Immunohistochemical localization of epididymal secretory glycoprotein EP1 in the adult male chimpanzee.

Proteins, synthesized by the epididymal epithelium, are secreted sequentially into the lumen of the ducts epididymis where they effect sperm maturation and enable functional motility and fertilizing capacity. EP1 is a major secretory glycoprotein of chimpanzee (Pan troglodytes) epididymis. The epididymal duct exhibits diverse histology (Smithwick & Young, 1997). Epithelia I-V of the efferent ducts show no characteristic anti-EP1 binding. The densest granules of anti-EP1 reaction product appear in epithelium VI adjacent to the basal lamina in the infranuclear region of the principal cells (PCs), in the cytoplasm of the apical half of the PCs, and in the perinuclear and perivacuolar cytoplasm of the basal cells. In epithelia VII-XIV of the ductus epididymis proper, anti-EP1 binding decreases distally and is localized in the cytoplasm of the PCs and basal cells, among the stereocilia of the luminal border, within various microvillar borders, and in the luminal fluid. Therefore, EP1 appears to be synthesized and secreted primarily in the caput region of the ductus epididymis and may be reabsorbed nonselectively across epithelia with apical microvilli, including the non-ciliated cells of efferent ducts, the distal corpus and cauda of the ductus epididymis, and the proximal ductus deferens.     

Effects of androgen deprivation on the histology of adult chimpanzee testis

Until primate sperm are exposed to the unique microenvironment of the epididymis, they are not capable of fertilization or vigorous motility. Many of the proteins that contribute to the unique microenvironment of the primate epididymis, and thus to sperm maturation, are dependent on androgens to induce their synthesis and secretion. GnRH antagonists have proved effective in suppressing LH and testosterone synthesis and secretion, and thus in maintaining a state of androgen deprivation or functional hypogonadotropism. We report here the effects of GnRH antagonist-induced androgen-deprivation on the histology of the testicular interstitium and seminiferous epithelium of the adult male chimpanzee. After only 21 days of androgen-deprivation, chimpanzee testicular tissues exhibit specific atrophic changes, including the loss of contact between developing spermatocytes and between Sertoli cells and their developing spermatids, alterations in cell development resulting in missing maturation steps (elongating Sc and structurally complete Sd2 spermatids) and inappropriate cell associations, varying degrees of cytoplasmic degradation in germ cells, Sertoli cells, and Leydig cells, and a tubular lumen obscured by masses of sloughed primary and secondary spermatocytes and what appear histologically to be Sb1 and Sd1 spermatids.     

Distribution of a proteinase inhibitor of epididymal origin in the tissues and secretions of the male reproductive tract of mice

Monoclonal antibodies to a low molecular weight, acid-stable acrosin-trypsin inhibitor isolated from epididymal homogenates were used to localize the inhibitor in tissues and secretions of the male reproductive tract of mice. The inhibitor, identified by indirect immunofluorescence, is present in the testes and in the apical portion of the epithelial cells from the caput region of the epididymis of both intact and efferentiectomized animals. Sperm isolated from the testes and caput epididymal region show inhibitor-positive fluorescence on the anterior acrosomal region. The inhibitor could not be localized on ductus or electroejaculated sperm or ductus sperm previously incubated in a purified inhibitor solution. Furthermore, the inhibitor was not visible in the copulatory plug of recently inseminated animals or on sperm recovered from the uterus or from an artificial capacitating medium. The inhibitor could be detected by an enzyme-linked immunosorbent assay in the supernatants of detergent treated or frozen-thawed caput sperm but not of ductus sperm. The data suggest that the inhibitor, made in both the testes and caput epididymis where it associates with the sperm, is lost from the sperm or irreversibly masked during the epididymal sojourn.     

Regulation of epididymal function and sperm maturation--endocrine approach to fertility control in male.

