Effect of cordycepin on CRF stimulation and steroid inhibition of ACTH secretion by rat pituitary cells.

Isolated pituitary cells prepared from adrenalectomized rats secrete ACTH in response to CRF, and this response is inhibited by corticosterone. Both the stimulation of release by CRF and the inhibition of release by corticosterone are antagonized by cordycepin (3'-deoxyadenosine). Inhibition of CRF-stimulated secretion by cordycepin is apparently not related to inhibition of RNA synthesis, since high doses of actinomycin D do not affect ACTH secretion. More likely, cordycepin's inhibition of secretion stems from its inhibition of adenylate cyclase activity. Inhibition of corticosterone action by cordycepin is qualitatively similar to that previously reported actinomycin D. This effect of both drugs is probably due to inhibition of RNA synthesis. Significantly, a low dose of cordycepin has a greater inhibitory effect on corticosterone action than on total cellular RNA synthesis. Cordycepin is reported to preferentially inhibit messenger RNA synthesis, and low dose preferentially inhibits appearance of cytoplasmic RNA in pituitary cells. These data suggest that corticosterone-induced RNA is a cytoplasmic (messenger) RNA.     

Mitochondrial cholesterol availability during gonadotropin-induced Leydig cell desensitization

In order to define the early lesion (before pregnenolone formation) of the androgen biosynthetic pathway induced by human CG (hCG) or LH in the Leydig cell, we initially have optimized the use of aminoglutethimide to obtain maximal and sustained inhibition of steroidogenesis in vivo and in vitro. Aminoglutethimide inhibited Leydig cell steroidogenesis in vitro at a dose of 100 micrograms/ml. The minimal serum concentration of aminoglutethimide necessary for maximal inhibition of testosterone in vivo was also 100 micrograms/ml (1 h after the ip injection of 20 mg aminoglutethimide). However, testosterone levels were normal 12 h later, coincident with a marked fall in the serum aminoglutethimide levels. The t 1/2 of the circulating aminoglutethimide was 5 +/- 0.7 h on the first day of treatment but was reduced to 3.0 +/- 0.4 and 2.25 +/- 0.35 h at 2 and 3 days of treatment. At the dose eliciting maximal and sustained steroid inhibition (60 mg/day) aminoglutethimide was able to prevent the estradiol-dependent late steroidogenic lesion (after pregnenolone formation) induced by 1 microgram hCG, with no effect on the early lesion (before pregnenolone formation) caused by 10 micrograms hCG. The aminoglutethimide-induced in vivo accumulation of cholesterol in the inner mitochondrial membrane (by 50%) was associated with an increase in the production of testosterone and pregnenolone by the Leydig cell when subsequently incubated in vitro. Similar increases in the steroidogenic capacity were observed after initial exposure of Leydig cells to aminoglutethimide in vitro, even after acid wash to remove the surface-bound endogenous LH. The steroidogenic cholesterol was also increased in desensitized Leydig cells (by 50-70%); however, the conversion of cholesterol to pregnenolone was substantially blocked in animals with the early lesion. Our findings define the requirement of increasing high levels of aminoglutethimide to inhibit cholesterol metabolism and provide a dose schedule suitable for studies on cholesterol availability and inhibition of steroidogenesis in the rat. These results support our proposal that the early lesion observed in desensitized Leydig cells is due to inhibition of the side-chain cleavage activity rather than to a decrease in the amount of metabolically available cholesterol.     

Corticosteroid and ribonucleic acid synthesis in isolated adrenal cells: Inhibition by actinomycin D

