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.     

Rat Sertoli cell aromatase cytochrome P450: Regulation by cell culture conditions and relationship to the state of cell differentiation

Summary Primary cultures of immature rat Sertoli cells in plastic dishes are highly responsive to follicle stimulating hormone (FSH) and its second messenger, cAMP, in metabolizing testosterone to estradiol, thus indicating the presence of an active, hormone-regulated aromatase cytochrome P450 (P450arom). However, in vivo studies indicated that P450arom is FSH-responsive only in very young animals, where the cells have not yet differentiated, but they lose this ability later on in development. Sertoli cells grown on Matrigel (a reconstituted basement membrane), laminin (a basement membrane component), or in bicameral chambers coated with Matrigel, assume structural and functional characteristics more similar to that of in vivo differentiated Sertoli cells. When the cells were cultured on laminin or Matrigel, the FSH- and cAMP-induced estradiol production was greatly reduced by 30 and 60%, respectively. When Sertoli cells were cultured in bicameral chambers coated with Matrigel, no induction of testosterone aromatization by FSH or cAMP was observed. However, FSH-induced cAMP formation was greater when the cells were cultured on basement membrane or in the chambers than on plastic dishes. These results suggest that culture conditions favoring the assumption by Sertoli cells of a phenotype closer that of the differentiated cells in vivo (tall columnar and highly polarized) suppress the induction of P450arom by FSH and cAMP. We then examined the mechanism(s) by which cell phenotype affects p450arom activity. Northern blot analyses of Sertoli cell RNA revealed one major band of 1.9 Kb and two minor bands of 3.3 and 5.2 Kb. However, there were no changes at the level of the expression of P450arom messenger RNA under the different culture conditions. No differences were found in P450arom enzymatic activity measured by the³H₂O release method in microsomes prepared from Sertoli cells cultured under the various conditions. Similarly, no differences were observed in the amount of protein detected by immunoblot analysis of Sertoli cell extracts using an antiserum raised against the human placental enzyme. Recombination experiments using microsomes from cells cultured on plastic or in the chambers and cytosol from control or FSH-treated cells cultured on plastic also proved inadequate in inducing P450arom activity. These data suggest that: a) P450arom activity could be used as a specific marker for Sertoli cell differentiation, and b) the differentiation process in Sertoli cells is associated with specific changes in the microenvironment or the regulation of P450arom, or both, that rendered the enzyme insensitive to FSH or cAMP induction.     

Sertoli cell proliferation in the adult testis--evidence from two fish species belonging to different orders

Germ cell survival and development critically depend on the cells' contact with Sertoli cells in the vertebrate testis. Fish and amphibians are different from mammals in that they show a cystic type of spermatogenesis in which a single germ cell clone is enclosed by and accompanied through the different stages of spermatogenesis by an accompanying group of Sertoli cells. We show that in maturing and adult testes from African catfish and Nile tilapia, Sertoli cell proliferation occurs primarily during spermatogonial proliferation, allowing the cyst-forming Sertoli cells to provide the increasing space required by the growing germ cell clone. In this regard, coincident with a dramatic increase in cyst volume and number of germ cells per cyst, in Nile tilapia, the number of Sertoli cells per cyst was strikingly increased from primary spermatogonia to spermatocyte cysts. In both African catfish and Nile tilapia, Sertoli cell proliferation is strongly reduced when germ cells have proceeded into meiosis, and stops in postmeiotic cysts. We conclude that Sertoli cell proliferation is the primary factor responsible for the increase in testis size and sperm production observed in teleost fish. In mammals, Sertoli cell proliferation in the adult testis is not observed under natural conditions. However, on the level of the individual spermatogenic cyst--similar to mammals--Sertoli cell proliferation ceases when germ cells have entered meiosis and when tight junctions are established between Sertoli cells. This suggests that fish are valid vertebrate models for studying Sertoli cell physiology.     