The structural and functional integrity of the epididymis, the acquisition of fertilizing ability by spermatozoa and their viability within the epididymis are androgen dependent phenomena. Although the precise mechanism by which sperm maturation and viability in the epididymis are brought about by androgen are not clearly understood, it is generally held that specific epididymal secretions produced under the influence of androgen affect these events. Though the spermatozoa appear to remain viable in a low androgen environment, sperm maturation requires a relatively high androgen environment. Against this background the potentiality of antiandrogens as extragonadal antifertility agents has been discussed. Studies with steroidal and nonsteroidal antiandrogens have revealed that in adult animals the secretory activity of the epididymis, as evidenced by the level of glycerylphosphorylcholine, either remains unaffected or is stimulated under their influence. These studies have further indicated that the extragonadal antifertility action of antiandrogens will depend upon their ability to (1) lower the testicular androgen synthesis and/or androgen binding protein, which possibly serves as a carrier of androgen from the testis to epididymis; (2) to lower local androgen synthesis as a result of reduced levels of circulating androgen, and (3) to inhibit 5 alpha-reduction of testosterone to dihydrotestosterone and/or to inhibit androgen binding to receptors. Success in the rational development of new antifertility agents for male which will act by controlling epididymal function will depend upon a clear understanding of the factors that regulate epididymal secretion and the role of epididymal secretions in sperm maturation and survival.     

Physiology of the epididymis and spermatozoa

The epididymis is an ideal extragonadal target site to inhibit fertility in the male. Synthesis and secretion of constituents like sialic acids, protein and glycerylphosphoryl choline by the epididymal epithelium under androgen control provide an ideal fluid environment for sperm maturation. An optimal level of sialic acid secretion by the epididymal epithelium is needed to maintain functional integrity of sperm. The existence of specific androgen receptors in the epididymis and spermatozoa are related to their ability to metabolise androgens.     

Mouse cysteine-rich secretory protein 4 (CRISP4): a member of the Crisp family exclusively expressed in the epididymis in an androgen-dependent manner

The final maturation of spermatozoa produced in the testis takes place during their passage through the epididymis. In this process, the proteins secreted into the epididymal lumen along with changes in the pH and salt composition of the epididymal fluid cause several biochemical changes and remodeling of the sperm plasma membrane. The Crisp family is a group of cysteine-rich secretory proteins that previously consisted of three members, one of which-CRISP1-is an epididymal protein shown to attach to the sperm surface in the epididymal lumen and to inhibit gamete membrane fusion. In the present paper, we introduce a new member of the Crisp protein family, CRISP4. The new gene was discovered through in silico analysis of the epididymal expressed sequence tag library deposited in the UniGene database. The peptide sequence of CRISP4 has a signal sequence suggesting that it is secreted into the epididymal lumen and might thus interact with sperm. Unlike the other members of the family, Crisp4 is located on chromosome 1 in a cluster of genes encoding for cysteine-rich proteins. Crisp4 is expressed in the mouse exclusively in epithelial cells of the epididymis in an androgen-dependent manner, and the expression of the gene starts at puberty along with the onset of sperm maturation. The identified murine CRISP4 peptide has high homology with human CRISP1, and the homology is higher than that between murine and human CRISP1, suggesting that CRISP4 represents the mouse counterpart of human CRISP1 and could have similar effects on sperm membrane as mouse and human CRISP1.     

Epididymal functions and their hormonal regulation

The epididymis is a complex organ which maintains a specific intraluminal environment thought to be important for effecting sperm maturation in proximal regions and sperm storage in distal regions of the duct. The composition of the internal milieu is achieved both by transport between blood and lumen (and vice versa) and by synthesis and secretion into the lumen. Several low-molecular weight organic molecules achieve high concentration in the epididymal lumen, but their functions in the events of sperm maturation and storage still remain unclear. Metabolic processes occurring within epididymal tissue and the absorptive and secretory activity of the epididymal epithelium are regulated by androgens. The synthesis of some, but not all, secretory proteins is also androgen-dependent. In addition to androgens, other hormones and local testicular factors may influence epididymal function. There is now increasing evidence that epididymal-specific and androgen-dependent secretory proteins play a fundamental role in modifying the surface characteristics of sperm in preparation for the events of fertilization.     

