Steroid metabolism by germ cells and spermatozoa in men after vasoepididymostomy.

The ability of germ cells (spermatocytes and spermatids) and spermatozoa present in human ejaculate to metabolize steroids was studied in men with obstructive infertility who had undergone vasoepididymostomy as corrective surgery. Steroid metabolism by spermatozoa in men who had undergone vasovasostomy was also investigated. Germ cells converted testosterone mainly to androstenedione. In addition to androstenedione, dihydrotestosterone and androstanediols were also formed in incubations using spermatids. Both types of germ cells converted estradiol to estrone. Spermatozoa from subjects who had undergone vasoepididymostomy or vasovasostomy converted testosterone to androstenedione as in normal men, while spermatozoa from infertile subjects converted testosterone mainly to dihydrotestosterone. Seminal fluid, free of germ cells, did not show steroid-metabolizing capability.     

In vitro metabolism of androgens by mammalian cauda epididymal spermatozoa.

The in vitro metabolism of [3H] testosterone (17beta-hydroxy-4-androsten-3-one), [3H] androstenedione (4-androstene-3,17-dione) and [3H] dehydroepiandrosterone (3beta-hydroxy-5-androsten-17-one) by cauda epididymal spermatozoa from the rat, rabbit, hamster, guinea-pig and ram, varied between species. There were differences in the androgens utilized, the extent of their conversion and the identities of the metabolites formed. Of the steroid substrates tested rat spermatozoa metabolized testosterone preferentially while spermatozoa from guinea-pig transformed [3H] dehydroepiandrosterone (DHEA) almost exclusively. Rabbit spermatozoa converted all three [3H] androgens while hamster sperm utilized [3H] testosterone and [3H] DHEA. Spermatozoa collected from rams killed at the abattoir metabolized both [3H] androstenedione and [3H] DHEA but this capacity was dramatically reduced in spermatozoa collected from rams subjected to short-term anaesthesea. The results are discussed in relation to the possible direct roles of androgens in sperm physiology.     

Testicular steroidogenesis in the rhesus monkey (Macaca mulatta.

Studies were undertaken to investigate testicular steroidogenesis in the Rhesus monkey Macaca mulatta. Testicular fragments (50 mg) were incubated for 3 hr with pregnenolone-7-3H or with progesterone-7-3H. The major metabolite of pregnenolone was progesterone (70.1%), with a lesser conversion to 17-hydroxyprogesterone (1.6%), androstenedione (3.3%), and testosterone (7.2%). The delta-5 intermediates 17-hydroxypregnenolone (4.6%) and dehydroepiandrosterone (8.6%) were also identified in the pregnenolone incubates. A majority of the progesterone substrate was not metabolized by the testicular fragments (80.1%), while some conversion to 17-hydroxyprogesterone (3.4%), androstenedione (4.8%), and testosterone (11.7%) occurred in the incubates. These results suggest that testicular fragments from the Rhesus monkey may convert pregnenolone to testosterone through both the delta-4 and the delta-5 pathways.     

Androgen dynamics in vitro in the normal and hyperplastic human prostate gland

The dynamics of uptake and metabolism in vitro of androgens by normal and hyperplastic human prostate glands was studied by means of a new experimental design proposed by Gurpide & Welch (1969). Prostate slices were perfused with a medium containing [(3)H]testosterone and [(14)C]androstenedione, or 5alpha-dihydro-[(3)H]testosterone and [(14)C]testosterone. The entry into the slices, the irreversible metabolism, the conversion between the compounds and the tissue retention or ;uptake' of the steroids were measured at the steady state. A similar portion of the three androgens entered the tissue and was irreversibly metabolized. Conversion of testosterone into 5alpha-dihydrotestosterone was much greater than the interconversion of testosterone and androstenedione. The prostate slices retained 5alpha-dihydrotestosterone at a concentration three times that in the medium, whereas testosterone and androstenedione were retained to a smaller extent. At a steroid concentration of 0.11mumol/l in the medium, the various parameters did not differ significantly in experiments performed with slices from normal and hyperplastic glands. When the steroid concentration in the medium was increased tenfold, however, a difference between normal and hyperplastic glands was evident. The normal glands increased the uptake and metabolism proportionally to the elevation of the steroid concentration in the medium. In the hyperplastic glands the entry and metabolism lagged behind the increase in steroid supply, whereas the tissue uptake became disproportionately high. The possible causes of this finding are discussed.     