Both adrenocorticotrophic hormone (ACTH) and cyclic AMP rapidly stimulate corticosterone synthesis in isolated adrenal cells prepared by collagenase disaggregation of decapsulated rat glands. This steroidogenic response is not accompanied by any acute increase in the incorporation of [³H]uridine into acid insoluble RNA; indeed a slight decrease is observed during the incubations. A wide variety of different effects of actinomycin D on adrenal steroidogenesis have previously been reported. The effects of a range of actinomycin D concentrations (1–50 μmol/l) on the steroidogenesis brought about by different concentrations of ACTH (0.1–100. mi.u./ml) and cyclic AMP (1–5 mmol/l) were therefore examined. Actinomycin D (1 μmol/l) inhibits overall RNA synthesis by over 91% but has little or no effect on the cellular response to low concentrations of ACTH, although both basal (non-stimulated) corticosterone output and cyclic AMP stimulated steroidogenesis are appreciably inhibited (by 29–54%). Even at very high doses of actinomycin D (50 μmol/l), which inhibit RNA synthesis by 96% a substantial steroidogenic stimulation is obvious at all concentrations of ACTH and cyclic AMP studied. There is a greater inhibition of stimulated steroidogenesis not only with increasing actinomycin D concentrations, but also with increasing time of cellular exposure to actinomycin D. It is concluded that the acute steroidogenic ACTH mechanism does not require newly synthesized RNA and that if the inhibition by actinomycin D is simply due to an effect on synthesis of various RNA species, then the shortest estimate of the half-life of any RNA involved is 70 min.     

Prolactin and antiprolactin receptor antibody inhibit steroidogenesis by purified rat Leydig cells in culture

The in vitro effects of ovine PRL (oPRL) on testicular testosterone synthesis were determined using isolated, collagenase-dispersed, adult rat Leydig cells in culture. oPRL (50-1000 ng/ml) had no effect either on basal or on LH (50, 100 or 2000 pg/ml)-stimulated testosterone secretion by Leydig cells in short-term culture (4 h). 125I-oPRL binding studies revealed a single class of high affinity sites (Ka 8.7 nM) with a low capacity (Bmax 6.7 fmol/mg protein identical to approximately 980 sites/Leydig cell). Isolated Leydig cells were further purified on a continuous Percoll gradient and cultured in serum-free medium, at 34 degrees C, in 5% CO2 and 95% air. After 3 days of culture, the media were collected, the cells washed and then stimulated with hCG (3 ng/ml) for 3 h. oPRL (1-1000 ng/ml) added at plating, caused a log dose-dependent inhibition of testosterone accumulation during the 3-day culture period; the highest and most consistent inhibition (31%) was with 500 ng/ml oPRL. hCG increased the sensitivity to the inhibitory effect of PRL, 10 ng/ml oPRL causing 40% inhibition and 100 ng/ml causing a maximal inhibition of 50%. PRL in fact caused a reduction in the maximal effect (efficacy) of hCG on steroidogenesis, without significantly affecting the ED50 (sensitivity). The effects of an antiPRL receptor antibody raised by the antiidiotypic route and previously shown to bind to rat testis PRL receptors were tested. The antiPRL receptor IgG (13 micrograms/ml) mimicked the PRL inhibitory effect and acted synergistically with PRL (100 ng/ml) in inhibiting both testosterone accumulation in 3-day cultured Leydig cells and their subsequent response to hCG. In summary, a clear inhibitory effect of PRL and a synergistic effect of antiPRL receptor antibody were demonstrated on testosterone synthesis by rat Leydig cells in 3-day culture.     

Characterization of insulin and insulin-like growth factor I receptors of purified Leydig cells and their role in steroidogenesis in primary culture: a comparative study

