Extracellular matrix promotes rat Sertoli cell histotypic expression in vitro

We describe procedures for the preparation of a cell-free seminiferous tubule biomatrix, and provide evidence demonstrating that this material constitutes a useful substratum for maintaining the normal architecture of Sertoli cells in primary culture. Seminiferous tubule biomatrix, which has the morphological appearance of a fibrillar network rich in filaments and amorphous substance, is shown to consist of about 50% protein, most of which is collagen and glycoproteins. Fibronectin and laminin are also present in the seminiferous tubule biomatrix, as judged by immunofluorescence microscopy. Sertoli cell aggregates plated on this substratum retain a cuboidal to columnar shape, spread very slowly to form a monolayer, and survive for at least 3 weeks when cultured in a hormone-free, serum-free, chemically defined medium. In contrast, Sertoli cells plated onto uncoated polystyrene readily spread to form a monolayer of flat squamous cells which do not survive as well. Other morphological and ultrastructural characteristics are described which indicate that cells cultured on the seminiferous tubule biomatrix more closely resemble those of Sertoli cells in vivo than do cells plated on uncoated plastic. These differences in cell structure, including the maintenance of normal polarity as indicated by the presence of basolateral tight junctional complexes, remain evident for periods of 10 to 14 days after plating Sertoli cells onto biomatrix substratum. Rates of DNA synthesis by immature Sertoli cells plated onto biomatrix are less than rates by cells plated onto uncoated plastic. The data are discussed in relation to the role of substratum in the preservation of normal functions and histotype of Sertoli cells.     

Extracellular matrix components and testicular peritubular cells influence the rate and pattern of Sertoli cell migration in vitro

We report the patterns of migration of Sertoli cells plated on specific substrata, and the influences of testicular peritubular cells on these processes. Data presented indicate that while peritubular cells readily spread when explanted onto Type I collagen, Sertoli cells do not. A delay of 4 to 6 days occurs after Sertoli cells are plated before they begin to migrate randomly to form plaque-like monolayers on Type I collagen. These processes are dependent upon the synthesis and subsequent deposition of laminin and/or Type IV collagen by Sertoli cells, and are independent of fibronectin. A different behavior occurs when reconstituted mixtures of purified Sertoli cells and pertiubular cells are sparsely plated onto Type I collagen. Peritubular cells rapidly spread to form chains of cells between Sertoli cell aggregates. Sertoli cells then migrate on the surfaces of the peritubular cells, culminating in the formation of cable-like structures between aggregates. Evidence is presented that the Sertoli cell migration to form "cables" under these conditions is dependent upon fibronectin synthesized by peritubular cells, and is independent of the presence of laminin or Type IV collagen. We discuss the possible relevance of these data to the role which precursors of peritubular cells may play in determining the behavior of Sertoli cell precursors in vivo during tubulogenesis, or in the remodelling of the seminiferous tubule which occurs during different stages of the cycle of the seminiferous epithelium in spermatogenesis.     

Morphogenetic restructuring and formation of basement membranes by Sertoli cells and testis peritubular cells in co-culture: inhibition of the morphogenetic cascade by cyclic AMP derivatives and by blocking direct cell contact