In vitro metabolism of C19 steroids in human endometrium

In order to quantitate the extent of intracellular metabolic conversions of C19 steroids in human endometrium, specimens of proliferative and secretory tissue were superfused at a constant rate with several pairs of labeled compounds at low concentrations. About 16% of dehydroepiandrosterone sulfate interacting with endometrial cells was converted to dehydroepiandrosterone and about 3% of this compound was converted to androstenedione. Androstenedione was reversibly reduced to testosterone and the extent of this conversion was shown to be several-fold higher in secretory than in proliferative tissue. About 1% of testosterone entering the cells was reduced to 5 alpha-dihydrotestosterone. These results demonstrate that the conversion of the main circulating C19 steroids in women, i.e. dehydroepiandrosterone sulfate and androstenedione, to 5 alpha-dihydrotestosterone, the compound considered to be the true intracellular androgen, is very small. In contrast, formation of testosterone from androstenedione is extensive and increases during the luteal phase under the influence of progesterone, a hormone known to stimulate the activity of 17 beta-hydroxysteroid dehydrogenase in human endometrium.     

Androgen metabolism in the male hamster--1. Metabolism of testosterone in the pituitary gland and in the brain of animals exposed to different photoperiods

It is known that the metabolism of testosterone in the brain and in the anterior pituitary is different in mammalian and in photoperiodic avian species. In many mammalian species, testosterone is mainly metabolized to 5-alpha-reduced compounds (e.g. 17-beta-hydroxy-5-alpha-androstan- 3-one, 5 alpha-DHT and 3-alpha,17-beta-dihydroxy-5-alpha-androstane, 5-alpha,3-alpha-diol) and, to a smaller extent, to 4-androstene-3,17-dione (androstenedione), while in birds, androstenedione is the main testosterone metabolite and the conversion to the 5-alpha-reduced compounds is quantitatively negligible. In avian species, testosterone is also converted to 5-beta-reduced steroids (mainly 17-beta-hydroxy-5-beta-androstan-3-one, 5-beta-DHT and 3-alpha,17-beta-dihydroxy-5-beta-androstane, 5-beta,3-alpha-diol), and there is also evidence that in these species testosterone metabolism in the central structures may be influenced by the photoperiod. Since the hamster is a mammal whose reproductive cycle is controlled by day length, it has been analyzed whether: (a) the central structures of the hamster (cerebral cortex, hypothalamus and anterior pituitary) metabolize testosterone in vitro following a mammalian (5-alpha-reduced derivatives) or an avian (androstenedione and 5-beta-reduced compounds) pattern; and (b) the metabolism of testosterone in the same structures may be modified by the exposure to different photoperiods (LD 14:10 or LD 8:16). The present data indicate that no one of the hamster structures examined produces the 5-beta-reduced derivatives. Moreover, the formation of the 5 alpha-DHT is quantitatively low, and is not affected by the photoperiod. In contrast, androstenedione is formed in quite high yields and the exposure of the animals to 60 days of short photostimulation increases the formation of this steroid in the pituitary gland, but not in the brain structures. From these data, it appears that the central structures of the hamster metabolize testosterone with a pattern which is intermediate between that of birds and mammals.     

Failure of human benign prostatic hyperplasia to aromatise testosterone

The conversion of androgcns to oestrogens in benign human prostatic tissue was examined. Cytosol preparations were incubated separately with radiolabelled androstenedione and testosterone in the presence of a co-factor. The metabolic products were separated by phenolic partition and thin layer chromatography. The results of our investigations suggest that under the present incubation conditions there was no evidence for the aromatisation of androgen in the human prostate.     

Ethanol-induced inhibition of testosterone biosynthesis in rat Leydig cells: role of L-glutamate and pyruvate

The mechanisms by which ethanol (EtOH) inhibits testicular testosterone biosynthesis were studied with isolated rat Leydig cells in vitro comparing the effects of EtOH in six different culture media. The actual sites of inhibition by EtOH, identified by measuring the steroidogenic precursors, varied depending on the medium used. In Krebs-Ringer bicarbonate buffer, EtOH inhibited both the conversion of pregnenolone to progesterone and androstenedione to testosterone. In the pyruvate (Pyr) supplemented Dulbecco's Modified Eagle medium, the decreased progesterone concentrations in the presence of EtOH were reflected to all successive steroids 17-OH-progesterone, androstenedione and testosterone. The presence of L-glutamate (Glu) in the medium elevated testosterone production, but EtOH still inhibited the conversion of pregnenolone to progesterone, and also the androstenedione/testosterone ratio was elevated because of the decreased testosterone concentrations. In the presence of both Glu and Pyr in the medium the EtOH-induced decreases in the steroid concentrations were fully recovered in isolated Leydig cells. These results demonstrate that both Pyr and Glu supplementations are essential for the maintenance of maximal rate of testosterone synthesis in vitro in the presence of EtOH.     