Characterization of insulin and type I insulin-like growth factor (IGF-I) receptors and the effects of insulin and IGF-I on steroidogenesis were evaluated by using purified adult Leydig cells from Sprague-Dawley rats. Purified Leydig cells were found to contain both high and low affinity binding sites for insulin, with Ka values of 1.08 X 10(9) and 1.1 X 10(7) M-1, respectively. Using affinity cross-linking of [125I]iodoinsulin to plasma membrane insulin receptor, several bands were identified by autoradiography under nonreduced conditions with mol wt of 230,000, 280,000, and 300,000. After reduction with 50 mM dithiothreitol, only one band was identified with a mol wt of 130,000, consistent with the alpha-subunit of insulin receptor. Purified Leydig cells also contain specific type I IGF receptors with estimated binding affinity of 0.6 X 10(9) M-1. Multiple high mol wt bands (greater than 250,000) were identified under nonreduced conditions by affinity cross-linking. Under reduced conditions, one band with an approximate mol wt of 135,000 was identified. Purified Leydig cells (10(5) cells/ml) were cultured in Dulbecco's Modified Eagle's Medium-Ham's F-12 Nutrient Mixture (1:1) containing 0.1% fetal calf serum at 37 C in a humidified atmosphere of 5% CO2-95% air. Insulin and IGF-I stimulated testosterone formation as early as 3 h after administration, and their effects were completely blocked by the addition of a protein synthesis inhibitor, cycloheximide (1 microgram/ml). Insulin and IGF-I also significantly potentiated hCG-and 8-bromo-cAMP-induced testosterone formation. Furthermore, insulin and IGF-I potentiated hCG-stimulated cAMP formation. This suggests that insulin and IGF-I have effects at both the LH receptor sites and the steps beyond adenylate cyclase. The ED50 values of insulin and IGF-I-stimulated testosterone formation were comparable (25 ng/ml). In conclusion, we found that Leydig cells contain specific insulin and type I IGF receptors, and both insulin and IGF-I are capable of modulating Leydig cell steroidogenesis.     

Effect of myxothiazol on Leydig cell steroidogenesis: inhibition of luteinizing hormone-mediated testosterone synthesis but stimulation of basal steroidogenesis

Studies of MA-10 Leydig cells have shown that intact mitochondria with active respiration are essential for LH-induced Leydig cell steroidogenesis. To further elucidate the role played by mitochondria in steroidogenesis, we examined the effects of the perturbation of the mitochondrial electron transport chain with myxothiazol (MYX) on testosterone production by primary cultures of Brown Norway rat Leydig cells. Analysis of the steroidogenic pathway revealed that cAMP production and the activities of each of 3beta-hydroxysteroid dehydrogenase, 17alpha-hydroxylase/C17-20 lyase, and 17beta-hydroxysteroid dehydrogenase were inhibited by MYX and that LH-stimulated testosterone production was suppressed. In contrast to the inhibition of LH-stimulated testosterone production by MYX, the incubation of Leydig cells with MYX in the absence of LH stimulated testosterone production. Although testosterone production was increased, steroidogenic acute regulatory protein was decreased in response to MYX, not increased as could be expected. Additional electron transport chain inhibitors had stimulatory effects on testosterone production that were similar to those of MYX, strongly suggesting that the effect of MYX on basal testosterone production is related to its effect on the mitochondrial electron transport chain. Finally, incubation of the cells with a combination of MYX and the calcium chelator 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetracetic acid tetrakis acetoxymethyl ester suppressed MYX-mediated increased basal steroidogenesis but had no effect on hydroxycholesterol-mediated steroidogenesis. Taken together, these results indicate that inhibition of the mitochondrial electron transport chain can block LH-stimulated testosterone production through suppression of a number of steps of the steroidogenic pathway but also stimulates basal testosterone production through a calcium-mediated mechanism.     

Effects of cannabinoids on testosterone and protein synthesis in rat testis Leydig cells in vitro.

Various water-insoluble cannabinoids as well as SP-111A, the water-soluble derivative of delta 9-tetrahydrocannabinol (delta 9-THC), reduced hCG and dibutyryl-cAMP stimulated testosterone production by rat testicular Leydig cell preparations. With 0.15 microM (0.05 micrograms/ml) 8-beta-OH-delta 9-THC the inhibition was about 50% of stimulated testosterone synthesis. Dose-related inhibitions were apparent with other cannabinoids and their order of potency in inhibiting stimulated steroidogenesis by the interstitial cells in vitro was found to be: 8-beta-OH-delta 9-THC greater than or equal to 11-OH-delta 9-THC greater than CBN = CBD = CBG greater than or equal delta 9-THC = delta 8-THC. The non-stimulated, basal, steroidogenesis was not affected even with 15 microM cannabinoids. The incorporation of L-[U-14C]leucine into the protein of Leydig cells was markedly reduced by 15 microM cannabinoids under both basal and stimulated conditions. The inhibition of steroidogenesis as well as protein synthesis in rat testicular Leydig cell preparations by various cannabinoids cannot be correlated with their psychoactivity. The present data suggest that cannabinoids at very low concentrations may interfere directly in Leydig cells with both protein and testosterone synthesis, and thus with their function.     