Role of Sertoli cell number and function on regulation of spermatogenesis

Testicular function is under the control of expression and repression of several genes and gene products, and many of these works through Sertoli cells. The capability of Sertoli cells to regulate spermatogenesis is dependent on Sertoli cell functions and Sertoli cell number. Sertoli cell number has long been thought to be stable in adults with no proliferation of Sertoli cells once adult numbers have been reached. However, adult horses do not have stable Sertoli cell numbers, and new studies indicate that adult Sertoli cells can be made to re-enter mitotic phase under certain experimental conditions. This review discusses roles of Sertoli cells in regulation of spermatogenesis and methods for estimating the number of Sertoli cells, in a testis, that overcome the problems (assumptions) associated with the indented, pear-shaped of Sertoli cell nuclei which make it difficult to estimate the volume of individual nuclei. Using several approaches to overcome the problems associated with any one method, the horse is identified as a species in which Sertoli cell number is not fixed, but it fluctuates with season. In addition to Sertoli cell numbers, the functions of Sertoli cells that are very important in signaling and controlling spermatogenesis are discussed. Recent studies have shown that "post-mitotic terminally differentiated Sertoli cells" from adult animals could, under certain conditions, re-enter the cell division cycle. Can seasonal influences be a natural set of conditions to induce the Sertoli cells of the horse testis to seasonally re-enter the cell division cycle and explain the seasonal differences in Sertoli cell number as summarized in this review? Alternatively, can seasonal differences in Sertoli cell number reflect, in the horse to a greater extent, but in adults of most species, the presence of some mitotic-capable Sertoli cells in adults? In any case, both Sertoli cell number and function are important in regulation of spermatogenesis.     

Isolation of sertoli cells from adult rat testes: an approach to ex vivo studies of Sertoli cell function

Much of what is known about the molecular regulation and function of adult Sertoli cells has been inferred from in vitro studies of immature Sertoli cells. However, adult and immature cells differ in significant ways and, moreover, many Sertoli cell functions are regulated by conditions that are difficult to replicate in vitro. Our objective was to develop a procedure to isolate Sertoli cells rapidly and in sufficient number and purity to make it possible to assess Sertoli cell function immediately after the isolation of the cells. The isolation procedure described herein takes less than 4 h and does not require culturing the cells. From a single 4-mo-old adult rat, we routinely obtain 7.0 +/- 0.4 x 10(6) Sertoli cells per testis, and from a 21-mo-old rat, 7.2 +/- 0.4 x 10(6) Sertoli cells per testis. The purity, determined by morphologic analyses of plastic-embedded cells or after staining for tyrosine-tubulin or vimentin, averaged 80%. The contaminants typically included germ cells (10%) and myoid cells (10%). The germ cell-expressed genes protamine-2 and hemiferrin were not detected in the Sertoli cell preparations by Northern blot analyses, but the Sertoli cell-expressed genes clusterin, cathepsin L, and transferrin were highly expressed. Transferrin mRNA levels were greater in Sertoli cells isolated from aged than from young adult rats, consistent with previous analyses of whole testes; and cathepsin L mRNA levels were far more highly expressed in Sertoli cells isolated from stages VI-VII than from other stages of the cycle of the seminiferous epithelium, also consistent with previous analyses of whole testes and isolated tubules. These studies indicate that the freshly isolated cells retain differentiated function, and thus it should be possible to assess the in vivo function of adult Sertoli cells by isolating the Sertoli cells and immediately assessing their function.     

Specificity and partial purification of a factor in spent media from Sertoli cell-enriched cultures that stimulates steroidogenesis in Leydig cells

There is increasing evidence that factors derived from the seminiferous tubules influence Leydig cell function in a paracrine way. In previous experiments we demonstrated that conditioned media from Sertoli cell-enriched cultures contain a protein with stimulatory activity on prepubertal rat Leydig cells. In this paper we further studied the specificity of this factor. In addition we describe a simple but efficient partial purification procedure. It is demonstrated that Sertoli cell conditioned media contain a factor that stimulates the testosterone output from prepubertal and adult Leydig cells. The effects are evident within the first hour of incubation and can be observed in the presence as well as in the absence of LH. Peritubular cells do not produce a similar factor but enhance the production of the Leydig cell stimulating factor when cocultured with Sertoli cells. The Sertoli cell factor acts on rat as well as on mouse Leydig cells. It barely influences the adrenostenedione output of ovarian stromal cells or the corticosterone output of adrenal cells. The production of this factor is enhanced by dbcAMP, FSH, L-isoproterenol and glucagon but is not affected by androgens. The characteristics of the Sertoli cell factor have been compared with those of a Leydig cell stimulating factor in the medium from an established rabbit kidney cell line: RK13. It is shown that the active principle in RK13 conditioned medium is also a thermolabile trypsin-sensitive protein with a mol. wt of more than 10,000. Nonetheless, the RK13 and Sertoli cell derived factors act by different mechanisms since at maximally effective concentrations their effects are additive. Finally it is demonstrated that molecular weight fractionation of Sertoli cell conditioned medium using an Amicon ultrafiltration system results in a 50- to 130-fold increase in Sertoli cell factor activity in a fraction corresponding to a mol. wt of 10,000 up to 30,000.     