Addition of dibutyryl cyclic AMP (dbcAMP), methylisobutylxanthine (MIX), or cytochalasin D to co-cultures of Sertoli cells and testicular peritubular myoid cells blocks a series of morphogenetic changes which otherwise occur during culture. When Sertoli cells are plated directly onto preexisting layers of peritubular cells maintained under basal conditions, structures form which display many of the characteristics of germ cell-depleted seminiferous tubules. The presence of dbcAMP, MIX, or cytochalasin D, added at varying times after plating Sertoli cells, results in the inhibition of each successive stage of in vitro remodeling: the inhibition of migration of Sertoli cells, the inhibition of initial ridge formation, the blockage of subsequent formation of mounds and nodules of compacted Sertoli cell aggregates, the prevention of the formation of basal lamina and associated layers of extracellular matrix between Sertoli cell aggregates and surrounding peritubular cells, and the inhibition of tubule formation. The presence of dbcAMP also inhibits the migration of peritubular cells, contractions by these cells, and compaction of Sertoli cell aggregates. When intimate cell apposition is prevented by plating the two cell types on either side of a membrane filter, the morphogenetic cascade is blocked, and no formation of a germ cell-depleted seminiferous tubule-like structure occurs. Other effects of dbcAMP on cell shape, cell movement, and cell association patterns during co-culture are described. Possible mechanisms by which dbcAMP, MIX, or cytochalasin D blocks restructuring are discussed. Since each elicits perturbations of the cytoskeleton, we offer the interpretation that cytoskeletal changes may be correlated with the prevention of closely apposing cell compact and the inhibition of basement membrane formation. Interactions observed between Sertoli cells and peritubular cells during co-culture are postulated to be analogous to those occurring in other types of mesenchymal cell-epithelial cell interactions during organogenesis and during tubulogenesis in the fetal testis. Speculatively, the blockage by dbcAMP of the morphogenetic cascade in the co-cultured system may be related to the inhibition by dbcAMP of testis cord formation in organ cultures of fetal gonads reported by others.     

Transforming growth factor beta gene expression and action in the seminiferous tubule: peritubular cell-Sertoli cell interactions

The potential role of transforming growth factor beta (TGF beta) as a mediator of cell-cell interactions within the seminiferous tubule was investigated through an examination of the local production and action of TGF beta. Sertoli cells and peritubular (myoid) cells were isolated and cultured under serum-free conditions. Secreted proteins from Sertoli cells and peritubular cells were found to contain a component that bound to TGF beta receptors in RRA. Reverse-phase chromatography of Sertoli cell and peritubular cell secreted proteins fractionated a protein with similar biochemical properties as TGF beta 1. This fractionated protein also contained TGF beta bioactivity in its ability to inhibit growth of an epidermal growth factor-dependent cell line. Both peritubular cells and Sertoli cells contained a 2.4 kilobase mRNA species that hybridized in a Northern blot analysis with a TGF beta 1 cDNA probe. TGF beta 1 gene expression was not detected in freshly isolated germ cells. TGF beta 1 alone was not found to influence Sertoli cell nor peritubular cell proliferation with cells isolated from a midpubertal stage of development. The effects of hormones and TGF beta on Sertoli cell differentiation and function were assessed through an examination of transferrin production by Sertoli cells. TGF beta 1 had no effect on transferrin production nor the ability of hormones to influence transferrin production. The presence of peritubular cells in a coculture with Sertoli cells also did not affect the inability of TGF beta 1 to act on Sertoli cells. Although Sertoli cell function did not appear to be influenced by TGF beta 1, peritubular cells responded to TGF beta 1 through an increase in the production of a number of radiolabeled secreted proteins. TGF beta 1 also had relatively rapid effects on peritubular cell migration and the promotion of colony formation in culture. Cocultures of Sertoli cells and peritubular cells responded to TGF beta 1 by the formation of large cell clusters with ball-like structures. Data indicate that TGF beta may have an important role in influencing the differentiation and migration of peritubular cells. Observations demonstrate the local production of TGF beta within the seminiferous tubule by Sertoli cells and peritubular cells and suggest that TGF beta may have a role as a paracrine-autocrine factor involved in the maintenance of testicular function.     

Cytochemical and biochemical characterization of testicular peritubular myoid cells