Evidence for the presence of oxytocin in the ovine epididymis

The testes of several species contain oxytocin and/or neurophysin, but the content or localization of oxytocin in epididymal tissue has not been studied. The present study was undertaken to localize oxytocin and neurophysin in epididymal tissue of the ram, and to quantify oxytocin in the ductus epididymidis and fluids entering and leaving the ductus epididymidis. Neurophysin was not detected in the epididymis; thus, synthesis of oxytocin by the epididymis is unlikely. Immunohistochemical localization of oxytocin was confined to the epithelium and capillaries. Oxytocin immunostaining was most intense for epithelium of the caput and declined in corpus and cauda regions. However, based on radioimmunoassay, no difference in oxytocin concentration was detected among regions of the epididymis. Since rete testis fluid entering and cauda epididymal fluid leaving the epididymis contained at least fourfold more oxytocin than testicular venous plasma, it was concluded that regional differences in epithelial concentration of oxytocin may have been masked by oxytocin contained in the luminal fluid. It was concluded further that the epididymis of the ram does not synthesize oxytocin, but about 22 ng/day enters the epididymis in rete testis fluid. Most of this luminal oxytocin apparently is absorbed by the epithelium of the caput epididymidis, with additional adsorption in the corpus and cauda. Although a role for oxytocin in ductal contractility cannot be excluded, it is more likely that the luminal oxytocin influences epithelial or sperm function.     

Albumin Is Synthesized in Epididymis and Aggregates in a High Molecular Mass Glycoprotein Complex Involved in Sperm-Egg Fertilization

The epididymis has an important role in the maturation of sperm for fertilization, but little is known about the epididymal molecules involved in sperm modifications during this process. We have previously described the expression pattern for an antigen in epididymal epithelial cells that reacts with the monoclonal antibody (mAb) TRA 54. Immunohistochemical and immunoblotting analyses suggest that the epitope of the epididymal antigen probably involves a sugar moiety that is released into the epididymal lumen in an androgen-dependent manner and subsequently binds to luminal sperm. Using column chromatography, SDS-PAGE with in situ digestion and mass spectrometry, we have identified the protein recognized by mAb TRA 54 in mouse epididymal epithelial cells. The ∼65 kDa protein is part of a high molecular mass complex (∼260 kDa) that is also present in the sperm acrosomal vesicle and is completely released after the acrosomal reaction. The amino acid sequence of the protein corresponded to that of albumin. Immunoprecipitates with anti-albumin antibody contained the antigen recognized by mAb TRA 54, indicating that the epididymal molecule recognized by mAb TRA 54 is albumin. RT-PCR detected albumin mRNA in the epididymis and fertilization assays in vitro showed that the glycoprotein complex containing albumin was involved in the ability of sperm to recognize and penetrate the egg zona pellucida. Together, these results indicate that epididymal-derived albumin participates in the formation of a high molecular mass glycoprotein complex that has an important role in egg fertilization.     

Ethylene dimethane sulfonate (EDS) ablation of Leydig cells in adult rat depletes testosterone resulting in epididymal sperm granuloma: Testosterone replacement prevents granuloma formation

