Identification of collagens in the human testis

Effects of phytoestrogens combined with cold stress on sperm parameters and testicular proteomics in rats

Phytoestrogens and cold negatively influence male fertility. However, the combined effects of these two factors on male reproduction remain unknown. Herein, we studied the changes of sperm parameters and identify potential biomarkers involved in testis of rats, which were intervened by phytoestrogens combined with cold stress. Male Sprague-Dawley rats were randomly divided into control and model groups. The rats in the model group were fed an estrogen diet and placed in a climate chamber [10 ± 2°C; humidity of 75 ± 5%] for 12 h/daily. When compared with the control group after 24 weeks, the rats in the model group showed increased food intake, urine and stool outputs, and higher estradiol and follicle-stimulating hormone levels. However, lower sperm concentration, motility, and viability, and reduced testosterone levels were detected. The epithelial cells of the seminiferous tubules and epididymal ducts presented morphological abnormalities. Proteomic analysis showed that 24 testicular proteins were upregulated and 15 were downregulated. The identified proteins were involved in reticulophagy and stress response. Our findings suggest that the phytoestrogens combined with cold stress had negative effects on the reproductive function of male rats and provide the basis for the establishment of "course simulation" type of oligospermia animal model.

Characterization and distribution of hyaluronan and the proteoglycans decorin, biglycan and perlecan in the developing embryonic mouse gonad

The morphogenesis of tissues and organs requires dynamic changes in cells and in extracellular matrix components. It is known that various extracellular matrix molecules are of fundamental importance for gonad differentiation and growth. In the adult testis, the extracellular matrix represents an important component of the interstitium, participating in the transport of biologically active substances needed for the communication between different cellular components, as well as for the regulation of spermatogenesis and hormone production. The present study was designed in order to identify the proteoglycans biglycan, decorin and perlecan, as well as the glycosaminoglycan hyaluronan, during testis development in mouse embryos. Our data profile the chronology of testis differentiation, as well as the distribution of these extracellular matrix components during testis development in mice. We show that these extracellular matrix molecules are present early in the development of the gonads, suggesting that they play a role in gonad development. In addition, we found no decorin in the testicular cords. Furthermore, of the proteoglycans analysed, only biglycan was seen surrounding immature Sertoli cells and Leydig cell precursors in the testicular cords. This indicates that specific sets of extracellular matrix molecules are required in the various compartments of the developing gonad.

Immunocytochemistry of extracellular matrix components in the rat seminiferous tubule: electron microscopic localization with improved methodology

BACKGROUND

Cell-cell interactions between Sertoli, myoid, Leydig, and germ cells are thought to be essential for spermatogenesis. These cells interact with each other through the extracellular matrices (ECMs) of the testicular lamina propria, which thus may have an important function in spermatogenesis. For an understanding of the role of ECMs in spermatogenesis, it is important to investigate the molecular constitution of the testicular ECM. We examined the distribution of type IV, V, and VI collagens (Cols), laminin (LM), fibronectin (FN), and heparan sulfate proteoglycan (HSPG) in the rat testicular lamina propria.

METHODS

Adult rat testes were fixed with 4% paraformaldehyde and 0.2% glutaraldehyde. Ultrathin frozen sections were made and immunolabeling was performed according to the method of Tokuyasu (1986 J. Microsc., 143:139-149). Alternatively, for preembedding immunocytochemistry, we used labeling with nanogold, followed by silver enhancement and gold toning. The tissues were then fixed with osmium and embedded in Epon (Sawada and Esaki 1994 J. Electron Microsc., 43:361-366). These specimens were examined in a JEOL JEM-100C transmission electron microscope operated at 80 kV.

RESULTS

Col IV, LM, and HSPG were localized in the basement membranes of the seminiferous tubule (ST-BM) and in the BM of myoid cells. Cols V and VI, and FN were localized both in the connective tissue between the seminiferous tubule and the myoid cells (tubule-myoid connective tissue) and in the connective tissue between the myoid cells and the lymphatic endothelial cells (myoid-endothelium connective tissue). Furthermore, statistical analysis of the micrographs of immunogold labeling for Col IV, LM, and FN around the ST-BM suggested that the Col IV molecule is located uniformly in the ST-BM, whereas the LM molecule is distributed mainly in the lamina rara of ST-BM, and the FN molecule appears to be present predominantly in the tubule-myoid connective tissue.

CONCLUSIONS

Distinct distribution patterns were observed for each antigen within the testicular lamina propria at the ultrastructural level. However, localization of some components was not consistent with localizations reported by others.