Developmental patterns of serum luteinizing hormone, gonadal and adrenal steroids in the sooty mangabey (Cercocebus atys)

Serum levels of luteinizing hormone (LH), testosterone, dehydroepiandrosterone sulfate (DHAS), androstenedione and cortisol were determined in multiple samples from 86 sooty mangabeys of varying ages (0-17 years). Testosterone, androstenedione, DHAS and cortisol were measured by radioimmunoassay; LH was determined by in vitro bioassay. Serum LH concentrations were elevated in neonates (less than 6 months) and in animals older than 72 months of age. The higher LH levels were associated with increased circulating concentrations of testosterone in males but not females. The pubertal rise in serum testosterone at approximately 55-60 months of age in males was coincident with rapid body growth. No pubertal growth spurt was observed in females. Serum levels of androstenedione and DHAS were highest during early postnatal life (less than 6 months) with androstenedione exceeding 600 ng/dl in males and 250 micrograms/dl in females, but declined rapidly in both sexes to a baseline of 150 ng/dl by 19 months of age. Serum androstenedione did not fluctuate significantly in adult animals. The pattern of age-related changes in serum DHAS paralleled those of serum androstenedione, whereas serum cortisol values did not change significantly with age. Developmental changes in serum LH, testosterone and body weight suggest that the sooty mangabey matures substantially later than the rhesus monkey. The pattern of serum gonadal and adrenal steroids during sexual maturation is similar to that seen in the baboon with no evidence of an adrenarche.     

Regional differences in the metabolism of testosterone in vitro in the epididymis & ductus deferens of the adult rhesus monkey Macaca mulatta.

Regional differences in the metabolism of testosterone in vitro in the epididymis (1.5 cm segments) and ductus deferens (2 cm segments) were investigated in the adult rhesus monkey, Macaca mulatta. The conversion of tritiated testosterone to its 5alpha-reduced derivatives increased from the proximal to the distal regions of the epididymis. The total amount of 5alpha-reduced products in the subsequent segments of the epididymis was highest in the intact monkey and on the intact side of the unilaterally castrated monkey and was followed in decreasing order by the castrated side of the hemiscastrate and least in the bilateral castrate. Hormonal requirements for maintenance of the biological functions of the epididymis and maturation of spermatozoa in the epididymis are discussed.     

Intracrinology and the skin

The skin, the largest organ in the human body, is composed of a series of androgen-sensitive components that all express the steroidogenic enzymes required to transform dehydroepiandrosterone (DHEA) into dihydrotestosterone (DHT). In fact, in post-menopausal women, all sex steroids made in the skin are from adrenal steroid precursors, especially DHEA. Secretion of this precursor steroid by the adrenals decreases progressively from the age of 30 years to less than 50% of its maximal value at the age of 60 years. DHEA applied topically or by the oral route stimulates sebaceous gland activity, the changes observed being completely blocked in the rat by a pure antiandrogen while a pure antiestrogen has no significant effect, thus indicating a predominant or almost exclusive androgenic effect. In human skin, the enzyme that transforms DHEA into androstenedione is type 1 3beta-hydroxysteroid dehydrogenase (type 1 3beta-HSD) as revealed by RNase protection and immunocytochemistry. The conversion of androstenedione into testosterone is then catalyzed in the human skin by type 5 17beta-HSD. All the epidermal cells and cells of the sebaceous glands are labelled by type 5 17beta-HSD. This enzyme is also present at a high level in the hair follicles. Type 1 is the 5alpha-reductase isoform responsible in human skin for the conversion of testosterone into DHT. In the vagina, on the other hand, DHEA exerts mainly an estrogenic effect, this effect having been demonstrated in the rat as well as in post-menopausal women. On the other hand, in experimental animals as well as in post-menopausal women, DHEA, at physiological doses, does not affect the endometrial epithelium, thus indicating the absence of DHEA-converting enzymes in this tissue, and avoiding the need for progestins when DHEA is used as hormone replacement therapy.     

