Age-dependent Sertoli cell responsiveness to germ cells in vitro

This study investigated the effect of germ cells (greater than 80% mid- and late-pachytene spermatocytes) on the secretion of androgen binding protein (ABP) and transferrin by monolayer cultures of Sertoli cells isolated from rats aged 10, 18 or 26 days. There was an age-dependent increase in secretion of ABP and transferrin. Treatment of the Sertoli cell monolayers with hypotonic buffer to remove residual germ cells reduced this increase significantly. On the other hand, addition of germ cells to hypotonic-treated Sertoli cell monolayers increased both basal and FSH + testosterone-stimulated ABP and transferrin secretion at all three ages, although Sertoli cells from 10-day-old animals showed the greatest response. Moreover, addition of germ cells reduced responsiveness to FSH + testosterone in Sertoli cell monolayers obtained from rats aged 18 or 26 days. In monolayers obtained from 10-day-old rats, the opposite effect was noted in the case of ABP secretion. The stimulatory effect of germ cells on ABP and transferrin secretion was proportional to their number, and was reversed 48 h after the germ cells added previously were removed by hypotonic treatment. Whereas the reversal was complete with cultures of Sertoli cells isolated from 18- and 26-day-old rats, approximately 40% of the stimulatory effect remained after removal of germ cells from cultures from the 10-day-old age group. Adhesion of germ cells to Sertoli cell monolayers was also found to be age-dependent, with the largest proportion of added germ cells adhering to Sertoli cells isolated at 18 and 26 days of age. It is concluded that germ cells can significantly and differentially modulate the basal and hormone-stimulated secretory activity of Sertoli cells in vitro and that Sertoli cell responsiveness to germ cells (pachytene spermatocytes) is age-dependent and seems to appear early during the maturation process, before these germ cells appear in the testis.     

Effect of germ cells on vectorial secretion of androgen binding protein and transferrin by immature rat Sertoli cells in vitro

The influence of germ cells (greater than 85% pachytene spermatocytes) on vectorial secretion of androgen binding protein (ABP) and transferrin by immature rat Sertoli cells was investigated using two-compartment culture chambers. The ratio of ABP secreted into the outer and inner compartment in control cultures of Sertoli cells alone was 1.9, and was not influenced by either FSH or testosterone. Co-culture of Sertoli cells in direct contact with germ cells in the presence of FSH decreased this ratio, the decrease being most pronounced (0.7) after 2 days of co-culture. This effect was not observed if the germ cells were not in direct contact with Sertoli cell monolayers. The outer to inner compartment ratio of transferrin in Sertoli cell-alone cultures was 1.6 and, in contrast to ABP, was not significantly influenced by the addition of germ cells, even in the presence of FSH. It is concluded that in immature rat Sertoli cells the polarity of ABP secretion, but not that of transferrin, may be regulated by pachytene spermatocytes (and possibly other germ cells), and that this process is FSH-dependent.     

Inhibition of RNA and DNA synthesis in Sertoli cells by co-culture with spermatogenic cells