Testicular peritubular myoid cells secrete a paracrine factor that is a potent modulator of Sertoli cell functions involved in the maintenance of spermatogenesis. These cells also play an integral role in maintaining the structural integrity of the seminiferous tubule. To better understand this important testicular cell type, studies were initiated to characterize cultured peritubular cells using biochemical and histochemical techniques. The electrophoretic pattern of radiolabeled secreted proteins was similar for primary and subcultured peritubular cells and was unique from that of Sertoli cells. Morphologic differences between Sertoli cells and peritubular cells were noted and extended with histochemical staining techniques. Desmin cytoskeletal filaments were demonstrated immunocytochemically in peritubular cells, both in culture and in tissue sections, but were not detected in Sertoli cells. Desmin is proposed to be a marker for peritubular cell differentiation as well as a marker for peritubular cell contamination in Sertoli cell cultures. Peritubular cells and Sertoli cells were also stained histochemically for the presence of alkaline phosphatase. Staining for the alkaline phosphatase enzyme was associated with peritubular cells but not with Sertoli cells. Alkaline phosphatase is therefore an additional histochemical marker for peritubular cells. Biochemical characterization of peritubular cells relied on cell-specific enzymatic activities. Creatine phosphokinase activity, a marker for contractile cells, was found to be associated with peritubular cells, while negligible activity was associated with Sertoli cells. Alkaline phosphatase activity assayed spectrophotometrically was found to be a useful biochemical marker for peritubular cell function and was utilized to determine the responsiveness of primary and subcultured cells to regulatory agents. Testosterone stimulated alkaline phosphatase activity associated with primary cultures of peritubular cells, thus supporting the observation that peritubular cells provide a site of androgen action in the testis. Retinol increased alkaline phosphatase activity in subcultured peritubular cells. Alkaline phosphatase activity increased in response to dibutyryl cyclic adenosine monophosphate (AMP) in both primary and subcultured peritubular cell cultures. Observations indicate that the ability of androgens and retinoids to regulate testicular function may be mediated, in part, through their effects on peritubular cells. This provides additional support for the proposal that the mesenchymal-epithelial cell interactions between peritubular cells and Sertoli cells are important for the maintenance and control of testicular function. Results imply that the endocrine regulation of tissue function may be mediated in part through alterations in mesenchymal-epithelial cell interactions.     

Actions of extracellular matrix on Sertoli cell morphology and function

Sertoli cells were isolated and cultured in the absence or presence of extracellular matrix (ECM) to determine whether ECM may influence Sertoli cell function on a molecular level. As previously described, a morphological analysis of the cells indicated that ECM allows the expression of a columnar histotype and the formation of junctional complexes. The combined actions of ECM and hormones were found to have a profound effect in promoting the expression of a polarized Sertoli cell morphology. In our investigation of the effects of ECM on Sertoli cells, we used transferrin and androgen-binding protein (ABP) production as biochemical markers of Sertoli cell function. The presence of ECM was found to cause a 25% increase in the basal level of transferrin production; however, ECM had no effect on the basal level of ABP production by Sertoli cells. Regulatory agents such as follicle-stimulating hormone (FSH) and a combination of FSH, insulin, retinol, and testosterone stimulated the production of both transferrin and ABP. The ability of hormones to stimulate these Sertoli cell functions was not influenced by the presence of ECM. Similar results were obtained with 2-microns- or 50-microns-thick ECM and with a seminiferous tubule biomatrix preparation. ECM was found to increase the maintenance of long-term Sertoli cell cultures; however, the decline in Sertoli cell functional integrity, which occurs during cell culture, was not affected by the presence of ECM. An additional functional parameter examined was the radiolabeled proteins secreted by Sertoli cells. ECM did not promote the production or affect the electrophoretic profile of Sertoli cell-secreted proteins under basal or hormonally stimulated conditions. Combined results indicated that although ECM allowed the expression of a normal Sertoli cell histotype, ECM had no major effects on the Sertoli cell functions analyzed nor on the hormonal regulation of these functions. The inability of ECM to affect Sertoli cell function on a molecular level is discussed with regard to environmental as opposed to regulatory cellular interactions. Our observations imply that dramatic effects of ECM on cell morphology do not necessarily correlate to subsequent effects on cellular function.     

Immortalization of germ cells and somatic testicular cells using the SV40 large T antigen

