Function of human epididymal proteins in sperm maturation (original) (raw)
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The epididymis and its role on sperm quality and male fertility
The epididymis is a complex organ where spermatozoa acquire motility and ability to fertilize the egg. Epididymal maturation lasts 1 or 2 weeks and exposes the immature spermatozoa to a sequentially modified milieu, promoting intense interactions with secretions by the epididymal epithelium. Sperm surface modifications in response to interactions with epididymal secretions are key steps to achieve fertility ability. However, the precise molecular mechanisms that convert an immotile and infertile gamete into a highly motile cell capable of fusion with an oocyte are still unknown. Recent data on proteomics and transcriptomics of epididymal fluid and epididymosomes brought new ideas of the physiological roles of proteins and miRNAs in epididymal maturation in spermatozoa. This review focuses on the recent discoveries on epididymal fluid composition and its role on sperm maturation and preservation, linking to their survival and fertility potential.
Human epididymal proteins and sperm function during fertilization: un update
Biological Research, 2001
utilized as a new marker for semen abnormalities. In a recent report (Sutovsky et al, 2001b), a "sperm-ubiquitin tag immunoassay (SUTI)" was described as a valuable new tool for infertility diagnosis and prediction of IVF success in subfertile men diagnosed with idiopathic infertility. CONCLUSIONS This review has briefly shown some findings reported by several investigators on a set of human epididymal proteins identified and partially characterized in the recent years. The results suggest that the epididymis produces and secretes numerous proteins that would associate to the spermatozoa while they are transiting through the organ. These components would dramatically affect sperm functionality, allowing the male gamete to recognize the oocyte. However, much still is waiting to be done to comprehend this phenomenon. Implementation of genomics and proteomics will help, in the near future, to further characterize some already identified proteins, as well as to describe novel epididymal components, anticipating great advances in the elucidation of the sperm maturation process in humans.
Identification of epididymal proteins associated with hamster sperm
Journal of Experimental Zoology, 1991
The electrophoretic analysis of the proteins that were extracted from immature caput and mature cauda sperm showed evidence of accumulation of several proteins during the epididymal transit of the sperm. An antiserum, raised against detergent-extracted proteins from mature spermatozoa, immunostained six epididymal proteins with apparent molecular masses of 16,22.5, 26'37, 60, and 80 kDa on Western blots of epididymal fluid. Of these proteins, only the 26 kDa protein was significantly immunodetected in proximal caput epididymal fluid. Its biosynthesis by caput epididymis was confirmed by immunoprecipitation of an in vitro translated product of caput poly (A) RNA. The homology of the 26 kDa epididymal protein with the 26 kDa sperm protein was verified by epitope mapping. The other epididymal proteins were found in the fluid of the more distal portions of the organ. Their presence in the epididymal fluid coincided with their detection on the sperm. These epididymal proteins were considered to be sperm-coating proteins.
Biology of Reproduction, 1996
During epididymal transit, spermatozoa acquire new surface antigens that are involved in the acquisition of their fertilizing ability. We have previously described a 34-kDa (P34H) human epididymal sperm protein that shows antigenic and functional homologies with the hamster P26h. P34H is localized on the acrosomal cap of human spermatozoa and has been proposed to be involved in the interaction with the zona pellucida. The aim of this study was to document the expression of P34H on the sperm surface during transit along the male and female genital tracts. Immunohistochemical techniques were performed on human testes and epididymides by means of an antiserum specific for P34H. No labeling was detected on those spermatozoa found within the seminiferous tubules or in the vasa efferentia. P34H first appeared in the caput epididymidis and was restricted to the acrosomal cap. Signal intensity then increased considerably from the proximal corpus to the cauda region of the epididymis. After ejaculation, the same pattern of P34H distribution was observed, but the intensity was much lower than that characterizing the cauda epididymal spermatozoa. Strong labeling was restored after incubation in B2 medium and was maximal after 5 h of capacitation. After acrosomal exocytosis induced by a Ca 2+ ionophore, the percentage of P34Hlabeled spermatozoa decreased proportionally to the number of acrosome-reacted spermatozoa as determined by Pisum sativum-fluorescein isothiocyanate (FITC) labeling. P34H appeared to be strongly anchored to the sperm plasma membrane during epididymal transit as indicated by the requirement for detergent to extract this surface antigen from ejaculated spermatozoa. This confirms the importance of P34H binding to the sperm plasma membrane during epididymal maturation. We have previously proposed that P34H is involved in sperm-zona pellucida interaction. The appearance and accumulation of P34H on the sperm plasma membrane during epididymal maturation, followed by its inaccessibility associated with ejaculation, its unmasking during capacitation, and finally its elimination after the acrosome reaction, are in agreement with the proposed function of this sperm antigen.
