Effects and interactions of LH and LHRH agonist on testicular morphology and function in hypophysectomized rats

The effects of single or combined daily treatment with an LHRH agonist and low or high doses of LH upon the testes of adult hypophysectomized rats were studied for up to 2 weeks in which changes in testicular histology, particularly the interstitial tissue, were examined by morphometry and related to functional assessment of the Leydig cells in vivo and in vitro. Compared to saline-treated controls, LHRH agonist treatment did not alter testis volume or the composition of the seminiferous epithelium or any of the interstitial tissue components although serum testosterone and in-vitro testosterone production by isolated Leydig cells were significantly reduced. With 2 micrograms LH for treatment, testis volume was increased, spermatogenesis was qualitatively normal, total Leydig cell volume was increased, serum testosterone values were initially elevated but subsequently declined and in-vitro testosterone production was enhanced. Testis volume with 20 micrograms LH treatment was unchanged compared to saline treatment, the seminiferous epithelium exhibited severe disruption but total Leydig cell volume was greatly increased due to interstitial cell hyperplasia. This group showed elevated serum testosterone concentrations and major increases in testosterone production in vitro. Treatment with LHRH agonist with either dose of LH resulted in reduced testis volume, moderate to very severe focal spermatogenic disruption and increased total Leydig cell volume although serum testosterone values and in-vitro testosterone production were markedly reduced compared to control rats. It is concluded that, in the absence of the pituitary, LHRH agonist fails to disrupt spermatogenesis and the previously described antitesticular action of LHRH agonists in intact rats is therefore dependent upon the presence of LH, which alone or in combination with LHRH agonist, may focally disrupt spermatogenesis in hypophysectomized rats whereas the Leydig cells undergo hyperplasia. The findings show that impairment of spermatogenesis is accompanied by alterations of the interstitial tissue and suggest that communication between these two compartments is involved in the regulation of testicular function.     

The interaction of hCG, hydroxysteroids and interstitial fluid on rat Leydig cell steroidogenesis in vitro

Rat testicular interstitial fluid and hydroxycholesterol both stimulated testosterone production by isolated Leydig cells in vitro in a dose-dependent manner, but the dose-response lines were not parallel. The addition of cycloheximide blocked the stimulation by interstitial fluid but not that of hydroxycholesterol. Use of the compounds SU 10603 and cyanoketone (which inhibit 3 beta-hydroxysteroid dehydrogenase and 17 alpha-hydroxylase respectively) or aminoglutethimide (which acts on the cholesterol side-chain cleavage enzyme) showed that the stimulatory factor(s) in interstitial fluid stimulated steroidogenesis at the cholesterol side-chain cleavage enzyme, before the conversion of pregnenolone. This enzyme is rate-limiting in the synthesis of testosterone by Leydig cells and a site of action of LH; therefore, these results support the view that an interstitial fluid factor may be involved in the paracrine regulation of testicular steroidogenesis.     

Response of interstitial cells of the testes in the house musk shrew, Suncus murinus L., to various gonadotropins

Testicular interstitial cells of the house musk shrew culture in vitro released testosterone in response to ovine LH with a quite similar dose response relationship to that found in the cells of rats. The dose response curves suggested that a single testicular cell of the shrew has the same potency to secrete testosterone as that of the rat. In the shrew as well as in the rat, neither ovine PRL added alone nor together with oLH could stimulate the testosterone release from testicular cells, although a very limited enhancement of testosterone secretion was observed in the cell cultured with a large dose of oFSH in both species.     

Hormonal regulation of testicular prolactin receptors and testosterone synthesis in golden hamsters

