Lauri J. Pelliniemi

Fetal leydig cells : cellular origin, morphology, life span, and special functional features

Abstract The Leydig cells, responsible for testicular androgen production, have two growth phases during the life-span of mammals. The fetal population appears during fetal life and is responsible for the androgen-induced differentiation of the male genitalia. The fetal Leydig cells disappear after birth, and the other population, the adult Leydig cells, appears during puberty and persists for the whole adult life. The fetal Leydig cells, evidently due to the intrauterine endocrine milieu and their special functional requirements in genital differentiation, differ both morphologically and functionally from the adult population. The purpose of this review is to elucidate the special features of the mammalian fetal Leydig cell population, which presents an intriguing experimental model for studies of function and regulation of steroidogenic cells.

Transient coexpression of cytokeratin and vimentin in differentiating rat sertoli cells

The expression of cytokeratin and vimentin type intermediate filaments were studied in fetal, postnatal, and adult rat testes. Immunocytochemical observations were correlated with the light and electron microscopic analysis of the developing organs. The Sertoli cell precursors in 15-day-old fetal testes contained both cytokeratin and vimentin. A gradual reorganization of both filaments, accompanied by a decrease of cytokeratin-positivity, was observed toward the end of the fetal period. The simultaneous presence of cytokeratin and vimentin in the same cells was shown by double immunofluorescence of newborn testes and the primary culture of dissociated testicular cells. In postnatal Sertoli cells, cytokeratin-positivity continued to decrease and disappeared by the age of 14 days. The increase in vimentin content and the appearance of axially oriented vimentin filaments coincided with the acquisition of the columnar shape of the Sertoli cells. The presence of cytokeratin and vimentin in fetal and newborn testes, and only vimentin in the adult testes was confirmed by immunoblotting. The present results suggest that major qualitative changes in the expression of intermediate filament proteins can take place during the embryonic development. The expression of cytokeratin in developing Sertoli cells, although only transient, supports the epithelial origin of these cells and can be applied as a marker for embryonic and early postnatal Sertoli cells.

Fine structure of the human foetal testis

SummaryThirteen male human foetuses ranging in crown-rump length from 29 to 212 mm (ages 8–27 weeks) were studied. Four developmental phases are distinguished. 1. The predifferentiation phase (below 8 weeks): The interstitium contains only undifferentiated mesenchymal cells. 2. The differentiation phase (8–14 weeks): Leydig cells develop and gradually fill the space between the germ cords. 3. The maturity phase (14–18 weeks): The interstitium occupies more than one half of the total area in the testis sections and is filled with mature foetal Leydig cells. 4. The involution phase (18–40 weeks): Most of the Leydig cells gradually degenerate and disappear.The foetal Leydig cells are packed with tubular agranular endoplasmic reticulum (AER). Islets of parallel granular ER membranes and other organelles are embedded in the AER. The mitochondria vary in shape and form, the cristae being mainly tubular. Some mitochondria like organelles contain electron dense inclusions. Dark membrane bound bodies of variable form and resembling the Golgi cisternae are present in most cells. Reinke crystals are never found in the foetal cells. In degenerating Leydig cells the AER appears in vesicular form, membranous whorls are seen in some of them and the cell membrane seems to rupture finally, and cytoplasmic material protrudes outside the cells. The fine structure of the mature foetal Leydig cells is suggested to reflect signs of human chorionic gonadotrophin stimulation.

Human vascular adhesion protein-1 in smooth muscle cells

Human vascular adhesion protein-1 (VAP-1) is a dual-function molecule with adhesive and enzymatic properties. In addition to synthesis in endothelial cells, where it mediates lymphocyte binding, VAP-1 is expressed in smooth muscle cells. Here we studied the expression, biochemical structure, and function of VAP-1 in muscle cells and compared it to those in endothelial cells. VAP-1 is expressed on the plasma membrane of all types of smooth muscle cells, but it is completely absent from cardiac and skeletal muscle cells. In tumors, VAP-1 is retained on all leiomyoma cells, whereas it is lost in half of leiomyosarcoma samples. In smooth muscle VAP-1 predominantly exists as a approximately 165-kd homodimeric glycoprotein, but a trimeric (approximately 250 kd) form of VAP-1 is also found. It contains N-linked oligosaccharide side chains and abundant sialic acid decorations. In comparison, in endothelial cells dimeric VAP-1 is larger, no trimeric forms are found, and VAP-1 does not have N-glycanase-sensitive oligosaccharides. Unlike endothelial VAP-1, VAP-1 localized on smooth muscle cells does not support binding of lymphocytes. Instead, it deaminates exogenous and endogenous primary amines. In conclusion, VAP-1 in smooth muscle cells is structurally and functionally distinct from VAP-1 present on endothelial cells.