Studies of the human testis. XVIII. Simultaneous measurement of nine intratesticular steroids: evidence for reduced mitochondrial function in testis of elderly men

To determine the basis for the decline in testosterone production by the aged testis, intratesticular unconjugated steroids, including testosterone, pregnenolone (3 beta-hydroxy-5-pregnen-20-one), 17 alpha-hydroxypregnenolone (3 beta,17 alpha-dihydroxy-5-pregnen-20-one), dehydroepiandrosterone (3 beta-hydroxy-5-androsten-17-one), androstenediol (5-androstene-3 beta,17 beta-diol), progesterone, 17 alpha-hydroxyprogesterone, androstenedione (4-androstene-3,17-dione), and 17 beta-estradiol, were measured by simultaneous RIAs in 32 previously untreated elderly men (aged 61-85 yr) undergoing orchiectomy as therapy for prostatic carcinoma and 20 young men (aged 25-35 yr) with oligospermia and varicocele. In vitro steroidogenesis using labeled pregnenolone as substrate was also investigated. Serum and intratesticular testosterone levels were lower (P less than 0.05) in aged patients [3.3 +/- 1.9 ng/ml and 0.86 +/- 0.53 microgram/g tissue (mean +/- SD)] than in young men (6.4 +/- 1.9 ng/ml and 1.7 +/- 1.1 microgram/g tissue), while circulating LH levels were higher (P less than 0.05) in elderly men (151 +/- 105 ng/ml) than in the young men (79 +/- 33 ng/ml), indicating that a primary pathological process affects the senescent testis, producing a decline in testosterone production. Study of bioconversion of [3H]pregnenolone to delta 4 steroids, 17 alpha-hydroxysteroids, and C19 steroids as well as analysis of the relative amounts of intratesticular steroids, as determined by RIA, revealed no apparent differences in the process of microsomal steroidogenesis in elderly compared to that in young men. The sum of the nine measured intratesticular steroid concentrations per g tissue wt was significantly lower (P less than 0.05) in aged patients (1.94 +/- 0.93 microgram/g tissue), than in young patients (3.68 +/- 1.90 micrograms/g tissue). The sum of the nine intratesticular steroids measured was positively correlated (P less than 0.01) with circulating LH levels in both patient groups, and the slope of this regression line was 14-fold greater for young men than for elderly men. Since the total concentration of the nine measured steroids reflects the pregnenolone supplied by the mitochondria within Leydig cells, it appears that the decline in Leydig cell function in aged men is attributable to a reduced supply of mitochondrial steroid precursors rather than to an impairment in microsomal steroidogenesis.     

Serum lipoproteins increase testosterone production in hCG-desensitized Leydig cells

The effects of high density and low density lipoproteins (HDL and LDL) on testosterone synthesis by Leydig cells from rats treated three days earlier with 50 IU human chorionic gonadotropin (hCG) or from saline-injected control rats were investigated. HDL caused a significant, dose-dependent increase in both basal and hCG-stimulated testosterone production by Leydig cells from hCG-treated rats, but had no marked effect on Leydig cells from control rats. The serum testosterone concentration of hCG-treated rats was three times higher than in controls. Basal testosterone production by Leydig cells from hCG-treated rats was elevated two-fold in comparison to controls, while hCG-stimulated testosterone production was significantly lower than in controls. Both basal and hCG-stimulated testosterone production by Leydig cells from hCG-treated rats were significantly increased by the addition of HDL or LDL. Furthermore, HDL restored the hCG-stimulated testosterone production to the maximal amount produced by hCG-stimulated Leydig cells from control animals. When equivalent amounts of HDL or LDL cholesterol (140 microgram/ml) were added to the incubation, HDL caused a greater increase in testosterone production than did LDL. These results suggest that hCG-treatment, in vivo, caused a prolonged stimulation of the Leydig cells which resulted in depletion of the cholesterol available for steroidogenesis, since the addition of cholesterol in the form of HDL or LDL caused an increase in the testosterone production of these Leydig cells.     

