S-100 protein immunoreactivity in mammalian testis and epididymis

The present study deals with immunohistochemical localization of S-100 protein in mouse, bank vole and pine vole testis and epididymis. S-100 protein immunoreactivity was observed in the endothelia of capillaries and lymphatic sinusoids of pine vole testis. A reaction to S-100 protein of the same intensity as that noted in the endothelia of testicular capillaries was found in myoid cells of pine vole and bank vole seminiferous tubules. Moreover, a positive reaction to S-100 protein was observed in bank vole and mouse Leydig cells. In the epididymis, a weaker reaction to S-100 occurred in smooth muscles of pine vole and mouse epididymal duct. Despite difficult interpretation of physiological role of S-100 protein we suggest that it may be a part of the blood-testis barrier. It may also participate in the processes of transcytosis and contractility; its cellular expression is regulated by local factors. However, location of S-100 is not specific to the representatives of the same order.     

Characterization of the glycoconjugates of boar testis and epididymis

Lectin histochemistry was used to perform in situ characterization of the glycoconjugates present in boar testis and epididymis. Thirteen horseradish peroxidase- or digoxigenin-labelled lectins were used in samples obtained from healthy fertile boars. The acrosomes of the spermatids were stained intensely by lectins with affinity for galactose and N-acetyl-galactosamine residues, these being soybean, peanut and Ricinus communis agglutinins. Sertoli cells were stained selectively by Maackia ammurensis agglutinin. The lamina propria of seminiferous tubules showed the most intense staining with fucose-binding lectins. The Golgi area and the apical part of the principal cells of the epididymis were stained intensely with many lectins and their distribution was similar in the three zones of the epididymis. On the basis of lectin affinity, both testis and epididymis appear to have N- and O-linked glycoconjugates. Spermatozoa from different epididymal regions showed different expression of terminal galactose and N-acetyl-galactosamine. Sialic acid (specifically alpha2,3 neuraminic-5 acid) was probably incorporated into spermatozoa along the extratesticular ducts. These findings indicate that the development and maturation of boar spermatozoa are accompanied by changes in glycoconjugates. As some lectins stain cellular or extracellular compartments specifically, these lectins could be useful markers in histopathological evaluation of diseases of boar testis and epididymis.     

The N-acetylhexosaminidase components of the ram testis and epididymis

Three and four N-acetylhexosaminidase components, from ram testis and epididymis respectively, have been separated by ion-exchange chromatography on DEAE-cellulose. Although they all have the same molecular weight (approx. 140000) and very similar catalytic properties towards the synthetic substrates, 4-methylumbelliferyl N-acetyl-beta-glucosaminide and N-acetyl-beta-galactosaminide, isoelectric focusing of the individual components showed that each had a distinct pI value. Isoelectric focusing has also been used to demonstrate the occurrence of multiple forms in ejaculated ram semen.     

Post-natal sexual development of testis and epididymis in the rabbit: variability and relationships among macroscopic and microscopic markers

The present work was performed to examine the existence of some relationships between macroscopic and microscopic traits of testis and epididymis in rabbit. The variables studied were live weight (LW), testis length (TL), testis width (TWh), testis weight (TW), testis volume (TV), epididymis length (EL), epididymis width (EWh), epididymis weight (EW), epididymis volume (EV), percentage of seminiferous tubules with presence of lumen (STL), percentage of seminiferous tubules with presence of elongated spermatids (STES), percentage of seminiferous tubules with presence of spermatozoa (STS) and diameter of seminiferous tubules (STD). Measurements began after weaning and continued until males reached 33 weeks of age.Phenotypic correlations between testis and epidydimis traits and the principal component analysis were estimated as the residual correlation from an analysis of variance, including the effects of line, birth-season, age, and the double interactions line × age and birth-season × age.Four principal components (PCs) explained 79% of the total variation. The predominant variables defining the first PC were TL, TW and TV. Epididymis width and STS were located in the second PC. Epididymis weight and EV were important in the definition of the first and third PC. Tubular diameter seems important in the definition of the fourth PC.It has been not found correlation between traits related to either testis or epididymis size and variables related to active spermatogenesis. Therefore, TW and/or TV seemed not to be good markers of maturity.     

