Ketanserin, an antagonist of 5-HT2A receptor of serotonin, inhibits testosterone secretion by rat Leydig cells in vitro.

The effect of ketanserin, an antagonist of 5-HT2A receptor of serotonin, added to the culture medium, on basal and LH-stimulated testosterone secretion was studied in primary cultures of adolescent rat Leydig cells. Ketanserin decreased the basal secretion of testosterone but showed an insignificant influence on the LH-stimulated process. It can be concluded that ketanserin may affect the testosterone-secreting cells by an indirect action at the vascular level as well as directly at the level of Leydig cells, at least in adolescent rats, leading to down-regulation of the basal testosterone secretion.     

Testosterone deficiency impairs glucose oxidation through defective insulin and its receptor gene expression in target tissues of adult male rats

Testosterone and insulin interact in their actions on target tissues. Most of the studies that address this issue have focused on the physiological concentration of testosterone, which maintains normal insulin sensitivity but has deleterious effects on the same when the concentration of testosterone is out of this range. However, molecular basis of the action of testosterone in the early step of insulin action is not known. The present study has been designed to assess the impact of testosterone on insulin receptor gene expression and glucose oxidation in target tissues of adult male rat. Adult male albino rats were orchidectomized and supplemented with testosterone (100 microg/100 g b. wt., twice daily) for 15 days from the 11th day of post orchidectomy. On the day after the last treatment, animals were euthanized and blood was collected for the assay of plasma glucose, serum testosterone and insulin. Skeletal muscles, such as gracilis and quadriceps, liver and adipose tissue were dissected out and used for the assay of various parameters such as insulin receptor concentration, insulin receptor mRNA level and glucose oxidation. Testosterone deprivation due to orchidectomy decreased serum insulin concentration. In addition to this, insulin receptor number and its mRNA level and glucose oxidation in target tissues were significantly decreased (p<0.05) when compared to control. However, testosterone replacement in orchidectomized rats restored all these parameters to control level. It is concluded from this study that testosterone deficiency-induced defective glucose oxidation in skeletal muscles, liver and adipose tissue is mediated through impaired expression of insulin and its receptor gene.     

The effects of cytochalasin B on the testosterone synthesis by interstitial cells of rat testis

The present study examined the effects of cytochalasin B on various steps in the luteinizing hormone (LH)-stimulated increase in testosterone synthesis by collagenase-dispersed interstitial cells of adult rat testis. Cytochalasin B at a concentration range of 0.1–50 μM inhibited the LH-stimulated increase in testosterone synthesis in a dose-dependent manner. Both intracellular and medium (released) testosterone levels were reduced, thus indicating that the decrease was not due to the accumulation of testosterone inside the cell as a result of cytochalasin B treatment. Cytochalasin B also inhibited the 8-bromocyclic AMP and pregnenolone-stimulated testosterone synthesis in a similar dose-dependent manner. Cytochalasin B at the two higher doses (10 and 50 μM) also inhibited the LH-stimulated generation of cyclic AMP by interstitial cells. However, this drug had no effect on basal testosterone synthesis except at the highest concentration added.Previous studies on adrenocorticotropic hormone (ACTH)- and LH-stimulated increase in glucocorticoid and testosterone synthesis in adrenal and Leydig cells, respectively, demonstrated that cytochalasin B or anti-actin inhibited the transport of cholesterol into mitochondria. The present studies suggest that cytochalasin B inhibits at least two additional steps in the LH-stimulated increase in testosterone synthesis: (1) the generation of cyclic AMP at the level of the plasma membrane, and (2) the conversion of pregnenolone to the testosterone at the level of the smooth endoplasmic reticulum. It remains to be established whether these are direct effects of cytochalasin B, or whether they are mediated by disruption of microfilaments by cytochalasin B.     

