Pannexins (Panxs) are channel-forming proteins that have homology to the invertebrate gap junction proteins, the innexins. These proteins form membrane channels implicated in ATP release. To evaluate the role of Panxs in the male reproductive tract, we investigated the distribution and regulation of Panx1 and 3 in the testis, efferent ducts (ED), and epididymis of adult rats. In the testis, Panx1 localized to the basal compartment of the seminiferous epithelium, while Panx3 was expressed in Leydig cells. In the ED, both Panxs were expressed in the apical region of ciliated cells. In the epididymis, Panx1 was detected at the base of the epithelium, at times encompassing basal cells, while Panx3 was restricted to the apical plasma membrane of principal cells. Panx3 immunoreactions were high throughout the entire epididymis while Panx1 was high in all regions except the initial segment. Multiple transcripts for Panx1 were identified, and sequence analysis indicated that alternative splicing might account for them. Orchidectomy resulted in the expression of multiple immunoreactive Panx1 bands, and these appeared to be androgen-repressed throughout the epididymis. Panx3 levels in all epididymal regions were also androgen-repressed. Deglycosylation experiments indicated that some Panx1 species were due to glycosylation, but this did not account for all Panx1 immunoreactive species. In summary, Panxs expressed in the epididymis and regulated by both alternative splicing events and androgens. These proteins may play a role in ATP secretion into the epididymal lumen and basal extracellular spaces for functions involving sperm transport and maturation.
In the epididymis, Cx43 forms gap junctions between principal and basal cells but not between adjacent principal cells. Cx30.3, 31.1, and 32 were identified in adult rat epididymis by RT-PCR, whereas Cx26 was present in young rats. Postnatal development studies indicate that Cx26 mRNA was detectable only in the caput-corpus region of the epididymis and that levels increased by fivefold during the first 4 wk postnatally, when epithelial cells differentiate, and decrease to nondetectable levels thereafter. Cx31.1 and Cx32 mRNA levels were low throughout the epididymis in young rats and began to increase in the second and third weeks postnatally, when Cx26 levels are decreasing. Both Cx26 and Cx32 were localized to the lateral plasma membranes between adjacent epithelial cells of the epididymis. Colocalization studies indicate that Cx26 and Cx32 exist either independently of one another or can colocalize along the lateral plasma membrane of epithelial cells in young rats or between principal cells in the adult rat epididymis. The presence of multiple connexins (Cxs) and their differential regulation suggest that these play different roles in epididymal development.
The epididymis is responsible for posttesticular sperm maturation. Sperm maturation is dependent on the luminal microenvironments along the epididymis. Though the role of the epididymis is well established, the molecular and cellular mechanisms responsible for sperm maturation remain to be elucidated, particularly in the human, as limited biological tools exist. We have established the first stable epithelial cell lines transformed with SV40 large T antigen (LTAg) from two regions of the human adult epididymis. The cell lines are composed of homogenous populations of diploid principal cells that possess ultrastructural characteristics similar to those of human principal cells in vivo. These cells express transcripts for adherens (cadherins CDH1 and CDH2) and tight (claudins CLDN1, CLDN2, CLDN3, CLDN4, CLDN7, and CLDN8) junctions as well as desmosomes (desmoplakin, DSP). Transepithelial resistance (TER) measurements in fertile human caput epididymal cell line 1 (FHCE1) as well as the immunolocalization of tight junctional protein 1 (TJP1), occludin, and CLDN1 indicate that these cells form functional tight junctions. Furthermore, knockdown of CLDN1, CLDN3, CLDN4, or CLDN7 using specific siRNAs resulted in significant decreases in TER, suggesting that these CLDNs are essential for the barrier function of the blood-epididymis barrier. Disruption of CLDN1, CLDN3, CLDN4, and CLDN7 could, therefore, lead to epididymal dysfunction, resulting in male infertility.