We report the immortalization, using the SV40 large T antigen, of all the cell types contributing to a developing seminiferous tubule in the mouse testis. Sixteen peritubular, 22 Leydig, 8 Sertoli, and 1 germ cell line have been established and cultured successfully for 90 generations in a period of 2.5 years. Immortalized peritubular cells were identified by their spindle-like appearance, their high expression of alkaline phosphatase, and their expression of the intermediary filament desmin. They also produce high amounts of collagen. Immortalized Leydig cells are easily identifiable by the accumulation of lipid droplets in their cytoplasm and the production of the enzyme 3-beta-hydroxysteroid dehydrogenase. Some Leydig cell lines also express LH receptors. The immortalized Sertoli cells are able to adopt their typical in vivo columnar appearance when cultured at high density. They exhibit a typical indented nucleus and cytoplasmic phagosomes. Some Sertoli cell lines also express FSH receptors. A germ cell line (GC-1spg) was established that corresponds to a stage between spermatogonia type B and primary spermatocyte, based on its characteristics in phase contrast and electron microscopy. This cell line expresses the testicular cytochrome ct and lactate dehydrogenase-C4 isozyme. These four immortalized cell types, when plated together, are able to reaggregate and form structures resembling two-dimensional spermatogenic tubules in vitro. When only the immortalized somatic cells are cocultured, the peritubular and Sertoli cells form cord-like structures in the presence of Leydig cells. Fresh pachytene spermatocytes cocultured with the immortalized somatic cells integrate within the cords and are able to survive for at least 7 days. The ability to perform coculture experiments with immortalized testicular cell lines represents an important advancement in our ability to study the nature of cell-cell and cell-matrix interactions during spermatogenesis and testis morphogenesis.     

Role of laminin in the Morphogenetic cascade during Coculture of sertoli cells with peritubular cells

Observations summarized in this article demonstrate an essential role of laminin during the restructuring processes that occur during coculture of Sertoli cells with testicular peritubular cells. The data presented indicate that laminin becomes detectable on the free surfaces of Sertoli cells only after reaggregation of Sertoli cells begins, coincident with the initiation of repolarization at a specific stage of the morphogenetic cascade. We infer that laminin deposited at this time serves as a cohesion molecule that permits peritubular cells to come into close contact with Sertoli cells and subsequently to spread along the free surfaces of Sertoli cells. These conclusions and inferences are based on the following experiments. Cycloheximide-treated peritubular cells in culture in MEM containing cycloheximide readily attach to laminin-coated polystyrene surfaces. By contrast, added peritubular cells do not attach onto monolayers of Sertoli cells in monoculture or onto Sertoli cells plated on top of peritubular cells and maintained in coculture for periods of up to 48 h in cocultures maintained for 6 days, however, labeled peritbular cells readily adhere to the free surfaces of reaggregated Sertoli cells. Laminin, but not fibronectin, appears on the free surfaces of the reaggregated Sertoli cells atthis time, coinciding with the period of initial mound formation. The addition of antilaminin IgG, but not antifibronectin IgG, blocks the attachment of cycloheximide-treated peritubular cells to laminin-coated plates and also blocks the subsequent migration of peritubular cells required to form a monolayer. Similarly, anti-laminin IgG inhibits the attachment and spreading of labeled peritubular cells seeded on the free surfaces of reaggregated Sertoli cells in mounds generated during the morphogenetic cascade. We interpret the combined data to indicate that the appearance of laminin on the free surfaces of Sertoli cells is required to permit peritubular cells to adhere and subsequently to migrate on Sertoli cell surfaces, resulting in the formation of a tubule-like structure. © 1994 Wiley-Liss, Inc.     

Cooperativity between Sertoli cells and testicular peritubular cells in the production and deposition of extracellular matrix components

We examined the synthesis and deposition of extracellular matrix (ECM) components in cultures of Sertoli cells and testicular peritubular cells maintained alone or in contact with each other. Levels of soluble ECM components produced by populations of isolated Sertoli cells and testicular peritubular cells were determined quantitatively by competitive enzyme-linked immunoabsorbent assays, using antibodies shown to react specifically with Type I collagen, Type IV collagen, laminin, or fibronectin. Peritubular cells in monoculture released into the medium fibronectin (432 to 560 ng/microgram cell DNA per 48 h), Type I collagen (223 to 276 ng/microgram cell DNA per 48 h), and Type IV collagen (350 to 436 ng/microgram cell DNA per 48 h) during the initial six days of culture in serum-free medium. In contrast, Sertoli cells in monoculture released into the medium Type IV collagen (322 to 419 ng/microgram cell DNA per 48 h) but did not form detectable amounts of Type I collagen or fibronectin during the initial six days of culture. Neither cell type produced detectable quantities of soluble laminin. Immunocytochemical localization investigations demonstrated that peritubular cells in monoculture were positive for fibronectin, Type I collagen, and Type IV collagen but negative for laminin. In all monocultures most of the ECM components were intracellular, with scant deposition as extracellular fibrils. Sertoli cells were positive immunocytochemically for Type IV collagen and laminin but negative for fibronectin and Type I collagen. Co-cultures of peritubular cells and Sertoli cells resulted in interactions that quantitatively altered levels of soluble ECM components present in the medium. This was correlated with an increased deposition of ECM components in extracellular fibrils. The data correlated with an increased deposition of ECM components in extracellular fibrils. The data presented here we interpret to indicate that the two cell types in co-culture act cooperatively in the formation and deposition of ECM components. Results are discussed with respect to the nature of interactions between mesenchymal peritubular cell precursors and adjacent epithelial Sertoli cell precursors in the formation of the basal lamina of the seminiferous tubule.     