The helix-loop-helix inhibitor of differentiation (ID) proteins induce post-mitotic terminally differentiated Sertoli cells to re-enter the cell cycle and proliferate

Prior to puberty the Sertoli cells undergo active cell proliferation, and at the onset of puberty they become a terminally differentiated postmitotic cell population that support spermatogenesis. The molecular mechanisms involved in the postmitotic block of pubertal and adult Sertoli cells are unknown. The four known helix-loop-helix ID proteins (i.e., Id1, Id2, Id3, and Id4) are considered dominant negative regulators of cellular differentiation pathways and act as positive regulators of cellular proliferation. ID proteins are expressed at low levels by postpubertal Sertoli cells and are transiently induced by serum. The hypothesis tested was that ID proteins can induce a terminally differentiated postmitotic Sertoli cell to reenter the cell cycle if they are constitutively expressed. To test this hypothesis, ID1 and ID2 were stably integrated and individually overexpressed in postmitotic rat Sertoli cells. Overexpression of ID1 or ID2 allowed postmitotic Sertoli cells to reenter the cell cycle and undergo mitosis. The cells continued to proliferate even after 300 cell doublings. The functional markers of Sertoli cell differentiation such as transferrin, inhibin alpha, Sert1, and androgen binding protein (ABP) continued to be expressed by the proliferating Sertoli cells, but at lower levels. FSH receptor expression was lost in the proliferating Sertoli cell-Id lines. Some Sertoli cell genes, such as cyclic protein 2 (cathepsin L) and Sry-related HMG box protein-11 (Sox11) increase in expression. At no stage of proliferation did the cells exhibit senescence. The expression profile as determined with a microarray protocol of the Sertoli cell-Id lines suggested an overall increase in cell cycle genes and a decrease in growth inhibitory genes. These results demonstrate that overexpression of ID1 and ID2 genes in a postmitotic, terminally differentiated cell type have the capacity to induce reentry into the cell cycle. The observations are discussed in regards to potential future applications in model systems of terminally differentiated cell types such as neurons or myocytes.     

The response of adult rat sertoli cells,immortalized by a temperature-sensitive mutant of SV40, to 1,2-dinitrobenzene, 1,3-dinitrobenzene, 2,4-dinitrotoluene, 3,4-dinitrotoluene,and cadmium

In this study we test the hypothesis that immortalized adult rat Sertoli cells respond to known testicular toxins in a similar manner to Sertoli cells tested in vivo and in primary culture. This cell line was developed by immortalizing adult rat Sertoli cells with the temperature-sensitive mutant of SV40, ts255, such that the cells proliferate at the permissive temperature of 33 degrees C but express differentiated characteristics at the nonpermissive temperature of 40 degrees C. Confluent monolayers, grown at 33 degrees C or 40 degrees C, were exposed to a range of concentrations of dinitrobenzene (DNB) or dinitrotoluene (DNT) isomers or to cadmium chloride. Cellular response was assessed by neutral-red cell viability assay and ultrastructural changes. Cells grown at 40 degrees C were sensitive to lower concentrations of each toxicant than were cells grown at 33 degrees C. 1,2-DNB was more toxic than 1,3-DNB, and 3,4-DNT was more toxic than 2,4-DNT, as judged by the neutral-red cell viability assay. Ultrastructurally, cells treated with 1,2-DNB or 2,4-DNT showed increased numbers of autophagic vesicles compared to controls. Intercellular penetration of ruthenium red demonstrated breached tight junctions in 1,2-DNB and cadmium-treated cells. From these observations, we conclude that this cell line can serve as a model for studying toxic mechanisms in adult Sertoli cells.     