Sperm granuloma may develop in the epididymis following vasectomy or chemical insults. Inflammation due to sperm granuloma causes abdominal and scrotal pain. Prolonged and persistent inflammation in the epididymis due to sperm granuloma may lead to infertility. Extravasation of germ cells into the interstitium of epididymis following damage of the epididymal epithelium is one of the primary reasons for sperm granuloma-associated pathology. Since testosterone is vital for the maintenance of epididymal epithelium, we investigated the pathology of sperm granuloma and its relationship with testosterone. Adult rats were treated with a Leydig cell-specific toxicant ethylene dimethane sulfonate (EDS) to eliminate testosterone. At 7 days post-EDS, disrupted epididymal epithelium and sperm granuloma were observed in the caput epididymis. Sperm granuloma and caput were collagen-filled indicating fibrosis. Numerous round apoptotic cells were localized inside the caput lumen and dispersed through the sperm granuloma. Tnp1 (round spermatid marker) was significantly higher in the epididymis of the EDS-treated group compared to controls suggesting the apoptotic cells were round spermatids. Increases in CD68⁺ macrophages and T cells (CD4 and CD8) support an inflammatory immune infiltration in post-EDS epididymis. However, testosterone replacement following EDS prevented the sperm granuloma-associated pathology. We suggest that the immune response in the sperm granuloma may be due to the increased numbers of apoptotic round spermatids or other testicular tissue components that may be released, in addition to the regression of epididymal epithelium due to testosterone loss. Thus, testosterone replacement prevents EDS-induced sperm granuloma and ameliorates sperm granuloma-associated pathology.     

Reproduction in the male honey possum (Tarsipes rostratus: Marsupialia): the epididymis

The epididymis of the adult honey possum, Tarsipes rostratus, is enclosed by a heavily pigmented tunica vaginalis and lies with the testis in a prominent prepenile scrotum. It is connected to the testis by a single ductus efferentis and is lined by approximately equal numbers of cuboidal ciliated and principal cells. It is unusual for marsupials in having no well-defined compartments or fibrous septae and in having extensive convolutions of the duct only at the caudal flexure. Three principal functional zones (initial, middle, and terminal segments) were identified in the epididymis, based on epithelial type and ultrastructural evidence of sperm maturation. Luminal diameter increases progressively throughout the tract, and epithelial height variations (from about 2 to 20 microns) are greatest in the terminal segment. The epithelium itself is remarkably low (maximum of 21.6 microns) compared with that seen in the epididymis of other mammals. The thickness of the peritubular smooth muscle coat increases close to the junction of the epididymis and ductus deferens. Sperm concentrations were estimated from counts of sperm nuclei and thus can be no more than approximations. The figures are consistent, however, with a rapid increase in concentration in the initial segment, indicating extensive fluid resorption. Sperm concentrations appear to peak in the distal zone of the terminal segment, although sampling problems and wide variations in count make such a conclusion only tentative. Principal and basal cells are the predominant cell types in the epididymal epithelium. Basal cells are most abundant in the initial and distal middle segment. Principal cells show structural evidence of active exchange with the luminal contents and have abundant apical stereocilia, the structure of which depends on the epididymal zone. Other cell types occur less commonly in the epithelium. Lipid-rich and phagocytic principal cells are restricted to the middle and distal zones of the middle segment, respectively. Clear cells, restricted to the terminal segment, and halo cells were found in very low numbers. As in some other marsupials, principal cells (possibly specialized for this function) selectively remove cytoplasmic droplets and probably other cellular debris from the luminal contents. In Tarsipes, however, this process is not very efficient, and many discarded droplets pass through to the terminal segment where they form large masses of debris associated with aggregates of degenerating spermatozoa.     

Effects of breeding season and mating on total number and distribution of spermatozoa in the epididymis of the brown marsupial mouse, Antechinus stuartii