Influence of testosterone and/or luteinizing hormone releasing hormone analogue on precocious sexual development in the juvenile rainbow trout

The influence of testosterone, luteinizing hormone releasing hormone (LHRH) agonist and combinations of these hormones on gonadotropic hormone (GtH) levels in the sexually immature trout was investigated. Both the steroid and releasing hormone preparations, testosterone in Silastic capsules and cholesterol-pelleted LHRH-A, were formulated for sustained release and long-term biological action following a single hormone implantation. Marked increases in pituitary GtH followed testosterone and/or testosterone and LHRH analogue treatment combined, but the low pituitary GtH level in controls remained unchanged after LHRH analogue administration alone. Plasma GtH titers increased with time after testosterone treatment, indicating a positive steroid feedback effect by androgen on GtH in the juvenile rainbow trout. When combined with testosterone treatment, LHRH analogue augmented plasma GtH levels compared to fish receiving testosterone treatment alone. In males the elevated plasma GtH levels were associated with testes stimulation and onset of spermatogenesis; in females, however, no significant stimulation of the ovaries was observed. It can be concluded from these studies that the testosterone stimulus is sufficient to induce onset of sexual development in immature males but not females. Whereas LHRH analogue releases GtH from the testosterone-primed trout pituitary, LHRH treatment alone under these conditions fails to stimulate the juvenile trout reproductive system.     

The effects of the administration of testosterone propionate alone or with phenobarbitone and of testosterone metabolites to neonatal female rats

The effects of graded doses of testosterone propionate administered to female rats on Day 4 of postnatal life have been determined. The incidence of failure of ovulation as adults was related to the dose. With increasing dosage over the range 1–100 μg no significant evidence of a progressive decrease in immunoassayable luteinizing hormone concentration in the plasma or anterior pituitary was obtained. The reported protective action of sodium phenobarbitone when administered with testosterone propionate could not be confirmed. Single injections of 100 μg of testosterone, dihydrotestosterone, 5 α-androstanediol, or a combination of the two latter compounds had no masculinizing effect. When the 17-β propionate derivatives of these compounds were administered at the same dose level only testosterone propionate had a masculinizing effect.     

Effect of neonatal injections of estradiol, testosterone and cryproterone acetate on plasma and testicular testosterone and on the genital system in adult male mice]

On day old male mice received a single injection of oestradiol benzoate, testosterone propionate or cyproterone acetate in order to study their action on testicular development, particularly testosterone secretion. Oestrogenization of newborn males leads, when the animals mature, to a high proportion or cryptorchidism, to atrophy of testes and seminal vesicles, and inhibition of spermatogenesis. Testosterone levels were reduced in the plasma. Testosterone propionate produced moderate reduction of testicular weight but spermatogenesis was not impaired. Plasma testosterone level was reduced. Cyproterone acetate increased significantly testicular testosterone level.     

Testosterone and corticosterone co-regulate messenger RNA coding for secretory proteins in the epididymis of the lizard (Lacerta vivipara)

The hormonal requirements for the regulation of Lv132 mRNA coding for two proteins secreted by the principal cells of the lizard epididymis were examined by organotypic culture experiments. Testosterone, R1881 and corticosterone induced accumulation of Lv132 mRNA in explants from lizards castrated immediately after differentiation of the principal cells. The induction by testosterone was inhibited by the addition of cyproterone acetate. Progesterone and oestradiol alone or in presence of testosterone were ineffective. Unlike the induction by testosterone, the effect of corticosterone did not require binding on the androgen receptor as shown by competition binding studies. Corticosterone failed to induce gene expression in organs containing only reserve cells in their epithelium at the onset of the culture. However, corticosterone plus testosterone had a synergistic effect. These data suggest that testosterone promotes the differentiation of principal cells from reserve cells during the culture time and that a primary action of testosterone is necessary to confer corticosterone responsiveness on this tissue. Furthermore, the primary effects of testosterone could be memorized by the tissue because the corticosterone responsiveness persists after castration.     

Relationship between the release of hypophyseal LH under the influence of LRH and the plasma testosterone level in women]

There is a direct significant correlation (r = 0,49, p less than 0,01) between cumulative LH response to i.v. injection of 25 mug LRH and testosterone blood level in 17 women with an excess of endogenous androgens (plasmatic testosterone and/or urinary androsterone and etiocholanolone). The relation also exists if the patients are divided in two groups according to the origin of the dysfunction: polycystic ovaries (n = 9, r = 0,62, p less than 0.05) or hypercorticism (n = 8, r = 0,53, p less than 0.1). In the same patients there is no correlation between LH release and the sum of androsterone and etiocholanolone 24 hours urinary excretion (r = 0,21, p: NS); there is no correlation between basal testosterone blood levels and urinary metabolites (r = 0,19, p: NS). Our data suggest that testosterone (or a closely related metabolite) acts at the hypophyseal level to inhibit the spontaneous LH discharge hence increasing the pituitary hormonal stores. This action could be responsible for menstrual abnormalities often found in hirsut women.     