The use of nonradiolabelled steroid infusions to investigate the origin of oestrone sulphate in postmenopausal women

Infusion of nonradiolabelled dehydroepiandrosterone sulphate (DHA-S) has been used to investigate the possible formation of oestrone sulphate via a sulphated conjugate of androstenedione. The metabolic clearance rate (MCR) of DHA-S also was measured and the mean value (25 1/24h) was similar to values reported using isotopic techniques. Although conversion of DHA-S to 5-androstenediol, a steroid with oestrogenic properties, was detected during infusion of DHA-S, there were no significant increases in plasma levels of conjugated androstenedione or oestrone sulphate. The MCR's oestrone sulphate measured using infusion of nonradiolabelled steroid in two menopausal women were 99 1/24h and 121 1/24h. For one woman, the production rate of oestrone sulphate, calculated from the conversion of oestrone and oestradiol to oestrone sulphate (151 nmol/day) was similar to the measured production rate of oestrone sulphate (144 nmol/day). It is concluded that in menopausal women, oestrone sulphate is derived from conversion of oestrone and oestradiol with no formation occurring via conjugated androstenedione.     

The metabolism of androgens in rat preputial glands

The metabolism of testosterone, androstenedione and dehydroepiandrosterone in the rat preputial gland has been studied. A high activity of 5α-reductase is present as shown by the formation of 17β hydroxy-5α-androstan-3-one and 5α-androstan-3, 17-dione as the major products from testosterone and androstenedione respectively. Other enzyme activities are present including 17β-hydroxy steroid dehydrogenase, but the amounts of testosterone and 17β-hydroxy-5α-androstan-3-one formed from androstenedione and dehydroepiandrosterone are low. The main product of dehydroepiandrosterone metabolism was androstenedione indicating a high level of 3β-hydroxy steroid dehydrogenase 4-5 isomerase activity. The metabolism was compared with that in rat skin where it was found that the extent of metabolism was much less. The possible significance of the various products formed and of differences between skin and preputial gland metabolism is discussed. Some differences were noted between the metabolism of androgens by rat skin and preputial gland and the metabolism of androgens by human skin.     

催乳素对培养的绵羊睾丸间质细胞睾酮分泌的影响

在绵羊睾丸间质细胞体外无血清长期培养的条件下,研究了催乳素对睾丸间质细胞睾酮分泌的调节作用。实验结果表明,催乳素可增强细胞对人绒毛膜促性腺激素(hCG)刺激的反应。催乳素的这种作用呈双相调节。睾酮分泌量显著高于hCG和催乳素单独作用时的总和。在hCG存在下,不同的底物转化为睾酮的量不同。其中雄烯二酮和孕酮转化为睾酮的方式存在着双相性。脱氢表雄酮转为睾酮的量少,不存在双相性,而与其剂量成正比。催乳素在hCG存在下可调节底物转化为睾酮。低剂量的催乳素(1ng/ml)可使一定剂量的孕酮(10～30ng/ml)转化为睾酮的量明显增加,而高剂量的催乳素(>10ng/ml)却明显地抑制孕酮转化为睾酮。催乳素可明显地抑制雄烯二酮转化为睾酮,与剂量无关。可见催乳素对于孕酮和雄烯二酮这两个关键底物转化为睾酮的调节是不同的。催乳素增强hCG刺激睾酮分泌的作用可能部分是通过其促进孕酮转化为睾酮来实现的。     

The source of follicular androgens in the hamster follicle

The comparative ability of granulosa cells and theca of the hamster preovulatory follicle to produce androgens in vitro from endogenous and exogenous substrates was assessed. The results indicate that theca are the major source of follicular androstenedione, but that the granulosa cells may be the major source of follicular testosterone. Theca and granulosa cells accumulate comparable amounts of dihydrotestosterone from exogenous androstenedione and testosterone and both may be a significant source of follicular DHT. LH stimulates the conversion of progesterone and 17 alpha-OH progesterone to androstenedione, testosterone and DHT in theca. LH does not stimulate the conversion of androstenedione to testosterone or DHT, and that of testosterone to DHT in either granulosa cells or theca. FSH, in granulosa cells but not in theca, stimulates the conversion of adrostenedione to testosterone but it has no effect in DHT accumulation from exogenous testosterone.     

Steroid hormone formation in bovine ovarian follicles.

