Biosynthesis and metabolism of testosterone by sertoli cell-enriched seminiferous tubules

Sertoli cell-enriched tubules isolated from rats which had been treated with 1,4-dimethyl sulfonyloxybutane were incubated with either [¹⁴C] progesterone or [¹⁴C] testosterone for 2 hours. Tubules of normal rats and fragments of Sertoli cell-enriched testes were incubated under the same conditions. Sertoli cell-enriched tubules converted progesterone to 20α-dihydroprogesterone, 17α-hydroxyprogesterone, androstenedione and testosterone. The major metabolite was 20α-dihydroprogesterone. The percentage conversion of progesterone into testosterone corresponded to a production of 10–20 ng testosterone. Sertoli cell-enriched tubules converted testosterone to dihydrotestosterone, androstenedione, 3α-androstanediol and 3β-androstanediol. Under our experimental conditions, dihydrotestosterone was the major 5α-reduced metabolite. Normal tubules converted progesterone and testosterone to the same metabolites as Sertoli cell-enriched tubules. Fragments of Sertoli cell-enriched testes were much more active than isolated tubules in metabolizing progesterone. They produced the same amounts of 5α-reduced metabolites of testosterone.     

Steroid metabolism by testicular homogenates of the Stanley-Gumbreck pseudohermaphrodite male rat. I. Increased formation of androsterone and androstanediol

Tritiated progesterone androstenedione and testosterone were incubated with testicular homogenates of 4- and 32-week-old Stanley-Gumbreck pseudohermaphrodite (Ps) and normal (N1) male littermate rats. In 15 and 180 minute incubations, both 4- and 32-week-old Ps testes converted all three substrates predominantly to androsterone and to a lesser extent androstanediol, while androstanediol in 4-week and testosterone in 32-week-old N1 testis were the major products. The addition of carrier testosterone (240 μg/g tissue) to 15 min incubations of testicular homogenates from 4- and 32-week-old N1 rats almost completely blocked the formation of androstanediol and markedly increased the accumulation of testosterone (47 and 41% from Progesterone-1,2-³ H; 66 and 92% from androstenedione-l,2-³H) indicating that androstanediol formed in the absence of carrier testosterone is, most likely, a product of testosterone reduction. When similar incubations were repeated using testicular homogenates from 4- and 32-week-old Ps rats, testosterone accumulation was not greatly increased (4–11%) by the addition of carrier testosterone, but androsterone formation was completely inhibited. However, when the incubations of Progesterone-1 ,2-³H with 4- and 32-week-old Ps and N1 testis in the presence of carrier testosterone were continued for 180 min, the major fraction of radioactivity from 32-week-old N1 testis was testosterone (79%) while that from 4-week-old N1 testis was androstanediol (60%) and from 4-and 32-week-old Ps testis was both androsterone (44–45%) and androstanediol (22–33%). The present data indicate that 4-week-old Ps testis, like the N1, has a high level of ring A reductase activity but forms androsterone rather than androstanediol as its major product. Unlike the normal mature male rat testis, in which ring A reductase activity diminishes allowing testosterone to become the major product, the 32-week-old Ps testis maintains a high level of reductase activity.     

Bioconversion of the androgen precursors by pre- and post-pubertal rat testes with special reference to local irradiation and gonadotropin stimulation

Pubertal changes in the testicular steroid enzyme activities, responsible for the androgen production, were studied in rats in relation to the effects of testicular irradiation, followed by gonadotropin stimulation and cyproterone suppression. Five groups of pro-pubertal and adult rats were used in this study. The $\text{in vitro}$ bioconversion from progesterone-4-14C and 17-hydroxyprogesterone-44C to testosterone, androstenedione, androstanediol, dihydrotestosterone and androsterone, demonstrated the effect of age in all cases of drug response investigations. The sexually immature animals in the control group had higher levels of androstenedione than testosterone, in contrast to the findings in the adults. With irradiation, androgen biosynthesis was suppressed in both age groups, which did not recover, under gonadotropin stimulation, in spite of the generation of new cells caused by the treatment. The irradiated adult testes demonstrated ‘pre-pubertal’ type bioconversion by catabolizing the substrates more towards 5α-reduced androgens, like androstanediol (5α-androstane-3α 17β-diol) and androsterone. With cyproterone the 17α-hydroxylase activities were found to be diminished.     