Cisplatin inhibits testosterone synthesis by a mechanism that includes the action of reactive oxygen species (ROS) at the level of P450scc

Cisplatin (Cs) is a chemotherapeutic agent able to generate reactive oxygen species (ROS) which are linked to several side effects of the drug. Even when it is known that Cs produces Leydig cell dysfunction, it is unknown whether this particular side effect is mediated by ROS. The aim of this study was to evaluate the in vitro effects of Cs on testosterone production and the participation of ROS in this effect. We demonstrate that Cs promotes the generation of ROS in a time-, and concentration-dependent fashion, not only in mouse testicular interstitial cells but also in MA-10 Leydig cells. Also, Cs inhibits testosterone synthesis in a concentration-dependent fashion (5–50 μM for 4 h) and to a similar extent, in cells exposed to human chorionic gondadotropin hormone (hCG), to an analog of the second messenger cAMP (8Br-cAMP) or to a freely diffusible cholesterol analog (22R-hydroxycholesterol). However, this treatment does not inhibit the conversion of pregnenolone to testosterone. These data suggest that Cs exerts its inhibitory action on testosterone synthesis by an action at the level of P450scc. We also demonstrated that an antioxidant impairs the inhibitory effect of Cs on the conversion of the cholesterol analog into pregnenolone and that Cs does not change the expression level of P450scc mRNA. Therefore, it is concluded that Cs inhibits testosterone synthesis by a mechanism that includes the inhibition of P450scc by ROS.     

Relationship between the 2D:4D and prenatal testosterone,adult level testosterone,and testosterone change: Meta-analysis of 54 studies

The ratio between the hands' second to the fourth finger (2D:4D) is commonly hypothesized to result from prenatal testosterone. The 2D:4D has also been hypothesized to relate to adult-level testosterone and, more recently, to the testosterone response to a challenging situation. In the present work, we tested these core assumptions. Drawing from, in total, 54 studies and 8077 participants, we investigated whether the 2D:4D is related to adult level testosterone (44 studies), testosterone change (6 studies), and prenatal testosterone (10 studies). We found no evidence of the relationship between the above testosterone types and digit ratios. Furthermore, there was no relationship between testosterone and the right and left 2D:4D, male and female 2D:4D, and the 2D:4D and testosterone measurement (i.e., measured in blood or saliva). However, we found some evidence that prenatal testosterone measured in amniotic fluid (but not cord blood) might be related to the digit ratios—further studies are necessary to validate this observation. In summary, considering the current state of knowledge, any conclusions drawn from the assumption of the digit ratios as the proxy for testosterone (prenatal, adult level, or testosterone change under a challenging situation) warrant great caution.     

Ultrastructural changes in the uropygial gland of the male Japanese quail,Coturnix coturnix,after testosterone treatment

Summary The ultrastructure of the uropygial gland of the male quail was compared to that of the sebaceous gland of the male rat after castration and testosterone treatment of both species. In intact animals, the differentiating cells of these glands displayed almost the same pattern as regards their smooth endoplasmic reticulum, an organelle involved in lipogenesis in both cases. Castration reduced the volume of this organelle, while testosterone administration restored cell morphology to a normal or supranormal level. Finally, this study showed that at ultrastructural level, there is a close functional analogy between the uropygial gland of quail and the sebaceous glands of rats as regards their androgen dependency. Consequently, the uropygial gland might be an attractive model for study of action of androgens on sebaceous-like glands.     

Role of dihydrotestosterone in the control of sexual behaviour on castrated male sheep

Wethers (at least 2 1/2 years after castration) were implanted with testosterone propionate (TP), oestradiol dipropionate (ODP), dihydrotestosterone, or a combination of dihydrotestosterone and ODP Silastic capsules. Active immunization against both oestradiol and oestrone or oestradiol only was used to negate effects of oestrogens produced by aromatization of TP. On exposure to oestrous ewes, immunization of wethers implanted with TP significantly (P less than 0.01) reduced all components of mating behaviour (except sniffing and Flehmen) to levels seen in untreated controls. The results support the conclusion that dihydrotestosterone potentiates the action of oestrogens, particularly as regards Flehmen, and has no action on its own within the central nervous system, while oestrogens do not restore mating activity to the same level as that following treatment with testosterone.     