Sertoli cell monolayers were prepared from 30-day-old rat testes and cultured for 7 days to eliminate contaminant germ cells. Some of these monolayers were co-cultured with a spermatogenic cell preparation enriched in pachytene spermatocytes and round spermatids (fraction 3 from a Percoll gradient), isolated from 30-day-old rat testes. After co-culture for 4 to 48 h, germ cells were removed. RNA synthetic activity in rat Sertoli cell cultures alone was 216,800 +/- 66,480 dpm [3H]uridine.2h-1 X 10(6) cells-1 (mean +/- SD) compared to 98,390 +/- 23,595 in rat Sertoli cells which had been co-cultured with germ cells of fraction 3 for 24 h (P less than 0.01). By contrast, RNA synthesis in Sertoli cell monolayers prepared from immature pigs were unaffected by co-culture with rat germ cells. A similar inhibitory effect of germ cells was observed in rat Sertoli cells stimulated with FSH or testosterone. Culture medium, conditioned by 20 h culture of a fresh preparation of rat spermatogenic cells of fraction 3, was active in inducing the inhibitory effect on RNA synthesis in rat Sertoli cells. Co-culture of rat Sertoli cells with germ cells of this fraction also decreased the incorporative of [3H]thymidine into DNA in rat Sertoli cells, from 9061 +/- 3339 to 4766 +/- 526 dpm.2h-1 X 10(6) cells-1 (P less than 0.01), but no such change was found in pig Sertoli cells. A different spermatogenic cell preparation, partially deprived of pachytene spermatocytes (fraction 5), stimulated rat Sertoli cell DNA synthesis (Sertoli alone 7833 +/- 2550, Sertoli cells which had been in co-culture with germ cells of fraction 5, 13,300 +/- 2279 dpm.2h-1 X 10(6) cells-1, P less than 0.05). These inhibitory actions of some germ cells on Sertoli cells were observed together with the previously reported simultaneous stimulatory effect of Sertoli cells on germ cells. These Sertoli cell-germ cell interactions of detected in culture may represent regulatory influences operating in vivo.     

Influence of age, hormones and germ cells on glutathione S-transferase activity in cultured Sertoli cells

Glutathione S-transferase (GSH-S-T) activity was measured, using 1-Cl-2,4-dinitrobenzene as substrate, in Sertoli cell cultures obtained from rats aged 10, 18, and 26 days. The GSH-S-T activity showed a significant increase with age of the Sertoli cell donor. When cultures were treated with hypotonic solution, in order to eliminate residual contaminating germ cells, the age dependent increase in enzyme activity was less pronounced. FSH, but not testosterone, increased enzyme activity in all cultures. Addition of freshly isolated germ cells (mainly pachytene spermatocytes) to hypotonic-treated Sertoli cell monolayers enhanced GSH-S-T activity at all ages. It is concluded that GSH-S-T activity can be measured in cultured Sertoli cells during the period of onset of spermatogenesis (10-26 days). This enzyme activity is dependent on age of the Sertoli cell donor and is influenced by FSH and germ cells. Since GSH-S-Ts are actively engaged in cell detoxificative functions through conjugation of xenobiotics with glutathione, the present findings suggest that this enzyme may have a relevant protective role during the critical period when spermatogenesis is being established.     

Evidence suggesting that germ cells influence the bidirectional secretion of androgen binding protein by the seminiferous epithelium demonstrated by selective impairment of spermatogenesis with busulphan

Androgen binding protein (ABP) was measured in the serum, testes and epididymides of adult rats up to 105 days after the induction of reversible impairment of spermatogenesis by a single injection of busulphan. This treatment decreased testicular and epididymal weights within 7-21 days after treatment, reaching a minimum at 63 days with partial recovery by 105 days. The testicular and epididymal content of sperm was unchanged up to 42 days after busulphan administration, was reduced considerably at 63 days and thereafter increased towards control values. The serum and testicular concentrations of testosterone were normal at all times after treatment, even though serum LH levels were increased at 42 and 63 days. Serum levels of FSH were also increased at 43 and 63 days after treatment. A biphasic pattern in the serum levels of ABP was observed. Concentrations were low up to 43 days post treatment when only the early germ cell types were depleted from the seminiferous epithelium and when the testicular and epididymal contents of ABP were normal. Serum levels of ABP increased as the more mature germ cells were depleted in numbers and the testicular and epididymal contents of ABP declined. It is concluded that bidirectional secretion of ABP into the interstitium (serum) and into the seminiferous tubular lumen by Sertoli cells is influenced considerably by the population of germ cells that are present in the seminiferous epithelium.     