Orchestration of occludins, claudins, catenins and cadherins as players involved in maintenance of the blood-epididymal barrier in animals and humans
Although spermatozoa are formed during spermatogenesis in the testis, testicular spermatozoa are immature and cannot swim or fertilize. These critical spermatozoal functions are acquired in the epididymis where a specific luminal environment is created by the blood-epididymal barrier; proteins secreted by epididymal principal cells bind to maturing spermatozoa and regulate the maturational process of the spermatozoa. In the epididymis, epithelial cell-cell interactions are mediated by adhering junctions, necessary for cell adhesion, and by tight junctions, which form the blood-epididymal barrier. The regulation of these cellular junctions is thought to represent a key determinant in the process of sperm maturation within the epididymis. Tight junctions between adjacent principal cells permit the formation of a specific microenvironment in the lumen of the epididymis that is essential for sperm maturation. Although we have made significant progress in understanding epididymal function and the blood-epididymal barrier, using animal models, there is limited information on the human epididymis. If we are to understand the normal and pathological conditions attributable to human epididymal function, we must clearly establish the physiological, cellular and molecular regulation of the human epididymis, develop tools to characterize these functions and develop clinical strategies that will use epididymal functions to improve treatment of infertility.
The objectives of this study were to determine the effects of propylthiouracil (PTU)-induced neonatal hypothyroidism on the gap junctional protein Cx43 in rat testis and epididymis. PTU (0.02%) was administered via lactation from birth to Day 30, and the rats were sampled at 14, 18, 22, 26, 30, and 91 days of age. Testicular Cx43 was localized along the plasma membranes and cytoplasm of Sertoli cells until Day 22. At Day 30, the immunostaining was localized exclusively along the plasma membrane of Sertoli cells. In PTU-treated rats, Cx43 did not localize to the plasma membrane and was still cytoplasmic at 30 days of age. Occludin was present in tubules of treated rats, but was not localized to the blood-testis barrier in 30-day-old rats, as in controls. There were no differences in Cx43 immunostaining in the adult testis. In the proximal epididymis (initial segment, caput, corpus), Cx43 mRNA levels were lower in PTU-treated rats at 14, 18, and 22 days of age, but no differences were observed in the distal (cauda) epididymis at these ages. In 22- and 30-day-old rats, Cx43 was localized along the plasma membrane between principal and basal cells throughout the epididymis. In PTU-treated rats, Cx43 was not detectable in initial segment, caput, or corpus epididymidis. In the cauda epididymidis, however, Cx43 immunostaining in PTU-treated rats was similar to controls. These data suggest that thyroid hormones regulate Cx43-dependent gap junctional communication in the testis and epididymis.
Catenins in the Rat Epididymis: Their Expression and Regulation in Adulthood and during Postnatal Development
Tight and adhering junctions are important in maintaining the integrity of the epididymal epithelium and formation of the blood epididymal barrier, which are crucial for sperm maturation and storage. The composition of the catenin-adhering junctional family of proteins and their relationship with tight junctions remain to be established in the epididymis. In the normal adult rat epididymis, immunostaining for three anticatenin antibodies (alpha, beta-, and p120ctn) was noted along the lateral plasma membranes (LPM) between adjacent epithelial cells. Although alpha-catenin and beta-catenin were maximally expressed in the corpus and cauda epididymis, p120 expression was intense and similar in all epididymal regions. Bilateral orchidectomy of adult rats indicated that the expression of p120 at the LPM was not altered compared with that in control animals. On the other hand, staining at the LPM for alpha- and beta-catenin was markedly reduced, concomitant with an increased cytoplasmic reaction in each epididymal region. As the staining pattern for alpha- and beta-catenin returned to that seen in control animals after testosterone supplementation, it is suggested that their localization and targeting to the LPM are regulated by androgens. This is confirmed by postnatal studies in which maximal expression at the LPM for each catenin occurs by d 49, when androgen levels are adult-like. Immunolocalization of zona occludens-1 along with immunoprecipitation of epididymal homogenates of the initial segment/caput region of the epididymis revealed that zona occludens-1 is an integral part of the adhering junctional complex in young rats and coprecipitates with beta-catenin at the level of the apical tight junctions.