Role for prenatal estrogen in the development of masculine sexual behavior in the male ferret

Previous studies have shown that neonatal exposure to testosterone is essential for coital masculinization in male ferrets. In the present experiments, masculine sexual behavior was diminished in male ferrets by prenatal exposure to drugs which inhibited estrogenic stimulation of the brain. Similarly timed prenatal treatments with testosterone failed to masculinize the behavior of female offspring. We hypothesize that prenatal exposure of the male ferret to estrogen, derived from the neural aromatization of circulating androgen, may sensitize the developing brain to the subsequent masculinizing action of testosterone shortly after birth.     

Cortisol and testosterone: Inhibitory agents of the mineralocorticoid pathway. Is there a physiopathological meaning in adrenal tumors?

The authors incubated adrenal mitochondria to study the in vitro action of cortisol and testosterone on the transformation of corticosterone and 18-hydroxycorticosterone into aldosterone. The results show that cortisol at concentrations of 5 × 10⁻⁶ and 10⁻⁴ M inhibit the conversion of corticosterone into aldosterone by 23.6 to 90%; testosterone 5 × 10⁻⁵ and 10⁻⁴ M inhibit the reaction by 78.4 and 87.2%, respectively. The inhibition of the conversion of 18-hydroxycorticosterone into aldosterone is 12.5 to 91% by cortisol with concentrations ranging from 5 × 10⁻⁷ to 5 × 10⁻⁵ M and testosterone 5 × 10⁻⁵ and 10⁻⁴ M inhibits the reaction by 87.3 and 91%, respectively. Aldosterone (10⁻⁸ and 10⁻⁶ M) does not inhibit aldosterone biosynthesis from corticosterone or 18-hydroxycorticosterone. It thus appears that cortisol and testosterone have an effect on the aldosterone biosynthesis pathways in mitochondria. This action may be located at the binding site of the cytochrome P450 11β, which catalyzes all hydroxylation steps in the mineralocorticoid biosynthesis pathway. Because cortisol and testosterone may interfere with aldosterone biosynthesis, and since functional zonation is expected in adrenal carcinomas, the presence of these steroids in substantial amounts could explain the very low plasma aldosterone level usually observed, in adrenal carcinomas studies in our laboratory.     

Androgen action at the target musculature regulates brain‐derived neurotrophic factor protein in the spinal nucleus of the bulbocavernosus

We have previously demonstrated that brain‐derived neurotrophic factor (BDNF) interacts with testosterone to regulate dendritic morphology of motoneurons in the highly androgen‐sensitive spinal nucleus of the bulbocavernosus (SNB). Additionally, in adult male rats testosterone regulates BDNF in SNB motoneurons and its target muscle, the bulbocavernosus (BC). Because BDNF is retrogradely transported from skeletal muscles to spinal motoneurons, we hypothesized that testosterone could regulate BDNF in SNB motoneurons by acting locally at the BC muscle. To test this hypothesis, we restricted androgen manipulation to the SNB target musculature. After castration, BDNF immunolabeling in SNB motoneurons was maintained at levels similar to those of gonadally intact males by delivering testosterone treatment directly to the BC muscle. When the same implant was placed interscapularly in castrated males it was ineffective in supporting BDNF immunolabeling in SNB motoneurons. Furthermore, BDNF immunolabeling in gonadally intact adult males given the androgen receptor blocker hydroxyflutamide delivered directly to the BC muscle was decreased compared with that of gonadally intact animals that had the same hydroxyflutamide implant placed interscapularly, or when compared with castrated animals that had testosterone implants at the muscle. These results demonstrate that the BC musculature is a critical site of action for the androgenic regulation of BDNF in SNB motoneurons and that it is both necessary and sufficient for this action. Furthermore, the local action of androgens at the BC muscle in regulating BDNF provides a possible mechanism underlying the interactive effects of testosterone and BDNF on motoneuron morphology. © 2013 Wiley Periodicals, Inc. Develop Neurobiol 73: 587–598, 2013     

睾酮对鸟类繁殖影响研究进展

类固醇激素睾酮是影响鸟类繁殖最重要的性激素之一,与鸟类的繁殖行为的各个方面息息相关。睾酮通过影响鸟类的羽色、鸣声等来影响鸟类的配偶选择,同时睾酮可以调节配偶选择和繁殖投入之间的平衡。睾酮水平影响出雏数、出飞数、孵化率成功率等繁殖成效。睾酮还对个体的免疫活性和个体的存活率等产生影响。目前关于睾酮对鸟类繁殖影响的研究大多是通过外源性植入睾酮的方式来改变个体睾酮的浓度,其研究结果也常出现相互矛盾之处,对于自然状态下影响睾酮水平变化的因素尚缺乏了解,睾酮对雌雄鸟在繁殖过程中的影响也不尽相同,有必要继续深入研究。     