In an attempt to assess histophysiological implication of the follicular compartment of the bovine ovary in steroid hormone formation and the effect of human chorionic gonadotropin (hCG) in vitro on follicular steroidogenesis, minces of follicular tissues from non-gravid bovine ovaries were incubated with radioactive testosterone or acetate in the presence and absence of hCG. Significant amounts of estrone and estradiol-17beta were formed on incubation with testosterone-4-14C; hCG decreased the conversion approximately by 30%. The major radioactive products formed from acetate-l-14C were androstenedione and testosterone with lesser amounts of dehydroepiandrosterone and 17-hydroxyprogesterone. In addition, small amounts of progesterone, 17-hydroxypregnenolone, estrone and estradiol-17beta were formed. Histology of the dissected follicle specimens was characterized by dominant theca cells undergoing luteinization with small amounts of granulosa cells, which showed neither proliferation nor luteinization. The pattern of distribution of radioactivity among the steroids formed from acetate-14C was considered to represent steroidogenic profile of bovine atretic follicles. The addition of hCG in vitro increased the overall incorporation of radioactive acetate into the steroids approximately by 50%, although the range of increase was not uniform in the individual steroids under the exprimental conditions.     

Radioimmunoassay of androstenedione and testosterone in cow plasma at the time of luteolysis and oestrus

Androsteredione and testosterone were measured by radioimmunoassay after chromatography on micro-columns of Lipidex-5000 in jugular plasma samples taken every 2-3 h at the time of luteolysis and oestrus in 3 dairy cows. The concentrations of androstenedione and testosterone varied between 5 and 60 pg/ml and 5 and 80 pg/ml respectively and no consistent pattern in the fluctuations of either steroid was observed.     

Differential metabolism of pregnenolone by testicular homogenates of humans and two species of macaques. Lack of synthesis of the human sex pheromone precursor 5,16-androstadien-3 beta-ol in nonhuman primates.

In previous reports we described the early time sequence in in vitro [4-14C] pregnenolone metabolism in human and rat testicular homogenates and, apart from a difference in the preferred route of the conversion of pregnenolone to testosterone, we demonstrated the presence of delta 16-synthetase activity in human but not in rat testes. In the study of testicular function higher monkeys are increasingly used as a model for human reproduction. The availability of testes from 2 different species of macaques (rhesus and crab eating monkeys) enabled us to compare the in vitro metabolism of pregnenolone in these testes with human testes. The pattern obtained in both monkey species were very similar, but completely different from those found in man. The delta 4 pathway was the preferred route for the conversion of pregnenolone to testosterone in the monkeys tested, the delta 5 pathway in the humans. delta 16-Synthetase activity, a prerequisite for the synthesis of the sex pheromone precursors 5,16-androstadien-3 beta-ol and 4,16-androstadien-3-one, was clearly measurable in the human but not in the monkey testicular homogenates. So far, man and boar are the only species harbouring delta 16-synthetase activity in their testes. These in vitro data indicate that the nonhuman primates studied are not suitable models for the study of human testicular function.     

Sertoli cells from immature rats : in vitro stimulation of steroid metabolism by FSH.

Sertoli cells from 10 day old rats convert androstenedione to testosterone and 5α-androstane-3α,17β-diol, testosterone to 17β-hydroxy-5α-androstan-3-one and 5α-androstane-3α,17β-diol, and 17β-hydroxy-5α-androstan-3-one to 5α-andro-stane-3α,17β-diol after 72 hours $\text{in vitro}$. Conversions of androstenedione to testosterone and 5α-androstane-3α,17β-diol, and testosterone to 5α-androstane-3α,17β-diol were 2 to 3 times greater in FSH treated cultures. Steroid conversion was not stimulated significantly by LH or TSH. The results are interpreted as evidence that in young rats Sertoli steroid metabolism is stimulated by FSH, that Sertoli cells are an androgen target and that FSH may induce or facilitate Sertoli androgen responsiveness.     

Androstenedione and testosterone biosynthesis by the adrenal cortex of the horse

An homogenate from cortical tissue of mare adrenals was incubated in the presence of tritiated pregnenolone. The (3H) androstenedione and the (3H) testosterone synthesized during the incubation were extracted, purified, and co-crystallized to constant specific activity in the presence of unlabeled carriers. The rate of conversion of pregnenolone to androstenedione and testosterone was of the order of 5 and 0.15 per cent respectively. The high ratio of (3H) androstenedione to (3H) testosterone observed in this study suggests that androstenedione is the main androgen produced by mare adrenals. It is concluded that adrenals could contribute to the production of blood androgens in normal as well as hyperandrogenic mares.