Sperm plasma membrane

About: Sperm plasma membrane is a research topic. Over the lifetime, 1016 publications have been published within this topic receiving 49964 citations.

The 26 kD protein recognized on rat cauda epididymal sperm by monoclonal antibody 4E9 has internal peptide sequence that is identical to the secreted form of epididymal protein E1

Abstract: MAb 4E9, raised against a detergent extract of rat cauda epididymal sperm, recognizes a 26 kD glycoprotein that is found on the plasma membrane of the sperm tail in cauda, but not caput, sperm (Moore et al., 1994). It also recognizes an epididymis-secreted protein that has been shown to be protein E (Xu and Hamilton, 1996). It is felt that the secreted protein becomes associated with sperm, but there has been no biochemical evidence of molecular identity between the secreted and membrane proteins. In this report, the membrane form of the antigen has been purified by reverse phase HPLC. Cyanogen bromide cleavage of the purified protein yielded 3 peptides that were purified, also by reverse phase HPLC. One of the peptides yielded an unambiguous sequence of 34 amino acids that is identical to an internal peptide of the protein found in epididymal fluid. This is the first report showing sequence identity between an epididymis-secreted protein and a protein of the sperm plasma membrane.

Possible involvement of a sialylated component of the sperm plasma membrane in sperm‐zona interaction in the mouse

Abstract: We have studied the molecular mechanisms of gamete interaction in vitro in the laboratory mouse, Mus musculus. In particular, we were interested in whether this interaction is similar to a lectin-hapten-mediated process. Inhibition of sperm-zona binding was examined using various concentrations (.25 mM to 50 mM) of different sugars (sialic acid α-methylmannose, glucose, fucose, galactose, and N-acetyl-glucosamine). Sperm-zona binding was significantly decreased when eggs were pretreated with 10 mM of sialic acid or α-methylmannose but not by other sugars tested. Furthermore, treatment of capacitated sperm with neuraminidase destroyed their ability to bind and fertilize eggs. We have also used a specific lectin for sialic acid from the horseshoe crab (Limulus polyphemus) to agglutinate mouse sperm. The lectin (.120 ng/ml) mediated agglutination of mouse sperm (105 sperm/ml) was routinely observed to increase from a 10% agglutination immediately following their isolation from the epididymis to 100% agglutination 90 minutes later. Collectively, these results suggest the appearance of specific sugar moieties on the surface of the sperm plasma membrane which, in this particular species of mouse, are sialylated glycoproteins acting as ligands for specific receptors on the surface of the egg. These are the first data to indicate that sperm-egg recognition and attachment is a lectin-hapten-mediated process in the mouse.

Fertilization and development of mouse oocytes injected with membrane-damaged spermatozoa.

Abstract: The objective of this study was to investigate the influence of sperm plasma membrane on fertilization and development in a mouse model. The sperm plasma membrane was destroyed by exposure to Triton X-100 prior to intracytoplasmic sperm injection (ICSI). A single sperm curling (SSC) test was used to evaluate cell viability. The fertilization rates of oocytes obtained following ICSI of membrane-damaged sperm was not significantly higher than that of the control group (62.4 versus 59.6%). Rates of development to blastocyst were also not significantly different (51.7 and 50%). Inner cell mass (ICM) and total embryo cell numbers in the two groups were not statistically different (16 +/- 3.7 versus 14.73 +/- 3.35 and 45.8 +/- 12.5 versus 39.5 +/- 12 respectively). There were no differences in the implantation and live fetus rates between the two groups after transfer to pseudopregnant mice (61.5 and 35.9% respectively for the membrane-damaged group and 53.5 and 31.4% for the intact group). In conclusion, the present study clearly shows that destruction of the sperm plasma membrane does not affect fertilization and further development following injection of membrane-damaged spermatozoa into mouse oocytes. Fertilization and development can be achieved by dead spermatozoa at an early stage of necrosis when only the plasma membrane has been damaged.

002. Human spermatozoa: fruits of creation, seed of doubt

Abstract: Defective sperm function is the largest defined cause of human infertility, affecting one in twenty Australian males. Despite its prevalence, we are only just beginning to understand the underlying mechanisms. The past decade has seen two major advances in this field: (1) the discovery that Y chromosome deletions play a key role in the aetiology of non-obstructive azoospermia/oligozoospermia; and (2) recognition that oxidative stress can impact upon the functional competence of human spermatozoa through peroxidative damage to the sperm plasma membrane. Oxidative stress has also been found to disrupt the integrity of DNA in the male germ line and may represent an important mechanism by which environmental impacts on human health are mediated. Thus, paternal exposure to various toxicants (cigarette smoke, organic solvents, heavy metals) has been linked with oxidative DNA damage in spermatozoa and developmental defects, including cancer, in the F1 generation. The male germ line becomes particularly vulnerable to such factors during the post meiotic stages of differentiation. Pre-meiotic germ cells always have the option of undergoing apoptosis if DNA damage is severe. However, post meiotic germ cells have lost both the ability to mount an apoptotic response and the capacity for DNA repair. As a result, germ cells are particularly vulnerable to genotoxic agents during spermiogenesis and epididymal maturation. If the fertilizing capacity of the spermatozoa is retained following toxicant exposure, then DNA damage will be transferred to the zygote and must be repaired subsequently by the oocyte and/or early embryo. Aberrant DNA repair at this stage has the potential to create mutations that will compromise embryonic development and, ultimately, the normality of the offspring. Elucidating the causes of oxidative damage in spermatozoa should help resolve the aetiology of conditions such as male infertility, early pregnancy loss and childhood disease, including cancer.