Germ cell binding to rat Sertoli cells in vitro

The interaction between male germ cells and Sertoli cells was studied in vitro by co-incubation experiments using isolated rat germ cells and primary cultures of Sertoli cells made germ cell-free by the differential sensitivity of germ cells to hypotonic shock. The germ cell/Sertoli cell interaction was examined morphologically with phase-contrast and scanning electron microscopy and then quantified by measuring radioactivity bound to Sertoli cell cultures after co-incubation with added [3H]leucine-labeled germ cells. Germ cell binding to Sertoli cell cultures was the result of specific adhesion between these two cell types, and several features of this specific adhesion were observed. First, germ cells adhered to Sertoli cell cultures under conditions during which spleen cells and red blood cells did not. Second, germ cells had a greater affinity for Sertoli cell cultures than they had for cultures of testicular peritubular cells or cerebellar astrocytes. Third, germ cells fixed with paraformaldehyde adhered to live Sertoli cultures while similarly fixed spleen cells adhered less tightly. Neither live nor paraformaldehyde-fixed germ cells adhered to fixed Sertoli cell cultures. Fourth, germ cell binding to Sertoli cell cultures was not immediate but increased steadily and approached a maximum at 4 h of co-incubation. Saturation of germ cell binding to Sertoli cell cultures occurred when more than 4200 germ cells were added per mm2 of Sertoli cell culture surface. Finally, germ cell binding to Sertoli cell cultures was eliminated when co-incubation was performed on ice. Based on these observations, we concluded that germ cell adhesion to Sertoli cells was specific, temperature-dependent, and required a viable Sertoli cell but not necessarily a viable germ cell. These results have important implications for understanding the complex interaction between Sertoli cells and germ cells within the seminiferous tubule and in the design of future experiments probing details of this interaction.     

Extracellular matrix regulates Sertoli cell differentiation, testicular cord formation, and germ cell development in vitro

Sertoli cell preparations isolated from 10-day-old rats were cultured on three different substrates: plastic, a matrix deposited by co-culture of Sertoli and peritubular myoid cells, and a reconstituted basement membrane gel from the EHS tumor. When grown on plastic, Sertoli cells formed a squamous monolayer that did not retain contaminating germ cells. Grown on the matrix deposited by Sertoli-myoid cell co-cultures, Sertoli cells were more cuboidal and supported some germ cells but did not allow them to differentiate. After 3 wk however, the Sertoli cells flattened to resemble those grown on plastic. In contrast, the Sertoli cells grown on top of the reconstituted basement membrane formed polarized monolayers virtually identical to Sertoli cells in vivo. They were columnar with an elaborate cytoskeleton. In addition, they had characteristic basally located tight junctions and maintained germ cells for at least 5 wk in the basal aspect of the monolayer. However, germ cells did not differentiate. Total protein, androgen binding protein, transferrin, and type I collagen secretion were markedly greater when Sertoli cells were grown on the extracellular matrices than when they were grown on plastic. When Sertoli cells were cultured within rather than on top of reconstituted basement membrane gels they reorganized into cords. After one week, tight junctional complexes formed between adjacent Sertoli cells, functionally compartmentalizing the cords into central (adluminal) and peripheral (basal) compartments. Germ cells within the cords continued to differentiate. Thus, Sertoli cells cultured on top of extracellular matrix components assume a phenotype and morphology more characteristic of the in vivo, differentiated cells. Growing Sertoli cells within reconstituted basement membrane gels induces a morphogenesis of the cells into cords, which closely resemble the organ from which the cells were dissociated and which provide an environment permissive for germ cell differentiation.     

Selective loss of Sertoli cell and germ cell function leads to a disruption in sertoli cell-germ cell communication during aging in the Brown Norway rat

We investigated the effects of aging on Sertoli cell-germ cell interactions from Brown Norway rats using the induction of four specific mRNAs as markers. The testes from aging (24 mo old) Brown Norway rats can be normal size or regressed. One marker, a von Ebner's-like protein, is expressed in coculture and "in vivo" in germ cells from normal testes of 6- and 24-mo-old rats but not in germ cells from regressed testes of 24-mo-old rats. A second germ cell marker, the Huntington disease protein, is expressed in all germ cells. Two Sertoli cell markers, a serotonin receptor and a novel gene, are induced in Sertoli cells by meiotic germ cells. The serotonin receptor mRNA is expressed in Sertoli cells from 20-day, 6-mo, and 24-mo normal testes but not in those from 24-mo regressed testes. The novel gene is induced in Sertoli cells from all testes. We conclude that Sertoli cells from aged regressed testes are unable to respond to selective signals from germ cells from young rats, and germ cells from regressed testes show a similar selective loss. Such disruptions in communication between Sertoli cells and germ cells likely contribute to germ cell loss during aging.     