Thyroid hormones: their role in testicular steroidogenesis

Thyroid hormones are important for growth and development of many tissues. Altered thyroid hormone status causes testicular abnormalities. For instance, juvenile hypothyroidism/neonatal transient hypothyroidism induces macroorchidism, increases testicular cell number (Sertoli, Leydig, and germ cells) and daily sperm production. Triiodothyronine (T3) receptors have been identified in sperm, developing germ cells, Sertoli, Leydig, and peritubular cells. T3 stimulates Sertoli cell lactate secretion as well as mRNA expression of inhibin-alpha, androgen receptor, IGF-I, and IGFBP-4. It also inhibits Sertoli cell mRNA expression of Müllerian inhibiting substance (MIS), aromatase, estradiol receptor, and androgen binding protein (ABP) and ABP secretion. T3 directly increases Leydig cell LH receptor numbers and mRNA levels of steroidogenic enzymes and steroidogenic acute regulatory protein. It stimulates basal and LH-induced secretion of progesterone, testosterone, and estradiol by Leydig cells. Steroidogenic factor-1 acts as a mediator for T3-induced Leydig cell steroidogenesis. Although the role of T3 on sperm, germ, and peritubular cells has not yet been completely studied, it is clear that T3 directly regulates Sertoli and Leydig cell functions. Further studies are required to elucidate the direct effect of T3 on sperm, germ, and peritubular cells.     

Regulatory influence of germ cells on sertoli cell function in the pre-pubertal rat after acute irradiation of the testis

While germ cell regulation of Sertoli cells has been extensively explored in adult rats in vivo, in contrast, very little is known about germ cell influence on Sertoli cell function at the time when spermatogenesis begins and develops. In the present study various Sertoli cell parameters (number, testicular androgen binding protein (ABP) and testin, serum inhibin-B and, indirectly, follicle-stimulating hormone (FSH)) were investigated after the exposure of 19-day-old rats to a low dose of 3 Grays of gamma-rays. Differentiated spermatogonia were the primary testicular targets of the gamma-rays, which resulted in progressive maturation depletion, sequentially and reversibly affecting all germ cell classes. Testicular weight declined to a nadir when pachytene spermatocytes and spermatids were depleted from the seminiferous epithelium and complete or near complete recovery of spermatogenesis and testicular weight was observed at the end of the experiment. Blood levels of FSH and ABP were normal during the first 11 days after irradiation, when spermatogonia and early spermatocytes were depleted. While the number of Sertoli cells was not significantly affected by the irradiation, from days 11-66 after gamma-irradiation, ABP production declined and FSH levels increased when pachytene spermatocytes and spermatids were depleted and the recovery of these parameters was only observed when spermatogenesis was fully restored. Comparison of the pattern of change in serum levels of inhibin-B and testicular levels of testin and of germ cell numbers strongly suggest a relationship between the disappearance of spermatocytes and spermatids from the seminiferous epithelium and the decrease in levels of inhibin-B and increase in levels of testin from 7 to 36 days post-irradiation. Levels of testin and inhibin-B were restored before spermatogenesis had totally returned to normal. In conclusion, this in vivo study shows that pre-pubertal Sertoli cell function is under the complex control of various germ cell classes. This control presents clear differences when compared with that previously observed in adult animals and depends on the Sertoli cell parameter of interest, as well as on the germ cell type.     

Leydig cell and extracellular matrix effects on Sertoli cell function: biochemical and morphologic studies

The reciprocal influence between Leydig and Sertoli cells prepared from pig testis were studied by coculture of both types of cells in either plastic dishes or dishes coated with basement membrane matrix. After 2-3 days in plastic dishes, Sertoli cells produced an increase in the steroidogenic response of Leydig cells to hCG. Pretreatment of the coculture with pFSH enhanced the steroidogenic capacity of Leydig cells and increased the number of hCG receptors. Similarly, the number of FSH binding sites and the FSH-induced plasminogen activator activity secretion of Sertoli cells cocultured with Leydig cells were increased. Pretreatment of the coculture with hCG further enhanced both parameters. The positive reciprocal tropic effects between Leydig cells and Sertoli cells were significantly enhanced when the coculture was carried out on the top of extracellular matrix. In addition, when cells were cocultured under these conditions, but not on plastic dishes, they were organized in cell clusters or island structures, with most of the Leydig cells located in the outer area, whereas Sertoli cells were located inside the islands.     