Purification of a form of mouse liver UDP glucuronosyltransferase which glucuronidates androgens

A form of UDP glucuronosyltransferase active in the glucuronidation of the androgens, testosterone, androsterone and dihydrotestosterone has been purified to apparent homogeneity as judged by sodium dodecylsulfate polyacrylamide gel electrophoresis from the livers of phenobarbital-treated C57BL/6N mice. This UDP glucuronosyltransferase is inactive towards estrone as substrate. Data from chromatofocusing and purification experiments suggest that testosterone and androsterone are glucuronidated primarily by this enzyme form and to a lesser extent by an enzyme form which has a slightly higher isoelectric point. However, this major form is only responsible for about half the capacity to glucuronidate dihydrotestosterone.     

Effect of hypophysectomy and gonadotropin treatment on metabolism of 3H-progesterone by rat testicular tissue

This study was conducted to define the pattern of $\text{in}$$\text{vitro}$ metabolism of ³H-progesterone in incubates of rat testicular tissue at various time intervals after hypophysectomy and to determine the effect of $\text{in}$$\text{vivo}$ gonadotropin treatment on the metabolism of ³H-progesterone in posthypophysectomy regressed testes. Formation of tritium labeled testosterone, androstenedione, 5α-androstanediol and androsterone was markedly diminished within two weeks and only traces of these substances were formed between the 23rd and 54th day after hypophysectomy. The major metabolite throughout this time period was ³H-20α-dihydroprogesterone. These data demonstrate that in posthypophysectomy-regressed testes ³H-progesterone metabolism does not revert to that observed in fetal testes or testes from immature animals. Treatment with HCG, commencing on the 33rd day after hypophysectomy resulted first in formation of 5α-reduced androgens and marked decrease in 20α-dihydroprogesterone. Additional treatment produced increased formation of radiolabeled testosterone and androstenedione and diminution of 5α-reduced androgens. This metabolic pattern is reminiscent of that observed in normally developing testes. Treatment with PMS commencing on the 33rd day after hypophysectomy resulted in formation of large amounts of androstenedione and testosterone and decrease of 20α-dihydroprogesterone to trace amounts within 10 days of initiation of treatment. After additional 10 days of treatment the formation of androstenedione diminished, testosterone remained unchanged. The possibility is suggested that FSH activity in PMS may be responsible for the different pattern of progesterone metabolism. The data of an three experiments suggest that the 20α-hydroxysteroid oxidoreductase activity may be influenced by gonadotropins.     

Metabolism of testosterone by tes epididymis and ventral prostate of rat and its inhibition by cyproterone acetate

The metabolism of ³H-testosterone by the epididymis and accessory organs of adult male rats exposed continuously to microdoses of cyproterone acetate from subcutaneous capsules were studied. The major metabolite of ³M-testosterone in the epididymis, vas deferens and ventral prostate of control rat was dihydrotestosterone while the formation of androstanediol by these tissues was low. The highest percentage of DHT was formed by the ventral prostate and cauda epididymis. In rats exposed to cyproterone acetate for four months, the conversion of testosterone to DHT was inhibited in all the tissues but maximally in the ventral prostate and cauda epididymis. In these rats, the secretory function of the ventral prostate was normal while that of the epididymis was markedly decreased. These data are discussed based on the differential thresholds of androgens required to regulate the functions of the accessory organs.     

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.     

Steroid metabolism by mouse submaxillary glands. I. in vitro metabolism of testosterone and 4-androstene-3,17-dione

Tritiated 4-androstene-3,17-dione and testosterone were incubated with submaxillary gland homogenates of 6 month old male mice. In 15 and 180 minute incubations fortified with NADPH, submaxillary tissue converted 4-androstene-3,17-dione predominantly to androsterone and, to a lesser extent, testosterone, 17β-hydroxy-5α-androstan-3-one and 5α-androstane-3α, 17β-diol. Testosterone was converted primarily to 5α-androstane-3α, 17β-diol when exogenous NADPH was available; trace amounts of 4-androstene-3,17-dione, 17β-hydroxy-5α-androstan-3-one and androsterone were also formed. When a NADPH-generating system was omitted from the incubation medium both 4-androstene-3,17-dione and testosterone were poorly metabolized by submaxillary tissue; the amounts of reduced metabolites accumulating were markedly reduced.     