Interaction of thyroid hormone and sex steroids at the rabbit reticulocyte membrane in vitro: control by 17 beta-estradiol and testosterone of thyroid hormone-responsive Ca2+-ATPase activity

Physiological concentrations (10(-10) M) of L-thyroxine and triiodo-L-thyronine were found in vitro to enhance Ca2+-ATPase activity in reticulocyte-enriched red cell membranes from female rabbits and to inhibit this enzyme in the male reticulocyte. Cross-incubation experiments with reticulocyte-enriched red cells and plasma from the opposite sex demonstrated that this sex-specific membrane response to thyroid hormone was transferable by plasma. Similar experiments with intact reticulocytes exposed to physiological concentrations (10(-11) M) of testosterone and 17 beta-estradiol indicated that the plasma factors were the sex steroids. That is, incubation in vitro with testosterone converted female-source reticulocytes to male-type responsiveness to thyroid hormone (inhibition of Ca2+-ATPase activity); incubation with estradiol converted male-source reticulocyte-enriched red cells to female-type responsiveness (stimulation by iodothyronines of membrane Ca2+-ATPase activity). Similar results were obtained when reticulocyte ghosts were incubated with testosterone and 17 beta-estradiol prior to determination of membrane enzyme activity. Etiocholanolone (5 beta-androstan-3 alpha-ol-17-one) and testosterone were equipotent, but 5 alpha-dihydrotestosterone had little activity in this system. Estrone and estradiol were equipotent, but estriol had no permissive effect on the stimulation by iodothyronine of reticulocyte membrane Ca2+-ATPase activity. Expression of thyroid hormone action in vitro on Ca2+-ATPase activity in the rabbit reticulocyte is determined at the membrane level by testosterone and estrogen. The structure-activity relationships of the sex steroids for this membrane action are different than those reported for nuclear actions of the steroids.     

Sexual differentiation of the rodent hypothalamus: hormonal and environmental influences

Brain sexual differentiation is a complex developmental phenomenon influenced by the genetic background, sex hormone secretions and environmental inputs, including pollution. The main hormonal drive to masculinize and defeminize the rodent brain is testosterone secreted by the testis. The hormone does not influence sex brain differentiation only in its native configuration, but it mostly needs local conversion into active metabolites (estradiol and DHT) through the action of specific enzymatic systems: the aromatase and 5alpha-reductase (5alpha-R), respectively. This allows the hormone to control target cell gene expression either through the estrogen (ER) or the androgen (AR) receptors. The developmental profile of testosterone metabolizing enzymes, different in the two sexes, is therefore of the utmost importance in affecting the bioavailability of the steroids active in brain differentiation. Widely diffused pollutants, like polychlorinated biphenyls (PCBs) are able to affect the production and/or action of testosterone metabolites, exerting detrimental influences on reproduction and sex behavior. The main studies performed in our and other laboratories concerning the pattern of expression and the control of the enzymatic systems involved in brain androgen action and metabolism are shortly reviewed. Some recent data on the influence exerted by PCBs on these metabolic systems are also reported.     

Androgens in the demography of male life course--a review

While the basics of testosterone production, effects and metabolism have been known for decades, there has been a flow of novel insights in the genomics of testosterone action on a molecular and cellular level, as well as in the clinical effects from modern clinical trials, improving the understanding of the role of testosterone in male life course. Androgens are produced under the control of an endocrine cascade from GnRH via gonadotropins to the testicular Leydig cells. In some organs, testosterone is reduced to 5alpha-dihydrotestosterone prior to the receptor binding by the 5alpha reductase. The androgen receptor gene is located on the X chromosome in the q11-12 region, each mutation in the gene will induce phenotypic manisfestations. In the first stage of the male life course, testosterone moderates the male embryonic development under the control of a complex molecular genetic network. The next important phase of male maturation is the puberty, in which testosterone levels increase and induce the development of somatic and psychological characteristics of male sexuality. In the adult male, testosterone maintains sexual functions and fertility. In aging men, testosterone levels decrease slowly. Testosterone supplementation in the aging male is able to restore the function of androgen target organs only in part.