Protein secretory patterns of rat Sertoli and peritubular cells are influenced by culture conditions

An approach combining two-dimensional gel electrophoresis and autoradiography was used to correlate patterns of secretory proteins in cultures of Sertoli and peritubular cells with those observed in the incubation medium from segments of seminiferous tubules. Sertoli cells in culture and in seminiferous tubules secreted three proteins designated S70 (Mr 72,000-70,000), S45 (Mr 45,000), and S35 (Mr 35,000). Cultured Sertoli and peritubular cells and incubated seminiferous tubules secreted two proteins designated SP1 (Mr 42,000) and SP2 (Mr 50,000). SP1 and S45 have similar Mr but differ from each other in isoelectric point (pI). Cultured peritubular cells secreted a protein designated P40 (Mr 40,000) that was also seen in intact seminiferous tubules but not in seminiferous tubules lacking the peritubular cell wall. However, a large number of high-Mr proteins were observed only in the medium of cultured peritubular cells but not in the incubation medium of intact seminiferous tubules. Culture conditions influence the morphology and patterns of protein secretion of cultured peritubular cells. Peritubular cells that display a flat-stellate shape transition when placed in culture medium free of serum (with or without hormones and growth factors), accumulate various proteins in the medium that are less apparent when these cells are maintained in medium supplemented with serum. Two secretory proteins stimulated by follicle-stimulating hormone (FSH) (designated SCm1 and SCm2) previously found in the medium of cultured Sertoli cells, were also observed in the incubation medium of seminiferous tubular segments stimulated by FSH. Results of this study show that, although cultured Sertoli and peritubular cells synthesize and secrete proteins also observed in segments of incubated seminiferous tubules anther group of proteins lacks seminiferous tubular correlates. Our observations should facilitate efforts to achieve a differentiated functional state of Sertoli and peritubular cells in culture as well as to select secretory proteins for assessing their possible biological role in testicular function.     

Cyclic expression of endothelin-converting enzyme-1 mediates the functional regulation of seminiferous tubule contraction.

The potent smooth muscle agonist endothelin-1 (ET-1) is involved in the local control of seminiferous tubule contractility, which results in the forward propulsion of tubular fluid and spermatozoa, through its action on peritubular myoid cells. ET-1, known to be produced in the seminiferous epithelium by Sertoli cells, is derived from the inactive intermediate big endothelin-1 (big ET-1) through a specific cleavage operated by the endothelin-converting enzyme (ECE), a membrane-bound metalloprotease with ectoenzymatic activity. The data presented suggest that the timing of seminiferous tubule contractility is controlled locally by the cyclic interplay between different cell types. We have studied the expression of ECE by Sertoli cells and used myoid cell cultures and seminiferous tubule explants to monitor the biological activity of the enzymatic reaction product. Northern blot analysis showed that ECE-1 (and not ECE-2) is specifically expressed in Sertoli cells; competitive enzyme immunoassay of ET production showed that Sertoli cell monolayers are capable of cleaving big ET-1, an activity inhibited by the ECE inhibitor phosphoramidon. Microfluorimetric analysis of intracellular calcium mobilization in single cells showed that myoid cells do not respond to big endothelin, nor to Sertoli cell plain medium, but to the medium conditioned by Sertoli cells in the presence of big ET-1, resulting in cell contraction and desensitization to further ET-1 stimulation; in situ hybridization analysis shows regional differences in ECE expression, suggesting that pulsatile production of endothelin by Sertoli cells (at specific "stages" of the seminiferous epithelium) may regulate the cyclicity of tubular contraction; when viewed in a scanning electron microscope, segments of seminiferous tubules containing the specific stages characterized by high expression of ECE were observed to contract in response to big ET-1, whereas stages with low ECE expression remained virtually unaffected. These data indicate that endothelin-mediated spatiotemporal control of rhythmic tubular contractility might be operated by Sertoli cells through the cyclic expression of ECE-1, which is, in turn, dependent upon the timing of spermatogenesis.     