Changes in the number and distribution of spermatozoa in the epididymis of the adult brown marsupial mouse were examined during July/August in mated and unmated males. The effects of mating on epididymal sperm populations were studied in 2 groups of males each mated 3 times and compared with the number and distribution of spermatozoa in the epididymides of 4 unmated control groups. One testis and epididymis were removed from each animal (hemicastration) either before or early in the mating season to provide information on initial sperm content and distribution. The contralateral side was removed later in the mating season to examine the effects of mating or sexual abstinence on epididymal sperm distribution. Epididymal sperm number peaked in both the distal caput and distal corpus/proximal cauda epididymidis in late July. The total number of spermatozoa, including those remaining in the testis, available to each male at the beginning of the mating season in early August was approximately 4.4 x 10(6)/side. Although recruitment of spermatozoa into the epididymis from the testis continued until mid-August, sperm content of the epididymis reached a peak of about 3.5 x 10(6)/epididymis in early August. At this time approximately 0.9 x 10(6) spermatozoa remained in the testis which had ceased spermatogenic activity. Throughout the mating season, epididymal spermatozoa were concentrated in the distal corpus/proximal cauda regions of the epididymis and were replenished by spermatozoa from upper regions of the duct. Relatively few spermatozoa were found in the distal cauda epididymidis, confirming a low sperm storage capacity in this region. A constant loss of spermatozoa from the epididymis, probably via spermatorrhoea, occurred throughout the mating season and very few spermatozoa remained in unmated males in late August before the annual male die-off. Mating studies showed that an average of 0.23 x 10(6) spermatozoa/epididymis were delivered per mating in this species, but the number of spermatozoa released at each ejaculation may be as few as 0.04 x 10(6)/epididymis when sperm loss via spermatorrhoea is taken into account. We suggest that the unusual structure of the cauda epididymidis, which has a very restricted sperm storage capacity, may function to limit the numbers of spermatozoa available at each ejaculation and thus conserve the dwindling epididymal sperm reserves in order to maximize the number of successful matings which are possible during the mating season.     

Two-dimensional electrophoresis of proteins in principal cells, spermatozoa, and fluid associated with the rat epididymis

Spermatozoa, fluids, and principal cells from different regions of the epididymis were characterized by two-dimensional electrophoresis. Rete testis fluid was collected after 36-h efferent duct ligation, and cauda epididymal fluid was collected by retrograde perfusion through the vas deferens. Spermatozoa were collected after their exudation from minced caput and corpus epididymal tissue. Principal cells were recovered after enzymatic disaggregation and centrifugal elutriation of epididymides. Two-dimensional polyacrylamide gel electrophoresis was used to prepare protein profiles of all samples. Comparison of the proteins found in rete testis fluid versus those found in cauda epididymal fluid revealed a dramatic change in composition, including the loss, addition, or retention of specific proteins as well as changes in the relative concentrations of certain proteins. Prominent cauda epididymal fluid proteins, possibly contributed by the epididymal epithelium, were detected at 16, 23, and 34 kDa. After epididymal transit, a considerable decrease was observed in the number of aqueous-soluble sperm proteins. Differences in the protein composition of epididymal epithelial principal cells from the caput versus corpus epididymidis were also noted, suggesting that functional differences exist for these epididymal regions. Of particular interest was the occurrence of a prominent protein of approximately 20-23 kDa found in all sperm samples, in fluids, and in caput and corpus principal cells. However, this protein was absent in cauda epididymal sperm after 36-h efferent duct ligation. The rapid loss of this protein from sperm after efferent duct ligation suggests that this surgical intervention may affect spermatozoa residing within the epididymis.     

The major androgen-regulated secretory proteins of the rat epididymis bear sequence homology with members of the alpha 2u-globulin superfamily

The primary amino acid sequence of 18.5 kDa androgen-dependent secretory proteins of the rat epididymis has been compared with protein data-base sequences. The comparison has revealed that the epididymal proteins belong to the alpha 2u-globulin superfamily which includes human, rat and mouse urinary proteins, ungulate beta-lactoglobulins, and serum retinol-binding proteins. The homology suggests that the epididymal proteins may function to transport retinoids within the male reproductive tract. The androgen-dependent characteristics of the proteins and their tissue-specific nature have been ascertained by use of the protein's cDNA as a probe. The mRNA for the proteins was found in the epididymis of the rat and mouse, but not the epididymis of guinea-pig, rabbit, bull, boar, or ram.     

