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.
Germ cell-specific hyaluronidases such as sperm adhesion molecule 1 (SPAM1) and hyaluronoglucosaminidase 5 (Hyal5) are in part responsible for dispersal of the cumulus cell mass, which is a critical step in establishing fertilization in mammals. In this study, we identified two testis-hyaluronidases, SPAM1 and Hyal5, in hamster and rat. These two genes were expressed specifically in the testis. At the protein level, hamster SPAM1 and Hyal5 display 78.7% and 75.4% identity with mouse SPAM1 and Hyal5. Further, the activity of the enzymes with respect to cumulus cell dispersion did not differ, although we observed that the enzymatic activity differed in pH range. These studies suggest that different sperm hyaluronidases are capable of dispersing the cumulus cell mass despite differences in enzyme activity.
During mammalian fertilization, germ cell-specific hyaluronidases, such as sperm adhesion molecule 1 (SPAM1) and hyaluronoglucosaminidase 5 (Hyal5), are important for the dispersal of the cumulus mass. In this study, we demonstrated that bull Hyal5 is a single copy gene on chromosome 4 that is expressed specifically in the testis. In addition, we expressed recombinant bull SPAM1 and Hyal5 in human embryonic kidney 293T cells and showed that these enzymes possessed hyaluronidase activity. We also demonstrated that a polyclonal antibody against bull sperm hyaluronidase inhibits sperm-egg interactions in an in vitro fertilization (IVF) assay. Our results suggested that bull Hyal5 may have a critical role in bull fertilization.
Members of the Vps (Vacuolar protein sorting) protein family involved in the formation of the retromer complex have been discovered in a variety of species such as yeast, mouse, and human. A mammalian retromer complex is composed of Vps26, Vps29, and Vps35 proteins and plays and important role in cation-independent mannose-6-phosphate receptor retrieval from the endosome to the trans-Golgi network. In this study, we have identified the full-length sequences of the retromer components of Vps26, Vps29, and Vps35 in micro pigs. The cDNA sequences of these retromer components have been determined and the result showed there is 99% homology among the component counterparts from mouse, micro pigs, and humans. In addition, the retromer complexes formed with hetero-components were found in the brain of micro pigs. Based on above results, we suggest mammalian Vps components are well conserved in micro pigs.
Mammalian spermatogenesis takes place in the seminiferousepithelium, which is composed of Sertoli cells and germ cells. The interaction between spermatogenic and Sertoli cells as well as elongated spermatids and Sertoli cells is tightly regulated by junctional adhesion molecules (JAMs). JAMs, which are cell adhesion molecules, are known to play roles in various biological processes such as fertilization, neurogenesis, cancer progression, and spermatogenesis. Members of the JAM family have a unique structure: they contain an N-terminal signal peptide domain, immunoglobulin (Ig)-like domains, transmembrane and cytoplasmic tail domains, each of which has distinct functions. The extracellular Ig-like domains interact in a homophilic or heterophilic manner, whereas cytoplasmic tail domain mediates the tight junction assembly. Although members of the JAM family are exclusively present in or restricted to the testis, their precise roles in spermatogenesis and fertilization have not yet been completely explored. The functional roles of Nectin-2, Nectin-3, JAM-C, cell adhesion molecule1 (CADM1), coxsackie and adenovirus receptor (CAR) have been evaluated by analysis of null mutant mice. Unfortunately, CAR-deficient mice had an embryonic lethal phenotype; this demonstrates the importance of CAR in development, but its physiological role in spermatogenesis is not known. The loss of CADM1, Nectin-3 and JAM-C resulted in male infertility caused by loss of adhesion between germ and Sertoli cells. A variety of JAMs participate in the interaction between germ and Sertoli cells. Recently, human VSIG1 has been characterized, which was originally known as A34, as a new member of the JAM family; VSIG1 is composed of two extracellular Ig-like domains, a transmembrane domain, and a cytoplasmic domain. However, this molecule has not been functionally characterized, so this was one of the aims of our present study. RT-PCR and immunoblot analyses were used to study VSIG1 expression, VSIG1 was specifically expressed in testicular germ cells but not in sperm. Pull-down assay with glutathione S-transferase (GST) or His-fused first Ig and second Ig domains of VSIG1 and SDS-PAGE under mild non-reducing conditions demonstrated that VSIG1 functions as an in vitro homophilic adhesion molecule. Furthermore, cells expressing a deletion of the C-terminus of VSIG1 failed to interact with ZO-1, the central structural protein of the tight junction. These findings suggest mouse VSIG1 interacts with an unknown molecule in Sertoli cells via its extracellular domain, while its cytoplasmic domain is needed for binding to ZO-1. Thus, we suggest mouse VSIG1 may play an important role in spermatogenesis rather than fertilization by forming heterophilic complex with a molecule similar to JAM family.