Purification and identification of sperm surface proteins and changes during epididymal maturation
PROTEOMICS, 2011
Surface membrane proteins have a key role in the sequential interactions between spermatozoa and oocytes. The aim of this study was to characterize protein changes occurring during post-testicular differentiation using a new overall approach to study surface membrane proteins of spermatozoa. A dedicated protocol based on specific purification of surface membrane proteins labeled with sulfo-NHS-SS-biotin was developed for this purpose. Appropriate gel electrophoresis separation and purification methods combined with standard proteomic methods were then used to identify and quantify surface membrane proteins from immature and mature spermatozoa. Membrane-associated proteins were discriminated from integral membrane proteins by differential solubilization. Protein regionalization on the spermatozoon surface was achieved by comparative analysis of the surface protein extracts from the entire spermatozoa and from periacrosomal sperm plasma membranes. Identification of several known proteins and of new proteins related to the process of epididymal maturation showed the reliability of this protocol for specific purification of a subproteome and identification of new sperm membrane proteins. This approach opens up a new area in the search for male fertility markers.
Biochemical Characterization of Two Ram Cauda Epididymal Maturation-Dependent Sperm Glycoproteins1
Biology of Reproduction, 2000
Rabbit polyclonal antibodies were raised against ram cauda epididymal sperm proteins solubilized by N-octyl--D-glucopyranoside (anti-CESP) and against proteins of the fluid obtained from the cauda epididymidis (anti-CEF). The anti-CESP polyclonal antibody reacted with several bands from 17 to 111 kDa with different regionalization throughout the epididymis. The strongest epitopes at 17 kDa and 23 kDa were restricted to the cauda epididymidis. The anti-CEF polyclonal antibody reacted mainly with a 17-kDa and a 23-kDa compound in the cauda sperm extract. These cauda epididymal 17-and 23-kDa proteins disappeared after orchidectomy, but they reappeared in the same regions after testosterone supplementation, indicating that they were secreted by the epithelium. The fluid and membrane 17-and 23-kDa antigens had a low isoelectric point and were glycosylated. The fluid 17-and 23-kDa proteins had hydrophobic properties: they were highly enriched in the Triton X-114 detergent phase and could be extracted from the cauda epididymal fluid by a chloroform-methanol mixture. These proteins were further purified, and their N-terminal sequences did not match any protein in current databases. A polyclonal antibody against the fluid 17-kDa protein recognized the protein in the cauda epididymal sperm extract and immunolocalized it on the sperm flagellum membrane and at the luminal border of all cells in the cauda epididymal epithelium. These results indicated that secreted glycoproteins with hydrophobic properties could be directly integrated in a specific domain of the sperm plasma membrane.
The contribution of proteomics to understanding epididymal maturation of mammalian spermatozoa
Systems Biology in Reproductive Medicine, 2012
The acquisition of the ability of the male gamete to fertilize an ovum is the result of numerous and sequential steps of differentiation of spermatozoa that occur as they transit from the testis to the end of the epididymal tubule. The post gonadal sperm modifications are mostly related to motility, egg binding, and penetration processes. As the activity of the epididymis and its luminal fluid composition are believed to be directly related to 'sperm maturation', a review on epididymal proteins is presented. Comparative studies have shown that the epididymal activities are species specific. Nevertheless, for all mammalian species studied, similarities exist in the sequential proteomic changes of the luminal composition of the epididymal tubule and proteins on the sperm surface. The potential roles of these modifications are discussed.