Hypertension associated with decreased testosterone levels in natriuretic peptide receptor-A gene-knockout and gene-duplicated mutant mouse models.

Mice lacking the gene (Npr1) encoding the natriuretic peptide receptor A (NPRA) have hypertension with elevated blood pressure and cardiac hypertrophy. In particular, Npr1 gene-deficient male mice exhibit lethal vascular events similar to those seen in untreated human hypertensive patients. Serum testosterone levels tend to be lower in hypertensive male humans than in normal males without hypertension, but the genetic basis for this tendency remains unknown. To determine whether Npr1 gene function affects the testosterone level, we measured serum testosterone in male hypertensive mice lacking a functional Npr1 gene, wild-type animals with two copies, and the gene-duplicated littermates expressing four copies of the gene. In the Npr1 gene-knockout (zero-copy) mice, the serum testosterone level was 62% lower than that in the two-copy control mice (80+/-10 ts. 120+/-14 ng/ml, respectively; P < 0.005). Serum testosterone in the four-copy mice was 144% (P < 0.005) of that in the two-copy wild-type control mice. To investigate the role of NPRA in testicular steroidogenesis, we analyzed atrial natriuretic peptide (ANP)-dependent guanylyl cyclase activation, accumulation of intracellular cGMP, and testosterone production in purified primary Leydig cells from animals with zero, two, or four copies of the Npr1 gene. Leydig cells lacking the Npr1 gene did not show ANP-stimulated guanylyl cyclase activation or cGMP accumulation and had no ANP-dependent testosterone production. ANP stimulation of Leydig cells from the four-copy males elicited a 2-fold greater production of cGMP compared to that in the two-copy wild-type counterparts (260+/-12 vs. 126+/-7 pmol/l x 10(6) cells; P < 0.001). Similarly, ANP-dependent testosterone production in Leydig cells was nearly twice as high in four-copy mice as in two-copy wild-type controls (561+/-18 vs. 325+/-11 ng/l x 10(6) cells; P < 0.001). ANP-dependent guanylyl cyclase activation and production of cGMP in Leydig cells increased progressively with the number of Npr1 gene copies. Our results establish the existence of an alternate mechanism for testicular steroidogenesis that is stimulated by NPRA-dependent cGMP signaling, in addition to that mediated by gonadotropins, via a cAMP pathway. These findings demonstrate the role of Npr1 gene function in the maintenance of serum testosterone levels and testicular steroidogenesis and provide a genetic link between hypertension associated with decreased NPRA and low testosterone levels.     

Vitamin E, aging and Leydig cell steroidogenesis

Previous studies have suggested that oxidant-induced damage may play a role in the reduced ability of aged Brown Norway rat Leydig cells to produce testosterone. We reasoned that if this was the case, antioxidants such as vitamin E (VE) would be expected to have protective effects on steroidogenesis. To test this hypothesis, the effects of VE on Leydig cell steroidogenesis were examined both in vitro and in vivo. In vitro studies were conducted using Leydig cells isolated from the testes of young adult Brown Norway rats. In one experiment, isolated cells were incubated with luteinizing hormone (LH) alone or with LH plus VE (1.3-40 microg/ml). At each of 3, 5 and 7 days thereafter, the ability of the cells to produce testosterone was greater in the presence of VE than in its absence, and depended upon VE dose. Culturing the Leydig cells with the antioxidants melatonin or N-tert-butyl-alpha-phenylnitrone also protected Leydig cell steroidogenic function. Additionally, VE was found to suppress Fe2+/sodium ascorbate-induced lipid peroxidation in Leydig cells. These studies strongly supported the contention that VE has a protective effect on Leydig cell steroidogenesis. These in vitro results prompted us to ask whether, in vivo, VE also would affect steroidogenesis as Leydig cells age. To this end, rats were provided one of three diets, begun when the rats were 6 months of age and carried out through age 25 months: VE-deficient, VE-control, or VE-supplemented. The VE-deficient diet had no effect on the age-related reductions in Leydig cell testosterone production observed in VE-control rats. The VE-supplemented diet did not prevent age-related reductions in steroidogenesis, but the reductions at ages 23 and 25 months were significantly less than those seen in Leydig cells from VE-control or VE-deficient rats. Taken together, the results of the in vitro and in vivo studies reported herein are consistent with the conclusion that vitamin E exerts a protective effect on Leydig cell steroidogenesis.     