Immunocytochemistry of extracellular matrix in the lamina propria of the rat testis: electron microscopic localization

The distribution of laminin, type IV collagen, heparan sulfate proteoglycan, and fibronectin was investigated in the rat testicular lamina propria by electron microscopic immunocytochemistry. Distinct patterns were observed for each antigen within the extracellular matrix (ECM) layers of the lamina propria. Laminin, type IV collagen, and heparan sulfate proteoglycan all localized to the seminiferous tubule basement membrane. Type IV collagen and heparan sulfate proteoglycan, but not laminin, localized to the seminiferous tubule side of the peritubular myoid cells. All four of the antigens were localized between the peritubular and lymphatic endothelial cells. Failure to localize fibronectin in the ECM layer between the Sertoli and peritubular myoid cells tends to support the concept that adult Sertoli cells do not produce this protein in vivo. Intracellular immunostaining was insufficient to allow unambiguous identification of the cellular source of any of the ECM molecules.     

Localization and synthesis of entactin in seminiferous tubules of the mouse.

Localization and synthesis of entactin in seminiferous tubules of mouse testis was studied by immunocytochemistry. Frozen sections from adult mice testes were subjected to anti-entactin and anti-laminin immunofluorescence. Both entactin and laminin were localized within the seminiferous tubule basement membrane and intertubular region of the testis. The addition of excess amount of entactin (but not fibronectin), premixed with anti-entactin antiserum, abolished the immunostain. Western blotting showed that a protein extract from a seminiferous tubule basement membrane preparation was recognized by anti-entactin anti-serum and comigrated with recombinant entactin. Enriched fractions of isolated primary Sertoli cells and peritubular myoid cells cultured for 6 days on a glass coverslip were able to synthesize and secrete entactin as detected by immunofluorescence microscopy. Entactin was also produced by TM3 (Leydig-like) and TM4 (Sertoli-like) cell lines as detected by both immunofluorescence and Western blotting. The distribution of entactin vs. laminin within both the cultured primary cells and the TM3 and TM4 cell lines differed. Entactin appeared mainly localized extracellularly. In contrast, laminin was mainly localized intracellularly. The above findings suggested that 1) entactin existed in the seminiferous tubule basement membrane and intertubular region of adult mice testis, co-localized with laminin; 2) entactin was synthesized by the cultured primary Sertoli cells and peritubular myoid cells and the TM3 and TM4 cell lines; 3) entactin was exocytosed with little intracellular accumulation, in contrast to an intracellular accumulation of laminin.     

Autoimmune orchitis can be induced by thymic lymphocytes autosensitized against syngeneic sertoli cells in vitro

Thymic lymphocytes from normal inbred Lewis/Wistar rats were cocultured with syngeneic Sertoli cell-peritubular cell preparations in the presence of heterologous or allogeneic serum. Thymic cells cultured in this manner bound to Sertoli cells, became autosensitized , and markedly altered syngeneic Sertoli cell surface properties and remodeling functions in vitro. In contrast, control thymic cells incubated with Sertoli cells in autologous or syngeneic serum did not become sensitized. Coculture of autosensitized thymic cells with syngeneic seminiferous tubule segments, or local transfer of such lymphocytes into syngeneic rat testes, resulted in intratubular infiltration by "light cells." Intratesticular injection of autosensitized thymic cells was followed by derangement of the seminiferous epithelium, and by morphologic changes characteristic of experimental autoimmune orchitis. Thymic cells incubated with Sertoli cells in autologous or syngeneic serum did not elicit these changes. Thymic cells incubated with peritubular cells in heterologous or autologous serum behaved like control thymocytes, and were not sensitized. Data presented indicate that thymic cells are potentially capable of recognizing syngeneic Sertoli cell self-antigens. We speculate that factors normally present in serum may inhibit the recognition by thymic lymphocytes of antigenic determinants present on Sertoli cells. We discuss the possibility that the modulation of interactions between immature thymic lymphocytes and Sertoli cells is implicated in the prevention of autoimmune reactions against the testis.     

