recent results have prompted a reassessment of current paradigms concerning these interactions. In this review, we're going to discuss about the roles of the acrosomal matrix, the particulate component of the acrosomal contents, in fertilization. The general hypothesis is that acrosomal exocytosis leads to the exposure of acrosomal matrix proteins that become de-facto extracellular matrix (ECM) on the surface of the sperm head, and that the dynamic interactions of this newly-exposed sperm ECM with the egg ECM (the ZP) govern sperm-egg recognition and sperm penetration of the ZP Informations from these experiments may provide new ways to address the poor ZP binding of sperm from some human infertility patients and may offer new avenues for contraception through the disruption of purposeful sperm-ZP binding.