Localization of the antigotensin-converting enzyme activity in testis and epididymis

Angiotensin-converting enzyme (ACE) has been studied in different reproductive organs of the male rat, in somatic cell lines clonally derived from both rat and mouse testes, and in isolated spermatogenic cells of the mouse. Among the various reproductive organs only testis and epididymis show high levels of enzyme activity. The testicular activity is found mainly in the isolated germinal cells and residual bodies, whereas somatic cell lines contain negligible levels of activity even after addition of hormones and growth factors. Testicular homogenates, spermatogenic cells, epididymal spermatozoa, and spermatozoan cytoplasmic droplets, when fractionated by anion exchange chromatography, contain one major and one minor activity peak, whereas epididymal homogenates and epididymal secretions reveal an additional major activity peak together with the minor peak. All forms of ACE have a similar response to different modifiers, and are equally sensitive to the specific inhibitor N-[(S)-1-(ethoxycarbonyl)-3-phenylpropyl]-L-alanyl-L-proline (Enalapril). The testicular enzyme could provide a useful marker for spermatogenic maturation and/or cytoplasmic processes both in testis and epididymis. The separate epididymal peak is a secretory enzyme that may be responsible for the processing of spermatozoan plasma membrane constituents during epididymal transit, or may have a role in attacking some biologically active compounds.     

Distribution of sodium-potassium ATPase in the rat testis and epididymis.

Sodium-potassium ATPase (Na+K(+)-ATPase) is a ubiquitous plasma membrane enzyme which uses the hydrolysis of ATP to regulate cellular Na+ and K+ levels and fluid volume. This ion pumping action is also thought to be involved in fluid movement across certain epithelia. There are several different genes for this enzyme, some of which are tissue specific. Using an antibody specific for the catalytic subunit of canine kidney Na+K(+)-ATPase, we have localized immunoreactivity in the seminiferous and epididymal epithelium of rats of various ages. There was no specific staining of 10-day-old rat testis. Faint staining was detected at 13 days and appeared to be associated with the borders of Sertoli cells. At 16 days prominent apical and lateral staining but no basal staining of Sertoli cell membranes was observed. This type of distribution continued until spermatids were present in the epithelium. In the adult rat testis, specific staining was detected in Sertoli cell crypts associated with elongating spermatids, and on the apical and lateral Sertoli cell membrane. In some instances immunoreactivity was concentrated at presumed sites of junctional specializations. In the excurrent ducts of immature and mature rats, Na+K(+)-ATPase staining was heavy in the efferent ducts and somewhat lighter in the epididymis. In all regions, the staining was basolateral although there were variations in intensity among the different parts of the epididymis. These results show 1) that rat testis and epididymal Na+K(+)-ATPase share some immunological determinants with the canine enzyme; 2) that the epididymal enzyme is located in the conventional basolateral position; and 3) that the distribution of Sertoli cell Na+K(+)-ATPase is probably apical and lateral rather than basal.     

Postnatal development of lectin-binding pattern in the rat testis and epididymis

Seven rhodamine-conjugated lectins were utilized to study the distribution of glycoproteins in the developing rat testis and epididymis. In the testis a clear developmental pattern was found in Leydig cells and the cell boundaries between Sertoli and spermatogenic cells, as well as during acrosome formation. Some of the first degenerating meiotic cells and the apical extensions of the Sertoli cells at the time of spermiation also displayed a characteristic lectin binding. The epididymal differentiation was characterized by an increasing lectin binding of the subapical Golgi zone and apical surface, and intratubular secretion prior to the arrival of sperm. After the accumulation of tubular secretion and sperm some epithelial cells were transformed into narrow (initial segment) and light cells (distal caput, cauda) with a strong affinity for some lectins. These cells appeared to be responsible for the absorption and digestion of tubular material derived from the testis and of surplus secretion and/or sperm structures.     