Effect of hypotonic treatment on sertoli cell purity and function in culture

Summary Commonly used enzymic methods for the isolation of rat Seroli cells yield populations containing ∼15% germ cells. Although the germ cells become eliminated after several media changes, they could interferen with the use of Sertoli cells for critical studies during the first several days of culture. A brief treatment of Sertoli cell monolayer cultures with 20 mM Tris-HCl (pH 7.4) was found to eliminate most of the residual contaiminating germ cells. The duration of this treatment varied from 1.0 to 10 min, depending on cell denisty in the culture, the degree of germ cell contamination, and the age of animals used for Sertoli cell isolation. In a study of 95% pure 7-d Sertoli cell cultures, the hypotonic treatment did not alter the DNA or RNA content per dish or the incorporation of [³H]uridine into total and poly A+RNA. Also, the hypotonic treatment did not alter specific Sertoli cell functions, i. e., secretion of Sertoli cell factor (inhibin) and stimulation of cAMP levels by follicle stimuting hormone in 2-d cultures. Androgen receptor concentration per dish was also not changed. Changes in several general metabolic parameters observed after hypotonic treatment of 2-d cultures were attributed primarily to loss of contaiminating germ cells. Consequently, hypotonic treatment can be used to eliminate contaminating germ cells from the Sertoli cell cultures without apparent detrimental effects on a number of Sertoli cell biochemical parameters. This may be of considerable importance when the purity of Sertoli cells is critical for the interpretation of experimental data. This work was supported in part by grants HD-1-P50-08338, HD-17795 (BMS), and HD-18186 (JJH) from the National Institutes of Health, Bethesda, MD.     

Acid phosphatases in germinal and somatic cells of the testes

Four forms of acid phosphatase have been found in the testicular tissue of many mammalian species, but their exact cellular site has remained obscure. In this work, acid phosphatases have been studied in different reproductive organs of the male rat, in somatic cell lines derived by cloning from both rat and mouse testes, in primary cultures of rat Sertoli cells, and in isolated spermatogenic cells of the mouse. Among the reproductive organs, preputial glands show the highest specific activities with p-nitrophenyl phosphate as substrate, followed by the testicular tissue and the different regions of the epididymis. By contrast to that in other tissues, testicular activity with p-nitrophenyl phosphate is not influenced by tartrate and is activated markedly by cobalt (Co2+). Among the somatic cell lines, the highest hydrolysis rates are obtained with naphthyl substrates in the epithelial (TR-1) and myoid (TR-M) cell lines and marginally lower rates in the Leydig (TM3) and Sertoli (TM4) cell lines. With thymolphthalein phosphate, the latter two cell lines show very low activity. These activities are not influenced by different hormones and growth factors in the culture medium. The most marked Co2+-activated reaction with p-nitrophenyl phosphate is found in advanced stages of germinal cells and residual bodies. Primary cultures of Sertoli cells, prepared from rats 10 to 30 days of age, show a slight decrease in acid phosphatase levels; however, the activities are not influenced markedly by addition of follicle-stimulating hormone (FSH) and/or testosterone to the culture medium.(ABSTRACT TRUNCATED AT 250 WORDS)     

Testins are structurally related Sertoli cell proteins whose secretion is tightly coupled to the presence of germ cells