Overlapping and differential localization of Bmp-2, Bmp-4, Msx-2 and apoptosis in the endocardial cushion and adjacent tissues of the developing mouse heart

Abstract. The bone morphogenetic proteins BMP-2 and BMP-4 and the homeobox gene MSX-2 are required for normal development of many embryonic tissues. To elucidate their possible roles during the remodeling of the tubular heart into a fully septated four-chambered heart, we have localized the mRNA of Bmp-2, Bmp-4, Msx-2 and apoptotic cells in the developing mouse heart from embryonic day (E) 11 to E17. mRNA was localized by in situ hybridization, and apoptotic cells by TUNEL (TDT-mediated dUTP-biotin nick end-labeling) as well as by transmission electron microscopy. By analyzing adjacent serial sections, we demonstrated that the expression of Msx-2 and Bmp-2 strikingly overlapped in the atrioventricular canal myocardium, in the atrioventricular junctional myocardium, and in the maturing myocardium of the atrioventricular valves. Bmp-4 was expressed in the outflow tract myocardium and in the endocardial cushion of the outflow tract ridges from E12 to E14. Msx-2 appeared in the mesenchyme of the atrioventricular endocardial cushion from E11 to E14, while Bmp-2 and Bmp-4 were detected between E11 and E14. Apoptotic cells were also detected in the mesenchyme of the endocardial cushion between E12 and E14. Our results suggest that BMP-2 and MSX-2 are tightly linked to the formation of the atrioventricular junction and valves and that BMP-4 is involved in the development of the outflow tract myocardium and of the endocardial cushion. In addition, BMP-2, BMP-4 and MSX-2 and apoptosis seem to be associated with differentiation of the endocardial cushion.

Decorin is produced by capillary endothelial cells in inflammation-associated angiogenesis.

Decorin is a small extracellular chondroitin/dermatan sulfate proteoglycan that has previously been shown to be involved in the angiogenesis-like behavior of endothelial cells (ECs) in vitro. There is also evidence that decorin plays a role in angiogenesis in vivo. In this study we sought to further explore the involvement of decorin in angiogenesis in vivo, especially in that associated with inflammation. We found by CD31 immunostaining of ECs that in giant cell arteritis there are capillary blood vessels not only in the adventitia as in uninvolved temporal artery wall, but also in the media and the external zone of the thickened intima. Localization of decorin by antiserum LF-30 in adjacent sections showed that in normal temporal artery wall decorin resides mainly in the media and the adventitia, whereas in inflamed temporal artery wall decorin is distributed throughout the vessel wall including the intima. Furthermore, the most intense reaction for decorin was evident in ECs of capillary neovessels within the media and the thickened intima of inflamed temporal artery wall. Decorin was also found in capillary ECs in certain pathological and physiological conditions in which the pivotal role of angiogenesis is more generally accepted. Pyogenic granulomas, granulation tissue of healing dermal wounds, and ovaries at different phases of follicle and corpus luteum formation all contained widely distributed CD31-positive capillaries. Decorin, on the other hand, was found in capillary ECs in pyogenic granulomas and granulation tissue, but not in those in the ovaries. The assessment of the degree of inflammation in the specimens with the presence of CD68-positive macrophages showed that the pyogenic granuloma, granulation tissue, and giant cell arteritis specimens were rich in macrophages around the decorin-positive capillaries. In contrast, the ovarian specimens were populated with fewer macrophages and even they were not located in close vicinity of capillaries negative for decorin. Our results confirm that decorin is involved in angiogenesis in vivo and, particularly, in conditions in which the inflammatory component is dominant.

Ultrastructure of the indifferent gonad in male and female pig embryos

Pig embryos aged 24 days were obtained from artifically inseminated sows for ultrastructural study of the indifferent gonads. Sex was identified by chromosome analysis. The gonads are composed in both sexes of three different tissues: the surface epithelium, the gonadal blastema and the mesenchyme. The surface epithelial cells contained elongate mitochondria, granular endoplasmic reticulum, free polysomes, the Golgi complex, fine filaments and coated vesicles. The primitive cords were continuous with the surface epithelium and the interior of the gonad was occupied by blastema cells. They had prominent nucleoli, elongate mitochondria, granular endoplasmic reticulum, the Golgi complex, free polysomes, some lipid droplets and occasionally circular smooth membrane profiles resembling the agranular endoplasmic reticulum. Individual primordial germ cells were seen in all parts of the gonad. They were roundish with prominent nucleoli, globular mitochondria, granular endoplasmic reticulum, free polysomes, the Golgi complex, coated vesicles, lipid droplets and dense bodies. Degenerating cells and cells having pseudopods were also encountered. In comparison to the gonad at the age of 22 days, the primordium had grown into a longitudinal roundish protrusion and the number of primoridal germ cells had increased. Histological and ultrastructural observations showed that the pig gonads at the age of 24 days were similar in both sexes.