Cell-cell interactions in the control of spermatogenesis as studied using Leydig cell destruction and testosterone replacement

This review centers around studies which have used ethane dimethane sulphonate (EDS) selectively to destroy all of the Leydig cells in the adult rat testis. With additional manipulations such as testosterone replacement and/or experimental induction of severe seminiferous tubule damage in EDS-injected rats, the following questions have been addressed: 1) What are the roles and relative importance of testosterone and other non-androgenic Leydig cell products in normal spermatogenesis and testicular function in general? 2) What are the factors controlling Leydig cell proliferation and maturation? 3) Is it the Leydig cells or the seminiferous tubules (or both) which control the testicular vasculature? The findings emphasize that in the normal adult rat testis there is a complex interaction between the Leydig cells, the Sertoli (and/or peritubular) cells, the germ cells, and the vasculature, and that testosterone, but not other Leydig cell products, plays a central role in many of these interactions. The Leydig cells drive spermatogenesis via the secretion of testosterone which acts on the Sertoli and/or peritubular cells to create an environment which enables normal progression of germ cells through stage VII of the spermatogenic cycle. In addition, testosterone is involved in the control of the vasculature, and hence the formation of testicular interstitial fluid, presumably again via effects on the Sertoli and/or peritubular cells. When Leydig cells regenerate and mature after their destruction by EDS, it can be shown that both the rate and the location of regenerating Leydig cells is determined by an interplay between endocrine (LH and perhaps FSH) and paracrine factors; the latter emanate from the seminiferous tubules and are determined by the germ cell complement. Taken together with other data on the paracrine control of Leydig cell testosterone secretion by the seminiferous tubules, these findings demonstrate that the functions of all of the cell types in the testis are interwoven in a highly organized manner. This has considerable implications with regard to the concentration of research effort on in vitro studies of the testis, and is discussed together with the need for a multidisciplinary approach if the complex control of spermatogenesis is ever to be properly understood.     

Regulation of seminiferous tubular function by FSH and androgen.

Seminiferous tubules contain a cytoplasmic androgen receptor similar to the receptors in the epididymis and ventral prostate. The presence of a cytoplasmic receptor indicates that androgens maintain spermatogenesis by a direct action on certain types of cells within the seminiferous tubule. The Sertoli cell appears to be one of the cell types containing androgen receptors and the receptor might also be present in spermatogonia, primary spermatocytes, or peritubular cells. The Sertoli cell is stimulated by FSH to produce an androgen-binding protein which may serve to increase the accumulation of androgen in the seminiferous epithelium and make it available for binding by intracellular androgen receptors. This may be a way in which FSH enhances the action of androgen on spermatogenesis. Androgens act on the Sertoli cell to increase its response to FSH. This action of androgens on the Sertoli cell results in increased production of androgen-binding protein and may enhance the production of other substances which exert trophic effects on spermatogenesis.     