A study was conducted with hypophysectomized hamsters to determine effects of administration of prolactin (PRL), luteinizing hormone (LH), and follicle-stimulating hormone (FSH)-alone or in combination-on testicular PRL receptors and in vitro testosterone production. Hormonal injections commenced the second day after hypophysectomy, and hamsters were killed on Day 5, approximately 13 h after the last hormonal injection. PRL receptor numbers were reduced by hypophysectomy, and PRL administration alone lessened the extent of this decrease. By themselves, neither LH nor FSH affected PRL receptors, but a combination of PRL + FSH + LH produced the greatest effect on these receptors. Receptor affinity was only modestly affected by any treatments. In vitro testosterone synthesis was measured after addition of 0, 2, 10, and 50 mIU of human chorionic gonadotropin (hCG) to incubations of testicular tissue. Neither PRL nor FSH by themselves in vivo affected basal or hCG-stimulated testosterone production. However, PRL + FSH increased (p less than 0.05) the magnitude of the in vitro testosterone response to hCG, as well as the sensitivity of that response (slope of the dose-response curve). LH alone increased both basal and hCG-stimulated testosterone production. PRL + LH provided no additional increase in the magnitude of the testosterone response, but increased (p less than 0.05) the sensitivity. PRL + FSH + LH in vivo provided for the greatest sensitivity of the testosterone response to hCG.(ABSTRACT TRUNCATED AT 250 WORDS)     

Melatonin: Failure of pharmacological doses to induce testicular atrophy in the male golden hamster

Effects of graded doses of melatonin on reproductive function of the male golden hamster were studied. Daily injections of melatonin at 17:00 h brought about complete testicular regression when the hamster received 10, 25, and 100 ug melatonin; larger doses of 1,000 ug or 2,500 ug had a partial or no effect on testicular or accessory sex organ weights. The dose response relationship of testicular and accessory sex organ weights to melatonin treatment somewhat resembled an inverted bell-shaped curve. Plasma, LH and prolactin concentrations followed the pattern of the testicular and accessory sex organ weights; small doses of melatonin suppressed plasma, LH and prolactin while larger doses had no suppressive effects. These results indicate that melatonin can exert a reproductive inhibitory effect if injected with small, but not with larger doses.     

Significant steroidogenic activity of luteinizing hormone is maintained after enzymatic removal of oligosaccharides

Several reports have described the destruction of the N-linked oligosaccharides on glycoprotein hormones by hydrogen fluoride treatment and have noted the accompanying marked reduction, or complete loss, in biological activity. This has led to the concept that the oligosaccharides have an obligatory role in glycoprotein hormone steroidogenic function. Using a less radical and more complete method for removing sugar units, endoglycosidase treatment and ovine LH (oLH) and human LH (hLH) as examples, we examined the role of oligosaccharides in hormone function. Ovine LH and hLH were digested with endoglycosidase F. After treatment cleavage of oligosaccharides was demonstrated by compositional studies, greater than 87% cleavage was demonstrated and only N-acetylglucosamine or N-acetylglucosamine-Fucose shown to remain attached to the peptide, by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (appropriate size change) and by chromatofocusing (appearance of a single basic peak). Biological activities and relative potencies of preparations were then assessed in an in vitro assay, in which the ability of samples to promote testosterone production by testicular interstitial cells was measured. Although endoglycosidase F treatment reduced relative potencies 2- to 3-fold in the bioassay, (possibly in part due to subunit dissociation) it did not lessen abilities to induce maximal testosterone response (that of native hLH and oLH). These findings contrast with those obtained from hydrogen fluoride studies and indicate that the oligosaccharides, per se, do not play an obligatory role in the steroidogenic activity of LH.     

Role of testicular interstitial macrophages in regulating testosterone release in hyperprolactinemia