Morphogenesis and Fibronectin in Sexual Differentiation of Rat Embryonic Gonads

The possible role of fibronectin in the organization of the sex-specific gonadal components was studied by immunocytochemistry combined with electron and light microscopy in rat fetuses at the ages of 12-15 days. Fibronectin was evenly distributed in both sexes under the basal lamina of the surface epithelium. Other basal laminae were not seen using light or electron microscopy inside the gonadal ridges at the age of 12 days. As the first sign of sexual differentiation, fibronectin-negative gonadal cords appeared in 13-day-old fetuses. In the males the cords were bigger than those in the females. The cords were clearly separated from the interstitium in 15-day-old fetuses of both sexes. A continuous layer of fibronectin had formed between the testicular surface epithelium and the elongated cords indicating the formation of a tunica albuginea. In females the surface epithelium-cord connection was maintained at all stages. Connections of the gonadal cords to mesonephric tubuli were seen in the rete region of both sexes. The electron optical basal lamina around the gonadal cords became continuous by the age of 15 days. The present results suggest that fibronectin is intimately involved in the sexual differentiation of the gonads, but not under the regulation of H-Y antigen or other testis-organizing factor.

Ultrastructure of gonadal ridge in male and female pig embryos

SummaryPig embryos aged 21–22 days (d) were obtained from artificially inseminated sows for an ultrastructural study of the development and sex differentiation of the gonadal ridge. The chromosomal sex of the embryos was identified by a chromosome analysis.At the age of 21 d the gonadal ridge consisted of three different tissue: the surface epithelium, the primitive cords, and the mesenchyme.The surface epithelial cells contained elongate mitochondria with lamellar cristae, granular endoplasmic reticulum (GER), the Golgi complex, free polysomes, coated vesicles and fine filaments. The epithelium was continuous with the primitive cords, which were composed of ultrastructurally similar cells. The epithelial basal lamina followed the cord surface, but covered it incompletely.Primordial germ cells (PGC) were located under the surface epithelium in the mesenchyme and in the cords. The nucleus with a prominent nucleolus, and the large mitochondria were round. The cytoplasm contained a pair of centrioles, the Golgi complex, solitary lamellae of the GER, free polysomes, lipid droplets and some coated vesicles. The PGC entered the gonadal cords before these were surrounded by the continuous basal lamina.A day later (22 d) the number and length of the cords were increased. The PGC were more frequent and seen also in deeper layers. All the structures studied at the age of 21–22 d showed that the gonadal ridge also at the ultrastructural level is at the sexually indifferent stage.

Sox9 protein in rat Sertoli cells is age and stage dependent

Abstract We studied the location of Sox9 protein in the embryonic, juvenile, and adult rat testis by immunohistochemistry and immunoblotting. Sox9 belongs to a family of Sox proteins that are transcription factors and important in several developmental processes. In the incipient embryonic testis, Sox9 was prominently present in the gonadal blastema. With further embryonic differentiation, Sox9-positive cells arranged in the periphery of the testicular cords, showing the location of the Sertoli cells. Thereafter the immunoreaction for Sox9 gradually declined and was only weakly detectable in the 2-day-old postnatal rat testis. This situation remained for some period of time. In the 15-day-old rat testis, Sox9 protein strongly reappeared in the testicular cords. In the adult, the Sertoli cells of most regions of the seminiferous tubules were positive for Sox9. The strongest reaction for Sox9 was found in the dark zone. However, clearly negative or only weakly positive spermatogenic stages for the protein were also found, as seen for example in the pale zone. In fertile 1-year-old rats this basic situation was still detectable. Analyzed rat ovaries were all negative for Sox9, showing the sex-specific nature of Sox9. The results showed that Sox9 protein is distinctly present in the developing and mature Sertoli cells, but that its presence and amount is dependent on the age and the spermatogenetic stage within the seminiferous tubuli. The prominent presence of Sox9 in the incipient testis and at puberty suggests that this protein is needed at important phases of aggregation and reorganization of the Sertoli cells. The age and stage-specific presence of Sox9 in the testicular cords and in the seminiferous tubules of the adult suggests that Sox9 also may have a pivotal role in germ cell differentiation.