Establishment of a peritubular myoid-like cell line and interactions between established testicular cell lines in culture

Established cell lines and primary cultures derived from somatic cells of the testis have been used to study cell-cell interactions. Primary cultures of Sertoli cells or Sertoli-derived cell lines from the mouse (TM4) and rat (TR-ST) will aggregate when plated on monolayers of primary cultures of peritubular myoid cells or a rat (TR-M) cell line which has many properties of peritubular myoid cells. Time-lapse cinematography and scanning and transmission electron microscopy reveal that Sertoli cells formed aggregates after 1 day in coculture, display surface activity and move on the monolayer. When these aggregates touch one another, they rapidly combine. By the 4th day of culture, spherical aggregates are composed of 50 to 200 cells. They do not display surface activity or movement on the myoid monolayer. On the 5th and 6th day of culture most spherical aggregates have flattened to form dome-shaped aggregates in close association with the monolayer. Cells in the aggregates are characterized by long microvilli and some ruffles. In large aggregates, cells sometimes form close associations within the aggregates although junctions are seldom observed. Sertoli-derived cell lines will not aggregate on monolayers of Leydig-derived (TM3) or testicular endothelial-derived (TR-1) cell lines. Neither TM3 nor TR-1 cells will aggregate when plated on myoid monolayers. The TR-M cells produced an extensive extracellular matrix beneath the cells which contains collagen, an amorphous globular material resembling elastin and a fibrous noncollagenous component. Sertoli cells plated on this matrix will not aggregate. Thus the aggregation of Sertoli cells on myoid cell monolayers is cell type, but not species dependent and not determined solely by extracellular matrix components produced by TR-M cells.     

The lamina propria of the bovine seminiferous tubule

Summary The boundary tissue of bovine testicular seminiferous tubules exhibits remarkable regional differences at the level of the seminiferous tubule proper, as compared with its terminal segment. The basal lamina of the seminiferous tubule proper is multilayered and possesses knob-like protrusions. At the level of the terminal segment the basal lamina is highly specialized; in the region of the terminal plug candelabrum-like projections of the tubular basal lamina invade the bases of the modified supporting cells up to a depth of 3.5 m. The adjoining surface of these supporting cells is densely studded with hemidesmosomes. The elongated peritubular cells are arranged in 3–5 concentric layers around the tubulus seminiferus proper but form a loose association at the level of the terminal segment. Where the terminal segment joins the testicular straight tubule, peritubular cells may assemble to constitute a contractile spiral. Elastic tissue is situated mainly subjacent to the tubular basal lamina and to a lesser degree between the peritubular cell layers. A peritubular space lined by endothelium-like cells may surround the seminiferous tubule proper and also the transitional zone of the terminal segment.Supported by a grant from the Deutsche Forschungsgemeinschaft     

Evaluation of cholesteryl ester transfer in the seminiferous tubule cells of immature rats in vivo and in vitro

Sertoli cells and germ cells are separated from the interstitial blood capillaries by an extracellular matrix and the peritubular cells, which constitute a barrier to the movement of plasma lipoproteins. The present study was undertaken to evaluate in vivo and in vitro the high density lipoprotein (HDL) cholesteryl ester transfer from plasma to seminiferous tubule cells in the testis of 30-day-old rats. Firstly, the transfer of HDL cholesteryl oleate from plasma to testicular compartments was evaluated and, secondly, the role of apolipoproteins A-I and E in the uptake of cholesteryl ester by Sertoli cells was investigated. At 2 h after the administration of HDL reconstituted with [3H]cholesteryl ester, dimyristoyl phosphatidylcholine and apolipoproteins, the tissue space in the interstitial cells (740 +/- 60 microliters g-1 cell protein) was fourfold higher than that in the seminiferous tubule cells (170 +/- 10 microliters g-1). Sertoli cells were isolated and incubated with [3H]cholesteryl ester HDL reconstituted with apolipoprotein A-I or E to evaluate the mechanisms of cholesteryl ester influx. At the same apolipoprotein concentration (50 micrograms apolipoprotein ml-1 medium), the uptake of [3H]cholesteryl oleate from phospholipid-apolipoprotein E vesicles was twofold higher than that with phospholipid-apolipoprotein A-I vesicles. The presence of heparin reduced the uptake of cholesteryl ester from apolipoprotein E vesicles but not with apolipoprotein A-I vesicles, indicating that uptake of apolipoprotein A-I vesicles via a secretion of apolipoprotein E by the cells themselves was not involved. These results demonstrate that plasma lipoprotein cholesterol is able to cross the testis lamina propria and that Sertoli cells take up cholesteryl ester for seminiferous tubule cell metabolism mainly via an apolipoprotein E pathway.