Enhancement of sperm transport through the rat epididymis after castration

Transport of spermatozoa through different regions of the epididymis has been followed by labelling testicular spermatozoa with [3H]thymidine in intact rats and in rats in which the efferent ducts were ligated or the testes were removed. In intact rats, the transit times of epididymal spermatozoa from the initial segment to the caput, from the caput to the corpus, and from the corpus to the cauda were 2, 4 and 2 days, respectively, giving a total transit time of 8 days. After bilateral castration, labelled spermatozoa were transferred from the initial segment into the proximal cauda by 2 days and appeared in the ductus deferens by 4 days. This effect was prevented by a daily subcutaneous injection of testosterone propionate (0.2 mg/kg). Bilateral efferent duct ligation had only a slight effect on the passage of epididymal spermatozoa. The results indicate that epididymal sperm transport is enhanced after androgen withdrawal.     

Castration induces changes in the cation‐dependent mannose‐6‐phosphate receptor in rat epididymis: Possible implications in secretion of lysosomal enzymes

It is believed that the mammalian epididymis participates in the maturation of the sperm due to its secretory activity. High concentrations of several secreted acid hydrolases are found in the epididymal lumen. Moreover, some of these enzymes are secreted by the epididymal epithelium in an androgen‐dependent fashion. In this study, we attempted to discern whether mannose‐6‐phosphate receptors (MPRs) regulate transport and secretion of lysosomal enzymes in the rat epididymis, and if these events are altered when the animals are subjected to hormonal manipulation. We observed that expression of cation‐dependent MPR (CD‐MPR) and cation‐independent MPR (CI‐MPR) increased significantly in caudal epididymis of castrated rats by immunoblot. This increase was corroborated by quantitation of MPRs, by binding assays. This change could be due to androgen deprivation, as a similar effect was observed after treatment with the anti‐androgenic drug flutamide. Furthermore, we observed that the CD‐MPR was redistributed to the apical area of the epithelium on castrated rats by immunohistochemistry, which is compatible with the redistribution of the receptors toward lighter fractions in a Percoll gradient. Consistent with a possible involvement of the CD‐MPR in the secretion, we observed an increase in pro‐cathepsin D levels in epididymal fluid after castration. We conclude that the CD‐MPR might be regulated by hormones and that this receptor might be involved in the secretion of specific enzymes into the rat epididymis. J. Cell. Biochem. 110: 1101–1110, 2010. Published 2010 Wiley‐Liss, Inc.     

Maturing the sperm: unique mechanisms for modifying integral proteins in the sperm plasma membrane

The epididymis has been understudied, in part due to its cancer resistance and the development of effective technologies for sperm injection and in vitro fertilization. However, it is worthy of study because--absent advanced reproductive technology--its proper function is essential for conceiving children: sperm leaving the testis are immature and nonfertile. Epididymal functions can be divided into several general categories (1) concentration of sperm; (2) functional maturation; (3) storage in a quiescent state until ejaculation; (4) removal of degenerating sperm; (5) provision of appropriate conditions for survival; (6) transport by the myoid cells; (7) protection; (8) maintenance of the blood epididymal barrier. In the past decade investigators have focused on those maturational changes of the integral proteins of the sperm plasma membrane which are directly related to sperm-ova interactions. It has traditionally been thought that changes in the sperm plasma membrane proteins were limited to simple binding or removal of proteins or interactions with the proteases, glycosylases and glycotransferases present. However, the epididymis can also release secretory products in bulk through apical blebs and inject integral membrane proteins with epididymosomes which fuse with the plasma membrane. The epididymis also activates and cleaves enzymes present on the sperm surface (e.g., germ cell angiotensin converting enzyme), thus enabling them to modify proteins on the sperm membrane. Aside from the need to understand epididymal function relative to the sperm, basic science on epididymal physiology is warranted because it may help us understand the functioning of androgens, protection of tissues from oxidative damage, and resistance to cancer and benign hyperplasic growth.