Anatomic distribution of lectin-binding sites in mouse testis and epididymis

Abstract. Testis and epididymis of sexually mature mice were studied histochemically using 25 fluorescein-isothiocyanate-labeled lectins. Several lectin-specific binding patterns were recognized. Thus, HAA, HPA, GSA-I, and UEA-I1 reacted only with spermatozoa. PNA, GSA-11, SBA, VVA, BPA, RCA-I, and RCA-I1 reacted with spermatozoa and spermatocytes. WGA, PEA, LCA, and MPA reacted with spermatogonia, spermatocytes, and spematozoa in increasing order of intensity. ConA, SUC. ConA, LAA, STA, LTA, LPA, PHA-E, PHA-L, IJEA-I, and LBA reacted with all spermatogenic cells with equal intensity. In the epididymis, 12 lectins reacted uniformly with the epithelial cells lining all segments of this organ. One lectin (VVA) did not react with epididymal lining cells. The remaining 12 lectins reacted in a specific manner with portions of the head, body, or tail, thus selectively outlining different portions of the epididymis. RCA-I and RCA-I1 selectively accentuated the so-called halo cells of the epididymis. These findings provide a detailed map of lectin-binding sites in the mouse testis and epididymis and show that certain lectins can be used as specific markers for spermatogenic cells and segments of the epididymis.     

Peroxisomes and ether lipid biosynthesis in rat testis and epididymis

Plasmalogens are a main component of the spermatozoon membrane, playing a crucial role in their maturation. The initial steps in plasmalogen biosynthesis are catalyzed by two peroxisomal enzymes, dihydroxyacetonephosphate acyltransferase and alkyl-dihydroxyacetonephosphate synthase. The localization of both enzymes in the membrane of peroxisomes implies that plasmalogen-producing cells should contain this organelle. To unravel the putative source of spermatozoan plasmalogens we investigated which cell types in the testis and epididymis are endowed with peroxisomes. To this extent, testicular and epididymal tissue was analyzed at the protein and RNA levels by means of light and electron microscopical immunocytochemistry as well as by Western and Northern blotting. Proteins and mRNAs of peroxisomal enzymes, especially those of dihydroxyacetonephosphate acyltransferase and alkyl-dihydroxyacetonephosphate synthase, were detected in the testis and epididymis. In the testis, peroxisomes were localized exclusively in Leydig cells and not in cells of the seminiferous tubules, implying that the latter do not contribute to the biosynthesis of plasmalogens of the sperm membrane. In contrast, peroxisomes could be clearly visualized in the epithelial cells of the epididymis. The results suggest that peroxisomes in epithelial cells of the rat epididymis play a pivotal role in the biosynthesis of plasmalogens destined for delivery to the sperm plasma membrane.     

Initiation of sperm motility in the mammalian epididymis.

Spermatozoa acquire the capacity for motility as they traverse the mammalian epididymis. The biochemical basis for this induction of motility is still largely unknown. Current theories are discussed and recent studies from the authors' laboratory are described which indicate that two separate processes are involved and that these act synergistically. These processes are an increase in the intrasperm content of cyclic AMP during epididymal transit combined with the binding of a specific forward-motility protein. A second increase in cyclic AMP and stimulation by calcium ion is likely involved in the expression of the acquired potential for motility at the time of ejaculation.     