Hyperprolactinemia-induced hypogonadism has been linked to a dysfunction of the hypothalamus-pituitary-testis axis. The direct inhibitory effects of prolactin on the testicular release of testosterone have also been demonstrated, though their mechanisms remain unclear. Incubation of rat testicular interstitial cells (TICs) with prolactin stimulated the release of testosterone. TICs from rats with anterior pituitary-grafting-induced hyperprolactinemia release lower amounts of testosterone than controls. However, Leydig cells isolated from anterior pituitary-grafted rats release a greater amount of testosterone. These paradoxical observations have remained unexplained. This study examined the roles of testicular interstitial macrophages and of their product, tumor necrosis factor-alpha (TNF-alpha), in regulating Leydig cells under condition of hyperprolactinemia. Hyperprolactinemia was induced by grafting two anterior pituitary glands of rats under the renal capsule. Control animals were grafted with rat cortex tissue. The rats were sacrificed 6 weeks later. TICs and macrophages, and Leydig cells were isolated for in vitro incubation and drugs challenge. Testosterone released by testicular interstitial or Leydig cells was measured by radioimmunoassay. TNF-alpha concentration in the medium of TICs or macrophages was measured by enzyme-linked immunosorbent assay (ELISA). A dose-dependent stimulation of TNF-alpha secretion in the medium of TICs or macrophages by the prolactin challenge was observed. Higher amounts of TNF-alpha were released by TICs in the anterior pituitary-grafted rats than in the control group. In contrast, the release of TNF-alpha by testicular interstitial macrophages isolated from the anterior pituitary- and cortex-grafted groups was quantitatively similar. Challenge with human chorionic gonadotropin did not modify the TNF-alpha release by testicular interstitial macrophages in either group. Challenge of Leydig cells with TNF-alpha inhibited their release of testosterone stimulated by human chorionic gonadotropin, but not their basal testosterone release. These different patterns of testosterone release in TICs versus Leydig cells cultures in anterior pituitary-grafted rats may be due to the influence of testicular interstitial macrophages. These observations correlate with in vivo conditions, where prolactin increases the release of TNF-alpha by testicular interstitial macrophages, which, in turn, decreases the human chorionic gonadotropin-stimulated release of testosterone by Leydig cells. In summary, hyperprolactinemia-induced hypogonadism involves a mechanism of prolactin-originated, macrophage-mediated inhibitory regulation of testosterone release by Leydig cells. TNF-alpha, one of the cytokines secreted by macrophages, may play a key role in this mechanism.     

醋酸棉酚对大鼠睾丸HCG反应性及其受体功能的影响

给大鼠灌服醋酸棉酚30 mg/kg/d,每周6次,持续4周。给药2周后,血浆睾酮水平显著下降并持续至第4周,同时间质细胞呈萎缩性改变。醋酸棉酚明显抑制成年大鼠对HCG反应性,使睾丸LH/HCG受体亲和力下降,受体数目略有减少。结果提示,醋酸棉酚抑制大鼠睾丸酮的产生及降低成年大鼠睾丸对HCG的反应性,推测其机制是由于醋酸棉酚干扰了睾丸HCG受体功能而造成的。     

Direct effects of propylthiouracil on testosterone production in monkeys

Propylthiouracil (PTU) is an anti-thyroid drug. However, the direct effects of PTU on the endocrine functions of non-thyroid glands are unclear. In the present study, we examined the acute effects of PTU on testosterone secretion in monkeys. Male monkeys were infused intravenously with PTU for 30 min. Blood samples were collected at several time intervals. Monkey testicular interstitial cells were cultured with PTU, human chorionic gonadotropin (hCG), or forskolin, at 34 degrees C for 1 h. In another study, steroidogenesis in monkey testicular interstitial cells were examined. PTU decreased plasma testosterone but not plasma thyroxine (T4) and luteinizing hormone (LH) levels in monkeys. Administration of PTU resulted in a dose-dependent inhibition of basal and hCG-, as well as forskolin-stimulated testosterone release by monkey testicular interstitial cells. PTU also diminished the stimulatory effects induced by androstenedione. These results suggest that PTU inhibits testosterone secretion via a mechanism independent of the secretion of T4 and LH in primates. The inhibitory mechanism of PTU on testosterone production involves a decreased activity of 17beta-hydroxysteroid dehydrogenase (17beta-HSD) and post-cAMP pathways.     

Regulation of thyroid hormones on the production of testosterone in rats

The effects of a thyroidectomy and thyroxine (T4) replacement on the spontaneous and human chorionic gonadotropin (hCG)-stimulated secretion of testosterone and the production of adenosine 3',5'-cyclic monophosphate (cAMP) in rat testes were studied. Thyroidectomy decreased the basal levels of plasma luteinizing hormone (LH) and testosterone, which delayed the maximal response of testosterone to gonadotropin-releasing hormone (GnRH) and hCG in male rats. T4 replacement in thyroparathyroidectomized (Tx) rats restored the concentrations of plasma LH and testosterone to euthyroid levels. Thyroidectomy decreased the basal release of hypothalamic GnRH, pituitary LH, and testicular testosterone as well as the LH response to GnRH and testosterone response to hCG in vitro. T4 replacement in Tx rats restored the in vitro release of GnRH, GnRH-stimulated LH release as well as hCG-stimulated testosterone release. Administration of T4 in vitro restored the release of testosterone by rat testicular interstitial cells (TICs). The increase of testosterone release in response to forskolin and androstenedione was less in TICs from Tx rats than in that from sham Tx rats. Administration of nifedipine in vitro resulted in a decrease of testosterone release by TICs from sham Tx but not from Tx rats. The basal level of cAMP in TICs was decreased by thyroidectomy. The increased accumulation of cAMP in TICs following administration of forskolin was eliminated in Tx rats. T4 replacement in Tx restored the testosterone response to forskolin. But the testosterone response to androstenedione and the cAMP response to forskolin in TICs was not restored by T4 in Tx rats. These results suggest that the inhibitory effect of a thyroidectomy on the production of testosterone in rat TICs is in part due to: 1) the decreased basal secretion of pituitary LH and its response to GnRH; 2) the decreased response of TICs to gonadotropin; and 3) the diminished production of cAMP, influx of calcium, and activity of 17beta-HSD. T4 may enhance testosterone production by acting directly at the testicular interstitial cells of Tx rats.     

Effects of restraint stress on plasma LH and testosterone concentrations, Leydig cell LH/hCG receptors, and in vitro testicular steroidogenesis in adult rats

We examined the effect of restraint stress (3 hr) on plasma LH and testosterone levels, on the Leydig cell LH/hCG receptor, and on the activity of enzymes in the testicular steroidogenic pathway of the adult rat. Restraint stress caused a 47% reduction in plasma testosterone concentrations, but had no effect on plasma LH levels. The binding capacity and affinity of Leydig cell LH/hCG receptors were not affected by restraint. Stress did not affect the testicular activity of 20,22 desmolase or 3 beta-hydroxysteroid dehydrogenase, but testicular interstitial cells of stressed rats incubated in vitro with progesterone as a substrate produced more 17 alpha-hydroxyprogesterone but less testosterone than control cells, and when incubated with 17 alpha-hydroxypregnenolone, produced 39% less androstenedione and 40% less testosterone than control cells. These results suggest that restraint stress inhibited 17,20 desmolase but not 17 alpha-hydroxylase activity. When the delta 4 pathway was blocked with cyanoketone (3 beta-HSD inhibitor), stress did not alter the production of pregnenolone or 17 alpha-hydroxypregnenolone, but the production of dehydroepiandrosterone by cells from stressed rats was subnormal, suggesting again a reduction of 17,20 desmolase activity. The data suggest that a major site of the inhibitory action of restraint stress on testicular steroidogenesis is the 17,20 desmolase step. The disruption of androgen production by restraint appears to be LH independent since stress did not affect plasma LH levels, the binding capacity or affinity of LH/hCG receptors, or the activity of 20,22 desmolase.     

Nitric oxide control of steroidogenesis: endocrine effects of NG-nitro-L-arginine and comparisons to alcohol.

Recent studies suggest that nitric oxide (NO) may regulate hormone biosynthesis and secretion. This was tested by treating male rats with NG-nitro-L-arginine methyl ester (NAME), a NO synthase inhibitor, and measuring serum and testicular interstitial fluid testosterone and serum corticosterone, luteinizing hormone (LH), and prolactin (PRL). The effect of NG-nitro-L-arginine (NA), a less-soluble form of the same NO synthase inhibitor, on the reproductive suppressant actions of alcohol was also examined. NAME increased testosterone and corticosterone secretion dose-dependently without affecting LH and PRL secretion. The alcohol-induced suppression of testosterone or LH secretion was not altered by treatment with NA. Although effects of NAME and NA on other systems may be involved, these results indicate that testicular and adrenal steroidogenesis are negatively regulated by endogenous NO and that NO does not regulate LH and PRL secretion or inhibit the testicular steroidogenic pathway in the same way as alcohol.     

Hormonal regulation of testicular human chorionic gonadotropin binding and steroidogenesis in adult mice with different forms of hereditary diabetes and obesity

The regulation of testicular hCG binding and steroidogenesis in adult mutant mice with hereditary diabetes and obesity was studied. Low doses of hCG caused no change in hCG binding in obese (ob/ob) mice, whereas, in diabetic (db/db) mice, the increase in binding measured 24 h after hCG administration was not as great as in normal males. Intermediate doses of hCG caused a decrease in hCG binding in obese and normal mice, but not in diabetic animals. However, 72 h after injection of intermediate doses of hCG, a decrease in hCG binding also was observed in diabetic mice. Plasma testosterone was elevated 24 h after hCG injection in all types of mice studied, but the increase in diabetic mice was smaller than in normal animals. However, 72 h after treatment with hCG, plasma testosterone was still elevated in diabetic mice, but not in normal males. In vitro, hCG stimulated testicular testosterone synthesis in all groups of mice, but the observed increase was smaller in diabetic and obese than in normal animals. Plasma LH levels were higher in diabetic than in normal mice, whereas plasma FSH and prolactin levels were lower in obese mice than in normal animals. All parameters (i.e., LH receptors and circulating hormone levels) measured in yellow (Ay/a) mice were similar to those in normal (a/a) mice. The present study indicates that in these models for noninsulin-dependent diabetes, the testicular metabolism of LH receptors and capacity to secrete steroids is altered.     

Effect of cyclosporin treatment on luteinizing hormone and prolactin.

The effect of cyclosporin A (CsA) treatment on LH and prolactin was investigated. Chronic daily administration of an immunosuppressive dose of CsA (1.5 mg/100g bw) increased serum LH concentrations and pituitary gland LH content. CsA treatment also resulted in increased serum testosterone. Immunosuppressive doses of CsA had no effect on serum prolactin or pituitary gland prolactin content. Acute administration of low doses of 0.12, 1.2, 12 and 120ug CsA/100g bw had no effect on serum LH or prolactin. These results suggest that administration of immunosuppressive doses of CsA alters serum and pituitary LH and serum testosterone but not prolactin.     

Testosterone directly induces progesterone production and interacts with physiological concentrations of LH to increase granulosa cell progesterone production in laying hens (Gallus domesticus)

Blocking testosterone action with immunization or with a specific antagonist blocks the preovulatory surge of progesterone and ovulation in laying hens. Thus, testosterone may stimulate progesterone production in a paracrine fashion within the ovary. To test this hypothesis, we evaluated the effects of testosterone and its interaction with LH on the production of progesterone by granulosa cells in culture. Hen granulosa cells obtained from preovulatory follicles were cultured in 96 well plates. The effects of testosterone (0-100ng/ml) and/or LH (0-100ng/ml) were evaluated. LH-stimulated progesterone production in a dose response manner up to 10ng/ml (p<0.01). Testosterone, up to 10ng/ml, increased progesterone production in a dose response manner in the absence of LH and at all doses of LH up to 1ng/ml (p<0.001). However, at supraphysiological concentrations of LH (10 and 100ng/ml) there was no further increase in progesterone production caused by testosterone (p>0.05). Finally, the addition of 2-hydroxyflutamide (0-1000mug/ml) to hen granulosa cells cultured with 10ng/ml of testosterone reduced progesterone production in a dose response manner (p<0.001). In conclusion, testosterone stimulates progesterone production in preovulatory follicle granulosa cells and interacts with physiological concentrations of LH to increase progesterone production. In addition, testosterone stimulation on granulosa cells is specific since the testosterone antagonist decreased testosterone stimulatory action.     

Chronic corticosterone treatment impairs Leydig cell 11beta-hydroxysteroid dehydrogenase activity and LH-stimulated testosterone production.

The effects of excess corticosterone on luteinizing hormone (LH)-stimulated Leydig cell testosterone production and activity of 11beta-HSD was studied. Adult male rats (200-250 g body weight) were treated with corticosterone-21-acetate (2 mg/100 g body weight, i.m., twice daily) for 15 days. Another set of rats was treated with corticosterone (dose as above) plus LH (ovine LH 100 microg/kg body weight, s.c., daily) for 15 days. Corticosterone administration significantly increased serum and testicular interstitial fluid (TIF) corticosterone but decreased testosterone levels. Administration of LH with corticosterone partially prevented the decrease in serum and TIF testosterone. The oxidative activity of 11beta-hydroxysteroid dehydrogenase (11beta-HSD) was significantly decreased in Leydig cells of rats treated with corticosterone alone and in combination with LH. The direct effect of corticosterone on Leydig cell steroidogenic potency was also studied in vitro. Addition of corticosterone to Leydig cell culture showed a dose dependent effect on LH-stimulated testosterone production. Corticosterone at 50 and 100 ng/ml did not alter LH-stimulated testosterone production, but at high doses (200-400 ng/ml), decreased basal and LH-stimulated testosterone production. Basal and LH-stimulated cAMP production was not altered by corticosterone in vitro. It is concluded from the present study that elevated levels of corticosterone decreased the oxidative activity of 11beta-HSD and thus resulting in impaired Leydig cell steroidogenesis and the inhibitory effects of corticosterone on testosterone production appear to be mediated through inhibition of LH signal transduction at post-cAMP level.     

Temporal changes in rat Leydig cell function after the induction of bilateral cryptorchidism

Adult rats were made bilaterally cryptorchid and studied at intervals of 3, 7, 14 or 21 days to study temporal changes in Leydig cell function. Serum FSH and LH levels were measured and the cross-sectional area of the Leydig cells assessed by morphometry. The function of the Leydig cells was judged by the binding of 125I-labelled hCG to testicular tissue in vitro and the testosterone response of the testis to hCG stimulation in vitro. By 3 days after cryptorchidism, the binding of labelled hCG to testicular tissue was significantly decreased compared to that of controls, but the testes were able to respond to hCG stimulation in vitro. At 7, 14 and 21 days after cryptorchidism, an enhanced testosterone response was observed and the size of the Leydig cells was significantly greater than that of the controls, which indicated increased secretory activity by the cryptorchid testis. Although serum FSH levels were significantly elevated after 3 days of cryptorchidism, serum LH levels did not rise until 7 days, thereby suggesting that the loss of receptors is unlikely to result from down-regulation by LH. The reduced testosterone response of the cryptorchid testis in vivo to low doses of hCG and the enhanced response at high doses are probably related to the reduced blood flow to the cryptorchid testis and the decreased sensitivity of the Leydig cells induced by LH/hCG receptor loss.     

Bisphenol A inhibits testicular functions and increases luteinizing hormone secretion in adult male rats

Effects of a xenobiotic estrogen, bisphenol A (BPA), on reproductive functions were investigated using adult male rats. BPA was dissolved into sesame oil and injected s.c. every day (1 mg/rat) for 14 days. Animals were killed by decapitation after the final administration of BPA, and the trunk blood, pituitary, and testes were collected. Plasma concentrations of prolactin were dramatically increased and pituitary contents of prolactin were slightly increased in the BPA group compared to the control group. Plasma concentrations of testosterone were decreased and plasma concentrations of LH were increased in BPA-treated rats compared to control rats. Testicular contents of inhibin were decreased in BPA-treated rats compared to control rats, although plasma concentrations of inhibin were not changed after administration of BPA. The testicular response to hCG for progesterone and testosterone release was decreased in BPA-treated rats. Administration of BPA did not change the pituitary response to luteinizing hormone-releasing hormone (LH-RH) in castrated male rats treated with testosterone. Male sexual behavior also was not changed as a result of BPA treatment. These results suggest that BPA directly inhibits testicular functions and the increased level of plasma LH is probably due to a reduction in the negative feedback regulation by testosterone. The testis is probably a more sensitive site for BPA action than the hypothalamus-pituitary axis.     

3',5'-cyclic adenosine monophosphate as an intracellular second messenger of luteinizing hormone: application of the forskolin criteria

The role of adenosine 3',5'-cyclic monophosphate (cAMP) as an intracellular second messenger of luteinizing hormone (LH) was reinvestigated in vitro with diterpene forskolin, a highly specific activator of adenylate cyclase. Treatment of cultured testicular cells from adult hypophysectomized rats with increasing concentrations (10(7)-10(-4) M) of forskolin produced dose-dependent increments in cAMP and testosterone accumulation. Concomitant blockade of cAMP-phosphodiesterase activity with 3-isobutyl-1-methyl-xanthine (10(-4) M) resulted in significant (P less than 0.05) enhancement of the forskolin effect for all but the 10(-4) M forskolin dose. Potency evaluation as judged by half-maximal stimulation of testosterone accumulation revealed median effective doses (mean +/- SE) of 1.25 +/- 0.2 x 10(-5), 1.7 +/- 0.5 x 10(-5), and 2.5 +/- 0.4 x 10(-10) M for forskolin, N6, O2'-dibutyryl cAMP (Bt2cAMP), and human chorionic gonadotropin (hCG), respectively. Examination of the time requirements of forskolin disclosed time-dependent increments in the accumulation of extracellular cAMP and testosterone, the earliest significant (P less than 0.05) increases being noted by 6 hr of treatment. In comparison, a minimal time requirement of less than or equal to 12 hr was noted for hCG- and choleragen-stimulated androgen biosynthesis, whereas the apparent onset of action of Bt2cAMP was delayed to the 24-hr time point. Although 10(-7) M of forskolin by itself did not alter the accumulation of testosterone, its addition resulted in substantial amplification of the hCG effect, producing a 4.6-fold reduction in the median effective dose (ED50) of hCG. Moreover, concurrent treatment with this functionally inert dose of forskolin rendered steroidogenically inert doses of hCG (eg, 10(-11) or 3 x 10(-11) M) steroidogenically potent. However, combined treatment with maximally stimulatory doses of Bt2cAMP (10(-4) M) and one of several testicular cell agonists [forskolin (10(-4) M), choleragen (10(-9) M) or hCG (10(-9) M)] did not prove additive. Taken together, our findings indicate that forskolin, like LH, is capable of stimulating testicular cAMP generation as well as androgen biosynthesis and that a functionally inert low dose of forskolin can significantly amplify LH hormonal action. Inasmuch as forskolin-stimulated and forskolin-amplified hormonal action are acceptable as novel criteria of cAMP dependence, our observations provide new evidence in keeping with the notion that cAMP may be in intracellular second messenger of LH.     

Role of glucocorticoids in the stress-induced suppression of testicular steroidogenesis in adult male rats.

We have examined the role of glucocorticoids in the stress-induced inhibition of testicular steroidogenesis. Immobilization (3 hr) reduced plasma testosterone (T) levels to 24% of control values but did not affect plasma LH levels. This reduction was partially reversed by in vivo injections of the antiglucocorticoid, RU486, prior to the stress session at a dose of 10 mg/kg BW, but not at 1.0 or 50 mg/kg BW. Stressed rats that were treated with 10 mg/kg BW RU486 had twofold higher plasma T levels than vehicle-treated stressed animals. Injections of RU486 did not affect plasma LH levels in control or stressed rats and did not affect T levels of unstressed rats. Stressed rats had eightfold higher plasma corticosterone levels than controls, and RU486 had no effect on control or stress levels of corticosterone. The possible role of glucocorticoids in mediating the effect of stress on testicular T production was investigated also in vitro by incubating testicular interstitial cells from unstressed rats for 3 hr with corticosterone (0, 0.01, 0.1, or 1.0 microM) or dexamethasone (0, 0.001, 0.01, or 0.1 microM), followed by an additional 2 hr with hCG (0, 25, 50, or 100 microIU). Both corticosterone and dexamethasone inhibited hCG-stimulated T production in a dose-dependent manner. Cells incubated with the highest concentration of either of the glucocorticoids showed significantly reduced responses to hCG stimulation. In the absence of hCG, in vitro T production was not affected by dexamethasone or 0.01 and 0.1 microM corticosterone. However, the highest dose of corticosterone (1.0 microM) produced a 63% elevation in basal T production. Coincubation of testicular interstitial cells with corticosterone (1.0 microM) or dexamethasone (0.1 microM) and RU486 (0.01, 0.1, and 1.0 microM) reversed the glucocorticoid-induced suppressions of T production in a dose-dependent manner. Our results suggest that during stress increases in plasma levels of glucocorticoids in male rats act via glucocorticoid receptors on testicular interstitial cells to suppress the testicular response to gonadotropins, and that the decline of testosterone production during immobilization stress is in part mediated by a direct action of glucocorticoids on the testis.