RNA synthesis in the Leydig cells of the mature rat: effect of oestradiol-17 beta

In view of the evidence that there may be an effect of high concentrations of oestradiol on testicular steroidogenic function, we have investigated the effect of this steroid on [3H]uridine incorporation into RNA by testicular cells. Our results have shown that oestradiol in vitro induced a marked dose-dependent inhibition of RNA synthesis by purified Leydig cells. The concentrations of oestradiol tested varied from 2 to 40 mumol/l; these concentrations also impaired net testosterone synthesis in vitro after human chorionic gonadotrophin (hCG) stimulation. Under the effect of oestradiol, the kinetics of [3H]nucleoside incorporation into RNA were impaired early and the inhibition of RNA synthesis was specific for oestrogenic compounds. It was concluded that, in Leydig cells, oestradiol, in addition to its known inhibitory action on the response of testosterone to hCG, triggers a more extensive response that also includes RNA synthesis in vitro.     

Gonadotropin binding and stimulation of steroidogenesis in Leydig tumor cells

Testicular tumors are generally characterized by a loss of responsiveness to gonadotropins. The M5480 Leydig cell tumor is unusual, if not unique, in that it responds to human choriogonadotropin and to lutropin via increased steroidogenesis. This report describes the identification of two variants of the original M5480 tumor that have altered steroid output both in the basal state and in response to human choriogonadotropin. One of the tumors produces mainly progesterone, which is stimulated by the choriogonadotropin; the other tumor produces about equal amounts of progesterone and testosterone, and the secretion of both is stimulated by the choriogonadotropin. The dissociation constant describing the interaction between Leydig tumor cells and ¹²⁵I-labeled human choriogonadotropin is between 3 and 5×10^-11 M. This agrees with values reported for normal Leydig cells, although the tumor cells appear to have fewer receptors. The differences noted in the two tumors and normal Leydig cells may have arisen from alterations in gene regulation, or in mutations, involving one or more enzymes in the pathway in which progesterone is converted to testosterone. Under the experimental conditions used, all the tumors studied (seven generations) responded to the choriogonadotropin both in binding and in the resultant stimulation of steroidogenesis. This property, together with the characteristic that a homogeneous cell population can be obtained without enzymatic treatment, should qualify the M5480 Leydig cell tumor(s) as a model system for further studies on the mechanism of action of gonadotropin, on hormone receptors, and on hormonally responsive tumors.     

Comparison of steroidogenic potencies of homologous and heterologous gonadotropins in rat and mouse Leydig cells.

The in vitro steroidogenic potencies have been determined in rat and mouse Leydig cells for two homologous human gonadotropins, lutropin (hLH) and choriogonadotropin (hCG), and two heterologous gonadotropins, hCG beta wild-type and the product of an hCG beta clone containing a premature termination codon at position 122, each associated with a co-expressed bovine alpha subunit. hCG was found to be more potent than hLH in rat, but not mouse Leydig cells, and the heterologous gonadotropin containing the truncated hCG beta subunit was equipotent to that with hCG beta wild-type in both rat and mouse Leydig cells. Persistent steroidogenesis was determined by measuring testosterone production following pre-incubation with each of the above four gonadotropins and with ovine LH, subsequent washing of the cells, and re-incubation in the absence and presence of additional hormone. Interesting differences were found with the five gonadotropins in rat and mouse Leydig cells. The testosterone response to all gonadotropins in rat Leydig cells was essentially the same whether or not additional hormone was added after the initial cell incubation and washing. In contrast, only hLH and hCG yielded identical responses in mouse Leydig cells in the presence and absence of additional hormone, testosterone production being invariably lower with ovine LH and the two expressed heterologous gonadotropins unless they were present in the second incubation. In summary, the hCG beta C-terminal sequence from residues 122-145 makes no discernible contribution to the in vitro potency in rat or mouse Leydig cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Danazol inhibits steroidogenesis in the rat testis in vitro.

