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A PORCINE HOMOLOG OF THE MAJOR SECRETORY PROTEIN OF HUMAN EPIDIDYMIS, HE1,SPECIFICALLY BINDS CHOLESTEROL

A porcine homolog of the major secretory protein of human epididymis, HE1, was for the first time purified from the porcine cauda epididymal fluid. The HE1 homolog was secreted into the epididymal fluid as a 19-kDa glycoprotein, whose sugar moiety was gradually processed to form a 16-kDa protein during transit through the epididymis. The HE1 homolog mRNA was detected only in the caput and corpus epididymis among the porcine tissues examined. The purified HE1 homolog specifically bound cholesterol with high affinity (Kd=2. 3 microM). The binding stoichiometry was determined to be 0.94 mol/mol, suggesting that 1 mol of cholesterol binds to 1 mol of the protein. It was also found that the HE1 homolog is a major cholesterol-binding protein in the porcine epididymal fluid. The possibility that the HE1 homolog is involved in the regulation of the lipid composition of the sperm membranes during the maturation in epididymis is discussed.

New insights into epididymal function in relation to sperm maturation

Testicular spermatozoa acquire fertility only after 1 or 2 weeks of transit through the epididymis. At the end of this several meters long epididymal tubule, the male gamete is able to move, capacitate, migrate through the female tract, bind to the egg membrane and fuse to the oocyte to result in a viable embryo. All these sperm properties are acquired after sequential modifications occurring either at the level of the spermatozoon or in the epididymal surroundings. Over the last few decades, significant increases in the understanding of the composition of the male gamete and its surroundings have resulted from the use of new techniques such as genome sequencing, proteomics combined with high-sensitivity mass spectrometry, and gene-knockout approaches. This review reports and discusses the most relevant new results obtained in different species regarding the various cellular processes occurring at the sperm level, in particular, those related to the development of motility and egg binding during epididymal transit.

Identification of luminal and secreted proteins in bull epididymis.

The epididymis plays a major role in the acquisition of sperm fertility. In order to shed light on specific features of epididymal function in mammalian species, we characterized the luminal proteins (luminal proteome) and secreted proteins (secretome) in the bovine epididymis. We identified 172 different luminal proteins in 9 distinct epididymal regions. The concentration and secretory activity of luminal proteins were quantified throughout the epididymis. Among the most abundant secreted proteins, we found lipocalin 5, (LCN5), NADP(+)dependent prostaglandin dehydrogenase (PTGDS), Niemann-Pick disease type C2 protein (NPC2), glutathione peroxidase type 5 (GPX 5), clusterin (CLU), hexosaminidase B (HEXB) and galactosidase (GLB1), each of which is released in distinct epididymal regions. Gelsolin, (GSN) previously not described in mammalian epididymal fluid, appeared to be a major protein secreted exclusively in the distal region of the bovine epididymis, where fully mature spermatozoa are stored. Although the major epididymal proteins are conserved between mammalian species, this study highlights the specificity and mechanisms of protein processing of epididymal secretion in the bull. In addition, this study provides a major insight into the sequential changes occurring in the sperm environment while gaining fertilizing capacity and could provide new information for the future identification of potential fertility markers.

Mammalian epididymal proteome.

In all mammalian species, the final differentiation of the male germ cell occurs in the epididymal duct where the spermatozoa develop the ability to be motile and fertilize an ovum. Understanding of these biological processes is the key to understanding and controlling male fertility. Comparative studies between several mammals could be an informative approach to finding common sperm modifications which are not species-specific. The new global biological approaches such as transcriptomes and proteomes provide considerable information which can be used for such comparative approaches. This report summarizes our proteomic studies of the epididymis of several mammals, including humans.

Purification and identification of sperm surface proteins and changes during epididymal maturation

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.

The contribution of proteomics to understanding epididymal maturation of mammalian spermatozoa

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.

Protein Secretion in the Epididymis

The milieu surrounding the spermatozoa is certainly the most complex fluid found in any exocrine gland. This complexity results from two particularities: (1) continuous and progressive changes in its composition throughout the male excurrent duct and (2) the presence of components in unusual concentrations, some of them not found in other body fluids. This specificity is maintained not only by active secretion and reabsorption throughout the tract but also by the presence of significant restrictions in the exchanges between the luminal compartment and blood plasma. A blood barrier formed by tight junctions between the Sertoli cells in the testis and epithelial cells in the epididymis (Hoffer and Hinton, 1984; see Cyr, this volume) is present throughout gamete differentiation until the sperm complete their maturation. The most important function of the blood barrier is protection from autoimmune attack: 1) from new antigens which appear on the sperm during their differentiation, and 2) from specific testicular and epididymal protein secretions associated with the terminal cellular differentiation of the gametes.