Previous studies from this laboratory have shown that Sertoli cell-enriched culture medium contained two immunologically and structurally related proteins designated CMB-22 and CMB-23 with Mr of 37,000 and 40,000, respectively. We have now demonstrated that both CMB-22 and CMB-23 are monomeric proteins with the following NH2-terminal amino acid sequences: CMB-22, NH2-TPDPSLDVEWNEWRTKHGKTYNMNEERLKR; CMB-23, NH2-XAPXPDPSLDVEXNEXRTK. These sequences are virtually identical except that CMB-23 has three extra NH2 terminus amino acids of X-A-P. Comparison of these sequences with those in the Protein Identification Resource revealed that they are unique proteins. CMB-22 and CMB-23 are highly concentrated in testes and their levels in this tissue increase with age. Studies using [35S]methionine incorporation and immunoprecipitation demonstrated that Sertoli cells synthesize and secrete these proteins in vitro. Because they seem not to have been isolated previously, are concentrated in and synthesized by the testes, and are structurally related, we propose that CMB-22 and CMB-23 be designated testin I and testin II, respectively. The distribution of these proteins in biological fluids were compared with those of testibumin and rat androgen binding protein (rABP), two other Sertoli cell proteins. The results suggest that testins, unlike testibumin and rABP, are not transported to the epididymis. Although the amount of testins secreted by Sertoli cells in vitro is similar to that of testibumin and rABP, the concentrations in testis and rete testis fluid are several orders of magnitude less than that of testibumin and rABP. These observations suggest that the secretion of these proteins in vivo might be suppressed by germ cells. The fact that 10 times more testins are secreted by tubules from immature rats than by those from adult rats and that there is an increase in the testicular content of testins following a single dose of busulfan, which depleted the germ cells from the seminiferous epithelium, supports this hypothesis. Thus, the secretion of testins by Sertoli cells appears to be tightly coupled to the presence of germ cells; there is an inverse relationship between the amount of testins in the testis and the number of germ cells. These results suggest that testins are unique testicular proteins that can be used to study Sertoli cell-germ cell interactions in the seminiferous epithelium.     

In vivo analysis of phagocytosis of apoptotic cells by testicular Sertoli cells

Sertoli cells, a somatic cell type present within the seminiferous tubules of testes, are responsible for the phagocytic elimination of apoptotic spermatogenic cells. We here established an in vivo assay system that enables us to quantitatively analyze Sertoli cell phagocytosis of apoptotic cells in testes of live mice. Apoptotic cells were injected into the seminiferous tubules of spermatogenic cell-depleted mice, and the occurrence of phagocytosis by Sertoli cells was examined by histochemically analyzing testis sections or dispersed testicular cells. We reproducibly observed similar levels of phagocytosis in either examination, and the ratio of Sertoli cells that engulfed injected apoptotic cells was almost the same between the two examinations. These results indicated that a quantitative in vivo assay system was established using the seminiferous tubules of live mice as 'test tubes.' We then determined the requirements for Sertoli cell phagocytosis of apoptotic cells using this assay. For this purpose, apoptotic cells were injected together with various phagocytosis inhibitors, and the extent of phagocytosis by Sertoli cells was determined. The results revealed that Sertoli cells phagocytose apoptotic cells in a manner dependent on class B scavenger receptor type I (SR-BI) of Sertoli cells and phosphatidylserine exposed at the surface of target cells, as previously observed in vitro using primary cultures of dispersed rat testicular cells. Furthermore, the amount of SR-BI in Sertoli cells increased after injection of apoptotic cells into the seminiferous tubules, suggesting a positive feedback regulation of the expression of this phagocytosis receptor.     

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.     

Gap junctions with varied permeability properties establish cell-type specific communication pathways in the rat seminiferous epithelium

Dye coupling experiments were performed to determine whether the gap junctions connecting Sertoli cells with other Sertoli cells and different germ cell stages in rats showed functional variations. Chop loading of adult rat seminiferous tubules was conducted using fluorescent dextran controls and a variety of low-molecular-weight tracers (lucifer yellow, biotin-X-cadaverine, biotin cadaverine, and neurobiotin) to evaluate dye coupling in situ, and scrape loading was used to study dye coupling in Sertoli-germ cell cocultures established using prepuberal rats. Sertoli-Sertoli coupling is relatively short range and nonselective in situ, whereas coupling between Sertoli cells and chains of spermatogonia is strongly selective for the positively charged biotin tracers relative to negatively charged lucifer yellow. Coupling between Sertoli cells and spermatogonia was also asymmetric; lucifer yellow in germ cells never diffused into Sertoli cells, and biotinylated tracers only weakly diffused from spermatogonia to Sertoli cells. Asymmetric coupling would facilitate the concentration in germ cells of molecules diffusing through junctions from Sertoli cells. Dye coupling between Sertoli cells and adluminal germ cells was too weak to detect by fluorescence microscopy, suggesting that the junctional communication between these cells may be functionally different from that between Sertoli and basal germ cells. The results show that there are multiple routes of gap junction communication in rat seminiferous tubules that differ in permeability properties and show alternative gating states. Functional diversity of gap junctions may permit regulated communication among the many interacting Sertoli cells and germ cell stages in the seminiferous epithelium.