Nonspecific esterases of mammalian testis

Summary Ten different nonspecific esterases in both mouse (Mus musculus) and rat (Rattus norvegicus) testis were identified following the analysis of electrophoretic patterns using genetic, developmental, and biochemical criteria. None of the enzymes were unique to testis, although the pattern of activity was testis specific. The enzymes comprised, in each species, six carboxylesterases (EC 3.1.1.1), one arylesterase (EC 3.1.1.2), one acetylesterase (EC 3.1.1.6), and two butyrylesterases (tentative designation). Cholinesterase (EC 3.1.1.8) was not detected. Individual homology relationships were recognized between the two species for all of these activities, except three of the carboxylesterases; however, these were coded for by homologous gene clusters. Similarities between the two species extended to the developmental course of expression and the modulation of the pattern of activity by the testicular feminization (Tfm) mutation. We describe the effects of the sex reversal (Sxr) mutation in the mouse, as well as the distribution of individual activities between Leydig cells and seminiferous tubules. The results of earlier histochemical studies are interpreted in the light of the present investigation. The correspondence between mouse- and rat-testis esterases suggests that the results could serve as a basis for mammalian testis esterase systems in general.This is communication no. 47 of a research program devoted to the cellular distribution, genetics, and regulation of nonspeific esterases. This work was supported by the Dcutsche Forschungsgemeinschaft     

Immunolocalization of PTHrP in the European bison and pine vole testis and epididymis

The present study deals with immunohistochemical localization of PTHrP in European bison and pine vole testis and epididymis. PTHrP immunoreactivity was observed in spermatogenic cells of seminiferous tubules in European bison and pine vole testis, with the strongerst reaction occurring in spermatozoa of pine vole testis and epididymal duct. We also observed PTHrP expression in vascular smooth muscle of epididymis and testis in both animal species, as well as slightly weaker reaction in endothelial cells of European bison epididymis. PTHrP was also expressed in the smooth muscle of the epididymal duct in European bison and pine vole. In conclusion, PTHrP is a multifunctional peptide showing both paracrine and autocrine action. Its presence in vascular endothelium and smooth muscle of testis and epididymis is connected with the regulation of vascular muscle tone, thus affecting blood flow in the vessels. PTHrP expression depends on a number of local factors. Moreover, we suppose that PTHrP also contributes to the proliferation and differentiation of spermatogenic cells.     

Expression and localization of PMCA4 in rat testis and epididymis

It has recently been shown in mice that the plasma membrane Ca²⁺-ATPase isoform 4 (PMCA4) is essential for sperm fertilization capacity. We analyzed whether sperm PMCA4 is formed in the rat during spermatogenesis or is synthesized in the epididymis and transferred onto sperm during sperm maturation. We could show that PMCA4 is conserved in sperm from testis to epididymis. In testis, PMCA4 mRNA was restricted to spermatogonia and early spermatocytes, while the PMCA4 protein was detected in spermatogonia, late spermatocytes, spermatids and in epididymal sperm. In epididymis PMCA4 mRNA was localized in basolateral plasma membranes of epithelial cells of the caput, corpus and cauda epididymidis. In contrast, the protein was only detectable in the epithelial cells of the caput, indicating that PMCA4 mRNA is only translated into protein in caput epithelium. In the epididymal corpus and cauda, PMCA4 mRNA and protein, respectively, was localized and in peritubular cells. Furthermore, we detected an identical distribution of PMCA4a and b splice variants in rat testis, epididymal corpus and cauda. In the caput epididymidis, where PMCA4 is located in the epithelium splice variant 4b was more prominent. Further experiments have to clarify the functional importance of the differences in the PMCA4 distribution.     

Histochemical localization of carbonic anhydrase in the testis and epididymis of the boar.

The testis and epididymis of sexually mature, fertile boars were studied for localization of carbonic anhydrase (CA) using a cobalt precipitation technique. In the testis, cytoplasmic CA was found in the Sertoli cells and in the capillaries surrounding the seminiferous tubules. The epididymal duct was divided into initial, middle and terminal segments, and regional differences in CA activity were observed. The cell membranes of the basal cells were stained in the initial and middle segments. Strong cytoplasmic CA staining was present only in the apical cells in the initial and middle segments. The basolateral cell membranes were stained in the principal cells of the terminal segment and the ductus deferens. As a rule the capillaries surrounding the epididymal duct were unstained. The enzyme, specifically localized in regions of the male genitalia acting as sperm reservoirs, might be related to the quiescence of the stored spermatozoa by influencing the acid-base status of the epididymal fluid.