Journal of Andrology, 2012
A differential proteomics approach led to the identification of several novel epididymal sperm proteins. One of the novel proteins was methylmalonate-semialdehyde dehydrogenase (MMSDH). In the present study, we carried out an in-depth characterization to study its regulation by androgen, its appearance during ontogeny, and the mechanism of its interaction with and acquisition by the sperm. Western blotting and immunohistochemical studies suggest that the protein is present in both tissue and sperm from all regions of the epididymis, indicating synthesis as well as acquisition of the protein in these regions. Androgen depletion resulted in reduction of the MMSDH protein level in the epididymis, which completely disappeared 1 week after castration. The protein reappeared after testosterone propionate injection, indicating that the protein is regulated by androgens. Ontogeny studies indicated that the protein appeared from day 10 postnatal with a gradual increase at day 30, which maximized at day 50, indicating that the protein is developmentally regulated and is probably involved in epididymal development. Sequential extraction of sperm proteins indicated that MMSDH exists both as a peripheral and integral form on the plasma membrane. We also found that the protein can be transferred from the epididymosomes to testicular sperm in vitro. The study provides evidence regarding the acquisition of this multidomain androgen and developmentally regulated protein in the epididymis via the epididymosomes. The molecule has generated enough interest and deserves to be investigated further for its physiological relevance.
Novel epididymal proteins as targets for the development of post-testicular male contraception
Reproduction, 2008
Apart from condoms and vasectomy, modern contraceptive methods for men are still not available. Besides hormonal approaches to stop testicular sperm production, the post-meiotic blockage of epididymal sperm maturation carries lots of promise. Microarray and proteomics techniques and libraries of expressed sequence tags, in combination with digital differential display tools and publicly available gene expression databases, are being currently used to identify and characterize novel epididymal proteins as putative targets for male contraception. The data reported indicate that these technologies provide complementary information for the identification of novel highly expressed genes in the epididymis. Deleting the gene of interest by targeted ablation technology in mice or using immunization against the cognate protein are the two preferred methods to functionally validate the function of novel genes in vivo. In this review, we summarize the current knowledge of several epididymal proteins shown either in vivo or in vitro to be involved in the epididymal sperm maturation. These proteins include CRISP1, SPAG11e, DEFB126, carbonyl reductase P34H, CD52, and GPR64. In addition, we introduce novel proteinases and protease inhibitor gene families with potentially important roles in regulating the sperm maturation process. Furthermore, potential contraceptive strategies as well as delivery methods will be discussed. Despite the progress made in recent years, further studies are needed to reveal further details in the epididymal sperm maturation process and the factors involved, in order to facilitate the development of new epididymal contraceptives.
Epididymal cell secretory activities and the role of proteins in boar sperm maturation
Theriogenology, 2005
When mammalian spermatozoa exit the testis, they show a highly specialized morphology; however, they are not yet able to carry out their task: to fertilize an oocyte. This property, that includes the acquisition of motility and the ability to recognize and to fuse with the oocyte investments, is gained only after a transit through the epididymis during which the spermatozoa from the testis travel to the vas deferens. The exact molecular mechanisms that turn these cells into fertile gametes still remain mysterious, but surface-modifying events occurring in response to the external media are key steps in this process. Our laboratory has established cartographies of secreted (secretomes) and present proteins (proteomes) in the epididymal fluid of different mammals and have shown the regionalized variations in these fluid proteins along the epididymis. We have found that the main secreted proteins are common in different species and that enzymatic activities, capable of controlling the sperm surface changes, are present in the fluid. Our studies also indicate that the epididymal fluid is more complex than previously thought; it contains both soluble and particulate compartments such as exosome-like vesicles (epididymosomes) and certainly specific glycolipid-protein micelles. Understanding how these different compartments interplay to modify sperm components during their transit will be a necessary step if one wants to control and to ameliorate sperm quality and to obtain valuable fertility markers helpful to establish a male fertility based genetic selection.