Role of testosterone in the early stage of spermatocytogenesis in rats.

The role of testosterone in the early stage of spermatocytogenesis was investigated in newborn rats. The testes of rats, either 0 or 6 days of age, were implanted into those of hypophysectomized adult rats that had or had not been injected with testosterone propionate (TP) after hypophysectomy and also into those in intact adult rats. All the animals were autopsied 17 or 11 days later when the implanted testes reached 17 days of age. The implanted testes were examined for cellular components in the seminiferous tubules. In an additional experiment, newborn rats were injected with TP or cyproterone acetate, an antagonistic substance against androgen, daily for the first 17 days of life and examined for testes. Proliferation of supporting cells and development of seminiferous tubules were less remarkable in the testes of newborn rats which had been implanted into the testes of hypophysectomized rats than in those which had been implanted into the testes of intact adult rats. Proliferation of supporting cells was not stimulated by TP, but development of seminiferous tubules was slightly promoted. Progress in spermatocytogenesis from gonocytes to pachytene primary spermatocytes was observed in the testes of newborn rats which had been implanted into the testes of hypophysectiomized rats. It was not so marked after injection with TP. These results suggested that testosterone might have stimulated development of seminiferous tubules and maturation of spermatocytes in the early stage of spermatocytogenesis by its synergistic action with a gonadotropin, possible follicle-stimulating hormone.     

Sexual behavior of male golden hamsters receiving diverse androgen treatments

Four androgens were compared for their effectiveness in maintaining the sexual behavior of castrated male golden hamsters. Sexually experienced males were divided into 4 experimental treatment groups which received 500 μg daily of testosterone, androstenedione, dihydrotestosterone or androsterone. Control castrates were given oil. All animals were tested for sexual behavior every 2 wk for 10 wk following the onset of experimental treatment. Testosterone and androstenedione were the only androgens that maintained intromissions above the oil control level. However, testosterone, androstenedione and androsterone, but not dihydrotestosterone were effective in maintaining mounting behavior above the oil control level. No differences were detected between these 4 androgens in their maintenance of penile papillae.     

Testosterone formation in testis of the immature androgen insensitive pseudohermaphrodite male rat (Stanley-Gumbreck rat)

Testosterone formation from pregnenolone (3β-hydroxy-5-pregnen-20-one) and progesterone in testis of the Stanley-Gumbreck pseudohermaphrodite (Ps) adult rat is greatly reduced in comparison to the normal (Nl) adult rat testis. In an attempt to determine whether this defect is congenital or acquired postnatally with increasing age, minced testis of 1-month-old Ps and Nl rats were incubated with progesterone, and the labeled metabolites identified. Almost equal amounts of progesterone were metabolized by both Ps and Nl testis. In mince incubations without NADPH nearly as much testosterone and 4-androstene-3,17-dione accumulated in the Ps as in the Nl testis. Very little androsterone and 5α-androstane-3α,17β-diol were formed in these incubations. When minces were incubated with progesterone in the presence of NADPH, testosterone and 4-androstene-3,17-dione accumulation was greatly reduced, and instead 5α-androstane-3α,17β-diol was formed as the major product by Nl testis and androsterone by Ps testis. Neither heparin, a 5α-reductase inhibitor, nor glucose-6-phosphate dehydrogenase alone significantly influenced progesterone metabolism or the accumulation of testosterone or 4-androstene-3,17-dione in either Ps or Nl testis. These results indicated that the 5α-reductase activity in both the Ps and N1 testis is dependent only on NADPH. Although studies were not carried out in younger rats (2–5 days of age), our results are in agreement with previous studies of Goldstein and Wilson who demonstrated equal accumulation of testosterone in incubations of testis from normal and Tfm/y mice. However, it is apparent that differences between Nl and Ps testis may be revealed only under conditions which allow maximum rates of 17-oxo- and 5α-reductions.     