The effects of danazol on steroidogenesis in vitro in the rat testis were examined by studying: 1) androgen synthesis in rat Leydig cells cultured with danazol, 2) danazol binding to rat testis microsomal cytochrome P-450, and 3) enzyme kinetics of danazol inhibition of the microsomal enzymes of testicular steroidogenesis. Concentrations of danazol as low as 1 micrometer suppressed LH-stimulated testosterone and androstenedione production in cultured Leydig cells. The addition of danazol to a preparation of testicular microsomes elicited a type I cytochrome P-450 binding spectrum, with an apparent spectral dissociation constant (Ks) of 4.8 micrometer. Danazol inhibited progesterone and 17alpha-hydroxy-progesterone binding to microsomal P-450 with apparent spectral inhibition constants of 2.4 micrometer and 2.8 micrometer, respectively. Danazol competitively inhibited 3beta-hydroxy-delta5-steroid dehydrogenase-isomerase (apparent enzymatic inhibition constant, KI = 5.8 micrometer), 17alpha-hydroxylase (KI = 2.4 micrometer), 17,20 lyase (KI = 1.9 micrometer), and 17beta-hydroxysteroid dehydrogenase (KI = 4.4 micrometer). These findings indicate that low concentrations of danazol directly inhibit steroidogenesis in the rat testis in vitro.     

Measurement of steroidogenesis in rodent Leydig cells: a comparison between pregnenolone and testosterone production

The efficiency and specificity of inhibition of pregnenolone metabolism in mature, immature rat Leydig cells, mouse and tumour Leydig cells by SU-10603, a 17 alpha-hydroxylase inhibitor and epostane (WIN-32729), a 3 beta-hydroxysteroid dehydrogenase inhibitor, were studied. Metabolism of [14C]pregnenolone by mature rat Leydig cells was inhibited for more than 95% in the presence of 20 microM SU-10603 and 5 microM epostane. The sum of the different steroids produced by Leydig cells from immature rats incubated in the presence of a 5 alpha-reductase inhibitor was only 80% of pregnenolone production in the presence of SU-10603 and epostane. Pregnenolone metabolism could also be inhibited in tumour Leydig cells but not in mouse Leydig cells. Pregnenolone and testosterone production by Leydig cells from mature rats were similar when steroidogenesis is maximally stimulated by luteinizing hormone (LH). However, in the presence of LH and bovine serum albumin (bSA), or 22 R-hydroxycholesterol and bSA, pregnenolone production was 1.7- and 6-fold higher respectively, than testosterone production. The data show that for measuring the steroidogenic activity of Leydig cells estimation of pregnenolone production is more reliable than measuring testosterone production. At high activities of the cholesterol side-chain cleavage (CSCC) the conversion of pregnenolone into testosterone may become the rate-limiting step for testosterone production. Under all conditions the conversion of cholesterol into pregnenolone is the (hormonal regulated) rate-determining step for steroidogenesis.     

On the role of protein synthesis in the response of adrenal tumor cells to ACTH.