The blood-epididymal barrier creates a unique microenvironment critical for sperm maturation. There is little information on proteins comprising epididymal tight and adhering junctions or on factors regulating their expression. Claudins are a family of transmembrane proteins reported to be exclusively localized to tight junctions. In the present study the expression of claudin-l (Cl-1) was examined with respect to the different cell types of the epididymis and its various regions as well as its expression during postnatal development and regulation by testicular factors, using both immunocytochemistry and Northern blot analysis. RT-PCR of adult epididymal and testicular RNA (positive control) indicated that Cl-1 messenger RNA (mRNA) transcripts were present in all regions of the epididymis. In the adult, Cl-1 was localized immunocytochemically along the entire length of the lateral plasma membranes between adjacent principal cells, including apical areas containing tight junctions, as well as at the interface between principal and basal cells and along the basal plasma membrane of the epithelium in relation to the basement membrane. Northern blot analysis of adult epididymis with a rat Cl-1 complementary DNA indicated the presence of two hybridizing bands of 4.0 and 1.5 kb. Postnatally, in the caput-corpus and cauda epididymidis, mRNA levels for both transcripts were lowest on day 7. In the caput-corpus epididymidis, mRNA levels for the 1.5-kb transcript increased significantly between 7 and 14 days, whereas the levels of the 4.0-kb transcript were significantly higher by day 21. Postnatal studies revealed that in the initial segment and caput epididymidis, Cl-1 immunostaining was present along the entire length of the lateral plasma membranes of undifferentiated epididymal epithelial cells as early as day 7, including apical areas containing tight junctions. By day 21, staining was identical to that of adult animals, but as this is an age when androgen levels are not at their peak, the data would suggest that they are not a prominent factor regulating Cl-1 expression. Orchidectomy and orchidectomy plus testosterone replacement experiments revealed differences in Cl-1 immunostaining in the initial segment, suggesting that localization of Cl-1 in epididymal tight junctions is androgen dependant. Thus, Cl-1 expression in the initial segment appears to be only partially under the control of androgens. However, in all other epididymal regions, orchidectomy with or without testosterone replacement, revealed no changes to the normal staining pattern, suggesting that androgens do not regulate Cl-1 expression in these regions. Taken together, these studies demonstrate that Cl-1 expression in the epididymis is not localized exclusively to tight junctions, but appears along the entire interfaces of adjacent epithelial cells as well as along the basal plasma membrane, suggesting a role for Cl-1 as an adhesion molecule. The data also suggest that the regulation of Cl-1 in the epididymis is complex and multifactorial.
The epididymis is an androgen-dependent organ that allows spermatozoa to become fully functional as they pass through this tissue. The specialized functions of the epididymis are mediated by interactions between epididymal epithelial cells and between epididymal cells and spermatozoa. Although the critical role of the epididymis in sperm maturation is well established, the mechanisms regulating cell-cell interactions remain poorly understood because of the lack of appropriate cell line models. We now report the characterization of a novel rat caput epididymal cell line (RCE) that was immortalized by transfecting primary cultures of rat epididymal cells with the simian virus 40 large T antigen. At the electron microscope level, the cell line was composed of epithelial principal cells with characteristics of in vivo cells; principal cells had well-developed Golgi apparatus, abundant endoplasmic reticulum cisternae, and few endosomes. RCE cells expressed the mRNAs coding for the androgen receptor, estrogen receptor alpha, and 4-ene-steroid-5-alpha-reductase types 1 and 2 as well as epididymal-specific markers Crisp-1 and epididymal retinoic acid binding protein. Epididymal retinoic acid binding protein expression was significantly induced with dihydrotestosterone, although this effect was not blocked by flutamide, suggesting that RCE cells are not androgen responsive. Neighboring cells formed tight and gap junctions characteristic of epididymal cells in vivo and expressed tight (occludin and claudin-1, -3, and -4) and gap junctional proteins (connexin-26, -30.3, -32, and -43). The RCE cell line displays many characteristics of epithelial principal cells, thus providing a model for studying epididymal cell functions.
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