Increased apoptosis occurring during the first wave of spermatogenesis is stage-specific and primarily affects midpachytene spermatocytes in the rat testis

The physiological apoptosis that occurs in immature testis appears to be necessary for the maturation of this tissue. Thus, inhibition of the early apoptotic wave associated with the first round of spermatogenesis is followed by accumulation of spermatogonia and infertility later in life. To identify the cell types undergoing apoptosis in immature rat testis and to characterize the relationship between this apoptosis and progression of the first wave of spermatogenesis, sequential viable segments of seminiferous tubules from 8-, 18-, and 26-day-old rats were examined under a phase-contrast microscope. One novel observation was the existence of pronounced stage-specificity during the peak of apoptosis at the very early postnatal ages of 18 and 26 days. Increased apoptosis of pachytene spermatocytes in stages VII-VIII was the major feature that distinguished immature spermatogenesis from the corresponding adult process. The frequency of apoptosis among type A spermatogonia in immature stages IX-I was also elevated in comparison to the corresponding mature stages. The age-related peak of apoptosis was mediated by caspase 3; furthermore, stage-dependent expression of Bax in midpachytene spermatocytes was observed in the 18- and 26-day-old testis. These observations suggest that this Bax-regulated, caspase 3-mediated, increased apoptosis of midpachytene spermatocytes during the first wave of immature spermatogenesis represents a major difference in comparison to apoptosis occurring in the mature testis, and it may play an important regulatory role in establishing spermatogenesis in the rat testis.     

Localization of epoxide-metablozing enzymes in rat testis

Antibodies raised against rat hepatic epoxide hydrolase (EC 3.3.2.3) and glutathione S-transferases (EC 2.5.1.18) B, C and E were used to determine the presence and localizations of these epoxide-metabolizing enzymes in testes of sexually immature and mature Wistar and Holtzman rats. Unlabeled antibody peroxidase-antiperoxidase staining for each enzyme was readily detected in rat testes at the light microscopic level. Although significant strain-related differences were not apparent, staining intensity for certain enzymes differed markedly between Leydig cells and seminiferous tubules. Leydig cells of immature and mature rats were stained much intensely for epoxide hydrolase and glutathione S-transferase B and E than were seminiferous tubules, whereas Sertoli cells, spermatogonia, spermatocytes and spermatids, as well as Leydig cells, were stained intensely by the anti-glutathione S-transferase C. Age-related differences in staining for glutathione S-transferase B were not obvious, while the anti-glutathione S-transferase C stained seminiferous tubules more intensely in immature rats, and antibodies to expoxide hydrolase and glutathione S-transferases C and E stained Leydig cells much more intensely in mature rats. These observations thus demonstrate that testes of both sexually immature and mature rats contain epoxide hydrolase and glutathione S-transferases. Except for glutathione S-transferase C in immature rats, Leydig cells appear to contain much higher levels of enzymes than do seminiferous tubules. During sexual maturation, the testicular level of glutathione S-transferase B appears to remain constant, while levels of epoxide hydrolase and glutathione S-transferases C and E increase within Leydig cells and the level of glutathione S-transferase C decreases within seminiferous tubules.     

Androgen receptor in nuclei of rat testis.

Testis nuclei of hypophysectomized rats selectively accumulate labeled testosterone and 5alpha-dihydrotestosterone following the injection of tritiated testosterone in vivo. Testosterone and 5alpha-dihydrotestosterone are bound to macromolecules in nuclei and can be extracted with 0.5 M KCl. Accumulation of protein bound radioactive androgens in nuclei of isolated seminiferous tubules is similar to that of whole testis. The relative amounts of testosterone and dihydrotestosterone in purified nuclei were similar to the relative amounts bound to cytoplasmic receptors, suggesting that cytoplasmic androgen-receptor complexes may be transported into the nuclei. Binding of labeled androgen is saturable and inhibited by prior injection of unlabeled testosterone or cyproterone acetate. Nuclear binding sites are destroyed by the proteolytic enzyme pronase, but not by DNase. