Testosterone

About: Testosterone is a research topic. Over the lifetime, 23258 publications have been published within this topic receiving 808079 citations. The topic is also known as: 4-androsten-17beta-ol-3-one & 4-Androsten-3-one-17b-ol.

Age-Related Decreased Leydig Cell Testosterone Production in the Brown Norway Rat

Abstract: Previous studies have demonstrated that Leydig cell testosterone production diminishes with age in Brown Norway rats. The objective of the studies presented herein was to test the following possible explanations for age-related decline in steroidogenesis: (1) decline in Leydig cell number; (2) understimulation by luteinizing hormone (LH); (3) reduced ability of individual Leydig cells to produce testosterone; and (4) influence of loss of germ cells. Leydig cells isolated from the testes of young and aged rats by centrifugal elutriation and Percoll density gradient centrifugation were examined for their ability to produce testosterone when stimulated maximally with LH or with dibutyryl cyclic AMP (dbcAMP). Leydig cell number and volume were examined in situ using stereological methods. Serum LH levels were measured using a highly sensitive immunofluorometric assay. Average Leydig cell volume decreased with age, and consistent with this observation, individual Leydig cells isolated from aging rats produced significantly less testosterone than those from young rats whether the cells were cultured in vitro with maximally stimulating LH or with dbcAMP. The age-associated diminished testosterone production could not be explained by changes in Leydig cell number, serum LH levels, Leydig cell responsiveness to LH, or testicular germ cell content. These results, taken together, suggest that the reduced testosterone production seen in aged rats is related to defects in the steroidogenic pathway beyond the LH receptor-cAMP cascade. The nature of the initial age-related changes that cause reduced steroidogenesis is not known, and therefore it is not known whether such changes are intrinsic or extrinsic to the Leydig cells.

Suppression of androgen action and the induction of gross abnormalities of the reproductive tract in male rats treated neonatally with diethylstilbestrol.

Abstract: This study evaluated whether androgen action is altered in rats treated neonatally with diethylstilbestrol (DES) at a dose that induced reproductive tract abnormalities. Rats were treated on alternate days 2-12 with 10 microg DES and studied on Day 18. DES-induced abnormalities included a 70% reduction in testis weight, distension and overgrowth of the rete, distension and reduction in epithelial height of the efferent ducts, underdevelopment of the epididymal duct epithelium, reduction in epithelial height in the vas deferens, and convolution of the extra-epididymal vas. In DES-treated rats, androgen receptor (AR) immunoexpression was virtually absent from all affected tissues and the testis, whereas AR expression in controls was intense in epithelial and stromal cells. The DES-induced change in AR immunoexpression was confirmed by Western analysis for the testis. In rats treated neonatally with 1 microg DES, reproductive abnormalities were absent or minor, except for a 38% reduction in testis weight; loss of AR immunoexpression also did not occur in these rats. Treatment-induced changes in AR expression were paralleled by changes in Leydig cell volume per testis (91% reduction in the 10-microg DES group; no change in the 1-microg DES group). To test whether suppression of androgen production or action alone could induce comparable reproductive abnormalities to 10 microg DES, rats were treated neonatally with either a potent gonadotropin-releasing hormone antagonist (GnRHa) or with flutamide (50 mg/kg/day). These treatments reduced testis weight (68% for GnRHa, 40% for flutamide), and generally retarded development of the reproductive tract but failed to induce the abnormalities induced by 10 microg DES. GnRHa and flutamide caused no detectable change in AR immunoexpression in target tissues, with the exception of minor changes in the testes of flutamide-treated males. GnRHa treatment caused a reduction (83%) in Leydig cell volume comparable to that caused by 10 microg DES. Immunoexpression of estrogen receptor alpha (ER alpha) in the efferent ducts and of ER beta in all tissues studied were unaffected by any of the above treatments. Neonatal coadministration of testosterone esters (TE; 200 microg) with 10 microg DES prevented most of the morphological abnormalities induced by 10 microg DES treatment alone, though testis weight was still subnormal (46% reduction in DES + TE vs 72% in DES alone and 49% with TE alone) and some lumenal distension was still evident in the efferent ducts. Coadministration of TE with DES prevented DES-induced loss of AR immunoexpression (confirmed for testis by Western blot analysis). It is concluded that 1) reproductive tract abnormalities induced in the neonatal male rat by a high (10 microg) dose of DES are associated with reduced AR expression and Leydig cell volume; 2) these changes are largely absent with a lower dose of DES (1 microg); 3) treatments that interfere with androgen production (GnRHa) or action (flutamide) alone failed to induce reproductive tract abnormalities or alter AR expression as did 10 microg DES; 4) a grossly altered androgen:estrogen balance (low androgen + high estrogen) may underlie the reproductive tract abnormalities, other than reduced testis weight, induced by high doses of DES.

Neuroendocrine response to estrogen and sexual orientation

Abstract: A neuroendocrine component, the positive estrogen feedback effect, thought to be related to sexual orientation and, indirectly, to sexual differentiation, was evaluated in healthy, noninstitutionalized research volunteers. Men and women with a lifelong heterosexual orientation and men with a lifelong homosexual orientation were administered an estrogen preparation known to enhance the concentration of luteinizing hormone in women but not in men. The secretory pattern of luteinizing hormone in the homosexuals in response to estrogen was intermediate between that of the heterosexual men and that of the women. Furthermore, testosterone was depressed for a significantly longer period in the homosexual men than in the heterosexual men. These findings suggest that biological markers for sexual orientation may exist.

Ethylene dimethanesulfonate destroys Leydig cells in the rat testis.

Abstract: Ultrastructural changes in the interstitial cells of the adult rat testis were studied up to 45 days after administration of a single dose (100 mg/kg) of the antifertility compound ethylene dimethanesulfonate (EDS). Most Leydig cells showed degenerative changes 12 h after treatment. Twenty-four and 48 h after injection, all Leydig cells observed showed gross degenerative changes. At 4 and 14 days, intact Leydig cells could not be identified in the interstitial spaces. Twenty-one days after treatment with EDS, small Leydig cells were visible, and at 45 days, Leydig cells appeared normal. The seminiferous epithelium appeared morphologically normal until 4 days after injection of EDS, when slight abnormalities were observed. At 14 and 21 days, the seminiferous epithelium was grossly abnormal, but at 48 days, spermatogenesis appeared normal. Twelve, 24, and 48 h after treatment, large quantities of material, presumably from dead Leydig cells, were observed within the macrophage cytoplasm. The predominant cell in the interstitial space 4 and 14 days after EDS was the macrophage. Inclusions from the dead Leydig cells within the cytoplasm of the macrophages had almost disappeared. LH receptors (hCG binding) in testicular homogenates were consistent with the cytological changes in Leydig cells. Receptor concentration was low at 24 h and was almost zero at 4 days. This change was accompanied by a decrease in serum testosterone to castrate levels by 2 days. The responses of the endocrine system to destruction of the Leydig cell by EDS, as monitored by serum FSH, LH, and testosterone, were slower than those after castration, indicating that the response to EDS reflects the time required to kill the Leydig cell rather than direct impairment of the steroidogenic pathway. These experiments demonstrate that Leydig cells can be specifically destroyed by a cytotoxic drug. The availability of a specific cytotoxic agent for Leydig cells offers further opportunities to study the interrelationships between the Leydig cell and the seminiferous tubule.