Human Sertoli-spermatogenic cell cocultures prepared from biopsies of cryptorchid testes performed during orchidopexy

A procedure is described for the preparation and maintenance of human Sertoli-spermatogenic cell cocultures using biopsies of normal and undescended testis. The evaluation of cell viability and differentiation potential of cultured spermatogenic cell was monitored by [3H]thymidine labeling combined with light microscopic autoradiography. Spermatogenic cells of the same progeny, connected by intercellular bridges, display synchronous DNA synthesis when labeled at the preleptotene stage of meiotic prophase. The pattern of [35S]methionine-labeled secretory proteins was determined by two-dimensional electrophoresis and autoradiography during testicular development and compared with these observed in human Sertoli-spermatogenic cell cocultures prepared from same specimens. Both testicular tissue and cocultured Sertoli and spermatogenic cells displayed comparable patterns of secretory proteins. A discrete group of acidic polypeptides of Sertoli cell origin enhanced their radiolabeling intensity during testicular development. Results of this paper indicate that human Sertoli-spermatogenic cell cocultures could be valuable for assessing the proliferation and differentiation potential of spermatogenic cells in children with cryptorchid testis.     

In-vitro influence of germ cells on Sertoli cel l-secreted proteins: a two-dimensional gel electrophoresis analysis

Two-dimensional polyacrylamide gel electrophoresis (2D PAGE) was used to analyse [³⁵S]-methionine-labelled proteins secreted in vitro by Sertoli cells when cultured in the presence or absence of enriched preparations of pachytene spermatocytes (SPC), early spermatids (SPT) or residual bodies/cytoplasts from elongated spermatids (RB/CES). The presence of germ cells modified the pattern of Sertoli cell secreted proteins in co-culture. Out of 21 Sertoli cell secreted polypeptide families visualized by 2D PAGE, one (referred to as number 12) was stimulated, whereas the secretion of polypeptides 1 and 3 was inhibited by all of the germ cell populations tested. Early spermatids and RB/CES both enhanced the secretion of protein number 10 and inhibited the production of protein 11. The RB/CES fraction specifically inhibited secretion of polypeptide 13. Of particular note was the finding that co-culture with early spermatids or RB/CES induced the secretion of a novel polypeptide, termed GIP (germ cell-induced protein), with an apparent molecular weight of 72 kDa and an isoelectric point of 5.9. Under the present experimental conditions, media conditioned by the different germ cell fractions inhibited the secretion of polypeptide 2 but enhanced the secretion of polypeptides 10 and 18; of note also was the finding that media conditioned by early spermatids or RB/CES induced the appearance of GIP. This study confirms and extends the concept that germ cells influence Sertoli cell function and that the effects observed differ according to the stage of development of the germ cells. However, the sensitivity of the 2D gel electrophoresis technique, and to some extent its reproducibility, limit its use for studying the paracrine control of Sertoli cells in culture.     

Effects of gossypol on rat Sertoli and Leydig cells in primary culture and established cell lines

In order to evaluate the direct effect of gossypol on testicular cells, we used primary cultures of rat Leydig and Sertoli cells. No alteration in Leydig cell survival, morphology, or testosterone production was seen during three days of culture with up to 3 microgram/ml gossypol. With higher concentrations (3 to 7 microgram/ml) of gossypol, there was a reduction in cell survival but no change in androgen secretion. In contrast, there was a marked change in Sertoli cell morphology after five days of gossypol treatment. Large vacuoles and electron dense granules appeared in the cytoplasm, but these effects were reversed within six days of removing gossypol from the medium. There was a significant decrease in androgen binding protein (ABP) secretion by Sertoli cells in the presence of gossypol. We also tested the effect of gossypol on the growth of three established cell lines. Two Sertoli-derived cell lines, TM4 and TR-ST, were more sensitive than a Leydig-derived cell line (TM3). These results suggest that, of the somatic cell types in the testis, the Sertoli cells are most sensitive to gossypol.     