Y-1 adrenal tumor cells were incubated with aminoglutethimide with and without ACTH. Greater production of pregnenolone from endogenous cholesterol was observed (after washing to remove aminoglutethimide) in mitochondria from cells incubated with aminoglutethimide and ACTH than in those from cells incubated with aminoglutethimide alone. This response was inhibited by cycloheximide and puromycin but not by chloramphenicol or actinomycin D. ACTH increased the incorporation of [3H]tyrosine into protein associated with mitochondria but not into total cell protein or protein of postmitochondrial supernatant. This response did not require aminoglutethemide block and was inhibited by cycloheximide and puromycin but not by chloramphenicol or actinomycin D. Dibutyryl cyclic AMP produced both of these responses (increased production of pregnenolone and synthesis of protein associated with mitochondria). The concentration of cycloheximide required to cause 50% inhibition of the responses to ACTH and dibutyryl cyclic AMP was approximately the same for steroidogenesis by whole cells, for production of pregnenolone by isolated mitochondria, for incorporation of [3H]tyrosine into Y-1 cell protein and for the increase in synthesis of protein associated with mitochondria produced by ACTH (0.08--0.2 microgram/ml). Disc gel electrophoresis revealed that the increased incorporation of [3H]tyrosine involved two proteins corresponding to molecular weight of approximately 27,000 and 13,000 respectively. These observations suggest that ACTH promotes synthesis of protein(s) by cytoplasmic ribosomes on stable messenger RNA, that the protein(s) becomes associated with mitochondria and that the protein(s) includes one or more which are associated with the increase in production of pregnenolone produced in mitochondria by the addition of ACTH to adrenal cells.     

Evidence for specific binding and stimulatory effects of recombinant human erythropoietin on isolated adult rat Leydig cells.

The presence of specific binding of recombinant human erythropoietin and its effect on testosterone production were evaluated in isolated intact adult rat Leydig cells. Maximal specific binding was observed after 135 min incubation at 34 degrees C. Scatchard analysis of the binding data revealed two distinct classes of binding sites for [125I]-recombinant human erythropoietin with dissociation constant of (Kd1) 1.9 x 10(-10) mol/l and (Kd2) 1.37 x 10(-8) mol/l respectively and binding capacity of (Bmax1) 12.3 fmol/10(6) cells and (Bmax2) 42.8 fmol/10(6) cells, respectively. GnRH, hCG, IGF-I and EGF did not induce any modification of recombinant human erythropoietin-specific binding. Recombinant human erythropoietin added to isolated adult rat Leydig cells exerted a stimulatory effect on testosterone production reaching its maximal effect at the dose of 10(-10) mol/l (testosterone production from 14.9 +/- 1.7 to 45.1 +/- 6.2 pmol/10(6) cells/3 h). Addition of anti-recombinant human erythropoietin serum completely blocked the recombinant human erythropoietin-stimulated testosterone production. These results show that purified adult rat Leydig cells possess recombinant human erythropoietin specific binding, and suggest that this glycoprotein directly influences rat Leydig steroidogenesis.     

Direct effect of arachidonic acid on protein kinase C and LH-stimulated steroidogenesis in rat Leydig cells; evidence for tonic inhibitory control of steroidogenesis by protein kinase C.

The role of arachidonic acid in the regulation of steroidogenesis in rat Leydig cells was studied. A dose- and time-dependent biphasic effect on maximal and submaximal LH- and dibutyryl-cAMP-stimulated testosterone production was found. The locus of the inhibition, which occurred during 3 h incubation, was prior to the side chain cleavage of cholesterol and after cAMP production. The same inhibitory effect was found with the protein kinase C (PKC) activators, phorbol-12-myristate, 13-acetate (PMA) and oleic acid, also with no change in LH-stimulated cAMP production. Arachidonic acid, PMA, and diolein, all stimulated PKC activity in a dose-dependent fashion in partially purified Leydig cell homogenates. When the cells were incubated for 5 h, arachidonic acid potentiated LH- and dibutyryl-cAMP-stimulated testosterone production. Similarly, incubation with PMA for 5 h, potentiated subsequent basal and dibutyryl-cAMP-stimulated testosterone production. PKC was down-regulated over 5 h (but not during 3 h) by pretreating Leydig cells with PMA or arachidonic acid in the presence of LH. Lipoxygenase and cyclooxygenase inhibitors did not alter the stimulatory effects of arachidonic acid. We conclude that the short-term inhibitory effect of arachidonic acid (and PMA) is via activation of PKC, but when protein kinase C (PKC) is down-regulated by these ligands, steroidogenesis is enhanced. These results suggest that steroidogenesis is normally under tonic inhibitory control by PKC.