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THE IDENTIFICATION AND CHARACTERIZATION OF AN INNER ACROSOMAL MEMBRANE ASSOCIATED PROTEIN, IAM38, RESPONSIBLE FOR SECONDARY SPERM-ZONA BINDING DURING FERTILIZATIONYu, YANG 27 November 2008 (has links)
During mammalian fertilization, the exposure of the inner acrosomal membrane (IAM) after acrosomal exocytosis is essential for the secondary binding between sperm and zona pellucida (ZP) of the oocyte, a prerequisite for sperm penetration through the ZP. The identification of the sperm protein(s) responsible for secondary binding has posed a challenge for researchers. We were able to isolate a sperm head fraction in which the IAM was exposed. Attached to the IAM was an electon dense layer, which we termed the IAM extracellular coat (IAMC). The IAMC was also observable in acrosome reacted sperm. High salt extraction removed the IAMC including a prominent 38 kDa polypeptide, referred to as IAM38. Antibodies raised against IAM38 confirmed its presence in the IAMC of intact, sonicated, and acrosome-reacted sperm. Sequencing of IAM38 revealed it as the ortholog of porcine SP38, a protein that was found to bind specifically to ZP2 but whose intra-acrosomal location was not known. We showed that IAM38 occupied the leading edge of sperm contact with the zona pellucida during fertilization, and that secondary binding and fertilization were inhibited in vitro by antibodies directed against IAM38. As for the mechanism of secondary sperm-zona binding by IAM38, we provided evidence that the synthetic peptide derived from the ZP2-binding motif of IAM38 had a competitive inhibitory effect on both sperm-zona binding and fertilization while its mutant form was ineffective. In summary, our study provides a novel approach to obtain direct information on the peripheral and integral protein composition of the IAM and consolidates IAM38 as a genuine secondary sperm-zona binding protein. In addition, our investigation also provides an ultrastructural description of the origin, expression and assembly of IAM38 during spermatogenesis. It shows that IAM38 is originally secreted by the Golgi apparatus as part of the dense contents of the proacrosomic granules but later, during acrosome capping phase of spermiogenesis, is redistributed to the inner periphery of the acrosomal membrane. This relocation occurs at the time of acrosomal compaction, an obligatory structural change that fails to occur in Zpbp1-/- knockout mice, which do not express IAM38 and are infertile. / Thesis (Ph.D, Anatomy & Cell Biology) -- Queen's University, 2008-11-27 15:33:50.226
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Vliv estrogenů na kapacitaci a akrosomální reakci kančích spermií in vitro. / The effect of estrogens on capacitation and acrosome reaction of boar spermatozoa in vitro.Dostálová, Pavla January 2011 (has links)
Fertilization is a unique biological event where male and female gametes fuse together to produce a new organism. Before the gametes are able to fuse, however, they must undergo a series of controlled changes. For the male gamete, capacitation and acrosome reaction (AR) must occur, which take place during the sperm migration through the female genital tract. Unfortunately, while the process of capacitation has been known for over half a century, the molecular basis and influential factors behind it are not fully understood. Although estrogens have been considered mainly female reproductive hormones, there is increasing evidence suggesting that these steroids have an important role also in regulation of male reproductive functions. Sperm come into the contact with estrogens during their formation in the male and female genital tract, indicating that the hormone may play an important role in sperm maturation. In this study, we examined the importance of three endogenous estrogens (E1 -estron, E2 - 17β estradiol, E3 - estriol) and one synthetic estrogen (EE2 - 17α ethinylestradiol) on sperm maturation during capacitation and AR. Stimulatory effect were observed with all tested estrogens on both capacitation and zona pellucida induced AR. Moreover, we have determinied that the stimulatory effect on...
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Roles of Seminolipid and Its Associated Membrane Domain in Male FertilityKongmanas, Kessiri January 2015 (has links)
Our research aims at understanding the roles of seminolipid (sulfogalactosylglycerolipid or SGG) and its associated membrane domains in male reproduction. SGG is a sulfoglycolipid present selectively and abundantly in mammalian male germ cells. Therefore, information on its properties would be relevant towards the development of male fertility biomarkers and spermicide-based contraceptives. We have shown that SGG has direct affinity for zona pellucida (ZP, egg extracellular matrix) and plays a role in the formation of sperm lipid rafts, the ZP-binding platforms on the sperm anterior head plasma membrane (APM), the initial ZP binding site. For a better understanding of mechanisms underlying sperm-ZP interaction, I performed proteomic characterization of APM vesicles (SGG-associated membrane domains with ZP affinity) isolated from sperm before and after capacitation, a process through which sperm gain maximal ZP affinity. Proteomic results revealed that capacitated APM vesicles contained high-molecular-weight protein complexes, with higher ZP affinity and levels of ZP-binding proteins as compared with those of the non-capacitated samples. ZP-binding proteins known to exist in the acrosome (i.e., zonadhesin, proacrosin/acrosin) were found in these APM protein complexes. Immunofluorescence suggested that a fraction of these proteins trafficked from the acrosome to APM during capacitation. These findings provided a new mechanism on how sperm gain full ZP-binding ability during capacitation. Since SGG is a major component of APM, proper SGG levels at this site would be important for male fertility. Levels of sperm SGG are regulated through the synthesis and degradation. In fact, lack of SGG-synthesis enzymes causes a spermatogenesis disruption, resulting in male infertility. However, significance of SGG degradation remains unknown. SGG can be desulfated in vitro by arylsulfatase A (ARSA), an enzyme existing in the acrosomes of sperm/spermatids and lysosomes of Sertoli cells, testicular somatic cells that nurture developing germ cells. Sertoli cells also phagocytose ~50% of germ cells that become apoptotic during spermatogenesis. To understand physiological importance of SGG degradation, the fertility status and SGG levels of Arsa-/- male mice were determined. We found that Arsa-/- males became subfertile when they were older than 5 months, and when they were 8-month-old (~40-year-old men) they produced sperm at 50% wild type rate. Arsa-/- sperm had minimal in vitro fertilizing ability and a number of them showed abnormal morphology. Quantitative mass spectrometry revealed that SGG levels in Sertoli cells of 8-month-old Arsa-/- mice were increased to ~250% of the wild type level; this SGG accumulation may lead to a decrease in Sertoli cell ability to support spermatogenesis. However, SGG levels in sperm of 8-month-old Arsa-/- mice were ~50% of the wild type value, a result that partly explained the decreased fertilizing ability of these sperm. The reduced SGG level of Arsa-/- sperm was likely due to a lack of SGG’s building-block lipid (palmitylpalmitoylglycerol) putatively generated in Arsa-/- Sertoli cells and recycled to the next generation of primary spermatocytes for SGG synthesis. Hence, levels of sperm SGG are a promising bioindex for male fertility. Since Sertoli cells also regulate SGG homeostasis, their functionality should be now included in male fertility/subfertility diagnosis.
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