Germ cells and post-natal development of testicular function: in vitro studies]

Studies in recent years have clearly established that, in addition to the well known endocrine regulation by gonadotrophin hormones, spermatogenesis is under the modulatory control of a complex set of paracrine regulators. Whereas the role of Leydig cells (testosterone) and of Sertoli cells (nurce cells of germ cells) in spermatogenesis has focused most of the attention, until recently little was known about the contribution of germ cells in the spermatogenetic process. This was the aim of the present experiments. We have used, in vitro, 3 complementary approaches; 1) we measured the influence of the removal of germ cells contaminating Sertoli cell cultures by a hypotonic treatment; 2) in coculture, we examined to what extend isolated germ cells could affect Sertoli cell function; 3) we investigated the effects of germ cell conditioned media on Sertoli cell cultures. Our results indicate that germ cells are able to modulate Sertoli cell function in vitro. This germ cell influence varies according to: 1) the germ cell fraction tested (pachytene spermatocytes, early spermatids or cytoplast from elongated spermatids/residual bodies); 2) the parameter of Sertoli cell function studied (inhibition of oestradiol; stimulation of androgen-binding protein, transferrin...); 3) the age of the Sertoli cell donors; 4) the hormonal environment (+/- FSH). Furthermore we wave demonstrated that germ cell effects were partly at least mediated via proteinaceous factor(s) detected in germ cell spent media. Taking into account previous in vivo studies and these in vitro results, we have hypothesized that germ cells, in conjunction with hormones (LH, FSH, testosterone) play an important role in the ontogenesis of Sertoli cells and therefore in spermatogenesis.     

Effect of cryptorchidism and orchidopexy on inhibin secretion by rat Sertoli cells

The present study explored the effects of experimental bilateral cryptorchidism (of 21-, 28-, and 35-days duration) and orchidopexy (14 and 42 days) in the adult rat on the secretion of inhibin by cultures of isolated Sertoli cells. Changes in serum levels of gonadotropins, testis weight, and spermatogenesis also were assessed to verify the effectiveness of the surgical procedures. Cryptorchidy resulted in a progressive decline in testicular weight and a loss of germ cells, associated with increasing serum levels of FSH and LH. Inhibin secretion in vitro became nondetectable by 28 days after surgery. At 42 days after orchidopexy, spermatogenesis showed qualitative recovery, with a small increase in testes weight. Levels of LH in the circulation declined, but only to twice the intact control levels. However, inhibin secretion and serum FSH levels returned to nearly normal values. These results indicate that bilateral cryptorchidism severely impairs the secretion of inhibin and possibly other Sertoli cell functions which may account, at least partly, for the increase in circulating FSH levels and the arrest of spermatogenesis. The effects of cryptorchidism on these parameters can be reversed to a large degree by orchidopexy.     

Bovine sertoli cells colonize and form tubules in murine hosts following transplantation and grafting procedures

The contribution of somatic cells to nonrodent male germ cell transplantation success has not been well established due to lack of cell type-specific markers to distinguish donor cells from host cells. In the present study, we first screened antibodies and a lectin to identify markers suitable for unequivocal distinction between germ cells and Sertoli cells in bovine testes compared with mouse testes. Anti-vimentin and the Dolichos biflorus agglutinin (DBA) lectin detected only bovine Sertoli cells and spermatogonia, respectively; anti-NONO and anti-GCNA1 detected only mouse Sertoli and germ cells, respectively. The outcome of transplanting bovine testis cells into nude mouse testes was then studied using these markers. Our results clearly showed that immature bovine Sertoli cells survive and colonize mouse testes at 2.5 months after transplantation and that tubular structures composed of donor Sertoli cells formed adjacent to murine tubules within the host mouse testis. Bovine germ cell colonization and survival in mouse testes after transplantation were confirmed, but this was restricted to areas of bovine Sertoli cell colonization. In addition, ectopic grafts of intact bovine testis tissue and cell aggregates from hanging drop cultures were placed under the back skin and testis capsule of nude mice. Bovine Sertoli cells in ectopic grafts and aggregates were able to form tubular structures, and some bovine germ cells were observed around 2 months after implantation. This study therefore identifies a practical strategy to assess the outcome of testicular cell transplantation using different antibodies and a lectin to distinguish bovine cells from mouse cells. It identifies an approach that can readily be adapted to study other nonrodent species.     

Temperature and germ cell regulation of Leydig cell proliferation stimulated by Sertoli cell-secreted mitogenic factor: a possible role in cryptorchidism

Summary. Local control of Leydig cell morphology and function by seminiferous tubules was suggested in previous in vivo studies, especially those that used experimental cryptorchid rat testis as a model. These studies reported changes in morphology, increases in cell number and mitotic index and decreases in testosterone formation and luteinizing hormone/human chorionic gonadotropin receptor levels of Leydig cells. However, little is known about how these changes are mediated. We recently observed that a novel Sertoli cell-secreted mitogenic factor stimulated proliferation, decreased testosterone formation and luteinizing hormone/human chorionic gonadotropin receptor levels, and dramatically altered the morphology of Leydig cells in culture. In the present studies, we demonstrate that an increase in coculture temperature from 33 to 37 °C increased [³H]-thymidine incorporation (5.6- vs. 19.2-fold) and labelling index (4.3% vs. 15.8%), and accelerated proliferation (2.1- vs. 3.9-fold) of cultured immature Leydig cells. In addition, testosterone formation and luteinizing hormone/human chorionic gonadotropin receptor levels of Leydig cells cocultured with Sertoli cells were further decreased following a 4°C increase in coculture temperature. This elevation in culture temperature increased both the secretion of this factor by Sertoli cells and responsiveness of Leydig cells to this factor. In addition, the presence of germ cells, especially pachytene spermatocytes, inhibited the secretion of the mitogenic factor by Sertoli cells. These temperature- and germ cell-associated effects mimicked the morphological and functional changes of Leydig cells reported following experimental cryptorchidism. These observations suggest a possible role of this Sertoli cell-secreted mitogenic factor in explaining Leydig cell changes following experimental cryptorchidism.     

Endocrine correlates of meiosis in the male rat.

Changes in the proportion of cells within various DNA classes of dispersed testicular cells from the developing rat were monitored by microflow fluorometry and correlated with changes in the function of the pituitary (FSH), of the Leydig cells (androgens) and Sertoli cells (androgen-binding proteins, ABP). Peaks of androgens and of FSH appeared simultaneously and coincided with an accumulation of tetraploid cells and with the first appearance of haploid cells in the testis and ABP in the epididymis. Estrogen treatment (5 micrograms/day) of developing rats from day 7 completely prevented the appearance of haploid cells in the testis as well as ABP in the epididymis. In these animals the wave of tetraploid cells started and progressed normally, indicating that transformation and progression of germinal cells to the stage of the primary spermatocytes were taking place. A combined treatment with FSH and dihydrotestosterone propionate (DHTP) resulted in a premature start of Sertoli cell secretion of ABP into the epididymis, but in a normal appearance of haploid and tetraploid cells. The time correlation between peaks in FSH/androgens, the start of Sertoli cell secretion, and the occurrence of haploid cells in the testis stresses the importance of these two hormones for normal Sertoli cell function and the importance of a functional Sertoli cell for the completion of meiosis.     

Tonic inhibition of adenylate cyclase in cultured hamster Sertoli cells

Sertoli cells cultured from immature hamsters respond to FSH with a dose-related increase in cAMP accumulation. Pertussis toxin acts synergistically with FSH to stimulate cAMP accumulation. This effect of pertussis toxin indicates that Sertoli cell adenylate cyclase is under tonic inhibition due to the activity of the Ni inhibitory transducer. The acetylcholine receptor antagonists atropine or tubocurarine, or the opioid antagonist naltrexone, have no effect on the FSH-induced stimulation of cAMP accumulation, suggesting that neither acetylcholine nor opioids are responsible for the inhibition of Sertoli cell cyclase. While exogenous adenosine is inhibitory, adenosine deaminase augments the ability of FSH to stimulate cAMP accumulation, but not to the level of pertussis toxin. This indicates that the Sertoli cells produce endogenous adenosine that is at least partially responsible for the tonic inhibition of adenylate cyclase. Other possibilities for the tonic inhibition of cyclase include other Sertoli cell products, germ cell products, peritubular cell products or an action of FSH itself through both stimulatory and inhibitory transducers.     

Regulation of Sertoli cell myotubularin (rMTM) expression by germ cells in vitro

Recent studies have shown that rat myotubularin (rMTM), the homolog of human myotubularin, which is a putative protein tyrosine phosphatase (PTP), is expressed by Sertoli cells in the rat testis. In addition, a significant increase in its steady-state mRNA level was detected in Sertoli cells at the time of inter-Sertoli tight junction (TJ) assembly in vitro. Since the interplay of protein kinases and phosphatases that determines the intracellular phosphoprotein content can, in turn, regulate the assembly and maintenance of TJ and anchoring junctions (AJ) in vitro, as demonstrated in different cell types, such as Madin-Darby canine kidney (MDCK) cells, endothelial cells, and Sertoli cells, rMTM may be an important molecule in regulating the assembly and maintenance of inter-Sertoli TJs during spermatogenesis. We thus sought to characterize its regulation. During testicular maturation, it was shown that the rMTM steady-state mRNA level increased drastically with aging. The expression of rMTM increased by as much as 2-4-fold in the rat testis at 45-60 days of age versus 20 days of age, coinciding with the onset of spermiation. This result seemingly suggests that rMTM may participate in the release of spermatids by disassembling the Sertoli-spermatid AJs, since PTP inhibitor was shown to perturb the inter-Sertoli TJ permeability barrier in vitro. Unexpectedly, when Sertoli cells were isolated from 20-, 45-, and 90-day-old rats and the steady-state rMTM level was quantified, it was shown that there is a drastic reduction in rMTM expression in adult Sertoli cells. Studies that used Sertoli-germ cell cocultures and Sertoli cells incubated with increasing germ cell-derived proteins have shown that the high level of testicular rMTM expression in the testis might be maintained by germ cells. Although work remains to be done to delineate the role of rMTM in the testis, these results illustrate that germ cells play a very active role in regulation testicular function by altering the phosphoprotein content.     

Cytokines produced by microwave-radiated Sertoli cells interfere with spermatogenesis in rat testis

Microwave radiation resulted in degeneration, apoptosis or necrosis in germ cells at different stages. The molecular mechanisms by which microwaves induce spermatogenesis disorder have not been completely understood. Sertoli cells play crucial roles in mammalian spermatogenesis. Cytokines produced by Sertoli cells play pleiotropic roles in different conditions. At physiologically low concentration, TNFα, IL-1β and IL-6 behave as survival factors; while under pathological condition, these cytokines can induce apoptosis in testis. The effects of cytokines produced by microwave-radiated Sertoli cells on spermatogenesis are poorly understood. The purpose of this study was to determine the effect of cytokines produced by microwave-radiated Sertoli cells on the germ cells. We focused the effect of TNFα, IL-1β and IL-6 on the germ cells. The results showed that TNFα, IL-1β and IL-6 were increased in Sertoli cells after exposure to microwave radiation. These up-regulated cytokines can induce apoptosis and lipid peroxidation in the membrane of germ cells. In addition, germ cell apoptosis was associated with the up-regulation of Bax/Bcl-2 and caspase-3. These results suggest that cytokines produced by microwave-radiated Sertoli cells may disrupt spermatogenesis. Our data provided novel insight into the injury mechanism of germ cells induced by microwave radiation.