Molecular cloning and characterization of the epididymis-specific glutathione peroxidase-like protein secreted in the porcine epididymal fluid

The epididymis-specific glutathione peroxidase was purified from the porcine cauda epididymal fluid in order to analyze its enzymatic activity and roles in the epididymis. The purified protein was found to consist of four identical 23 kDa subunits. The complementary DNA encoding the 23 kDa subunit was cloned from the cDNA library of the porcine proximal caput epididymis, only where the 23 kDa subunit is expressed. Although the selenocysteine codon (TGA) is contained in the cDNA of the other cytosolic type of glutathione peroxidases, it is replaced by cysteine codon (TGT) in the 23 kDa subunit cDNA, similarly to the results previously obtained for cDNAs encoding the epididymis-specific form of the secreted glutathione peroxidases of mouse, rat and monkey. By the direct analysis of the selenium, the purified protein was proved to contain no selenium atom in the molecule. The activities of the purified epididymis-specific glutathione peroxidase toward hydrogen peroxide or organic hydroperoxides were by far lower than the activity of cytosolic selenium-dependent glutathione peroxidase (less than 0.1%). In addition, the concentration of glutathione in the porcine epididymal fluids was about 20 microM, which is much lower than the optimal concentration for the glutathione peroxidase activity of the purified protein. These results strongly suggest that this protein is enzymatically quiescent at least in the porcine epididymal fluid. An immunocytochemical study showed that this protein was found to bind to the acrosomal region of the epididymal sperm and to disappear during the acrosome reaction. Furthermore, this protein significantly retarded the acrosome reaction induced in vitro. The possibilities have been discussed that it protects sperm from the premature acrosome reaction and maintains sperm fertilizing ability in the epididymis.

Direct evidence for the elevated synthesis and secretion of procathepsin L in the distal caput epididymis of boar.

The proteins which are secreted from the restricted part of the epididymis are suggested to sustain sperm maturation. In porcine species, as the potential abilities of sperm for movement and fertilization greatly increase in the corpus epididymis, the secretions in both the caput and corpus epididymis seem to be very important for the sperm maturation. In this study, we have directed our attention to the 40 kDa protein which is detected in the fluid of the distal caput epididymis of boar. It was purified from the porcine cauda epididymal fluid and its cDNA was cloned from the cDNA library of the distal caput epididymis. According to the deduced amino acid sequence, the 40 kDa protein has been identified as procathepsin L. Northern blot analysis showed that the procathepsin L mRNA was most abundant in the distal caput epididymis among the tissues as examined. Consistent with the distribution of the procathepsin L mRNA in the epididymis, the activity of procathepsin L was absent in the fluid of the proximal and mid caput epididymis and first appeared in the distal caput epididymal fluid, whose contents gradually decreased with the passage through the epididymis. These results first appeared in the first distal caput epididymis expresses very high levels of procathepsin L and unusually secretes it into the luminal fluid instead of targeting it to lysosomes. It has been also found that the mRNA of PDGF, which is known to enhance cathepsin L expression in the culture cells, is very high in the mid caput epididymis, which just precedes the site of procathepsin L secretion. This result indicates that PDGF directly regulates the locally restricted expression and secretion of procathepsin L in the epididymis, which is one of the possible mechanisms involved in the functional differentiation in the epididymis.

The intracellular pathway of antagglutinin secretion in the boar caput epididymidis as revealed by immunogold labelling

SummaryAntagglutinin, a specific protein synthesized by the boar epididymis, was localized by an ultrastructural immunogold-labeling procedure in the principal cells of the three regions of the caput epididymidis, most notably at the sites of synthesis and secretion. The intensity of the reaction was variable in the three epididymal zones. Labeling was of low intensity in the proximal and middle caput, except in the granules of the latter. These granular “storage sites” did not correspond to typical secretory granules but appeared to be intracellular sites of degradation of this protein. In the distal caput, which was devoid of these granules, intense secretory activity for antagglutinin was detected. Few gold particles were localized in the RER profiles but labeling was detected in the Golgi zone, in numerous dense vesicles, in structures distributed between the Golgi zone and the apex of the cell, and in the epididymal lumen. This study has enabled us to visualize immunocytochemically antagglutinin along its intracellular secretory pathway, i.e. at the site of its synthesis, during its passage via the Golgi zone, and its intracellular transport to the lumen.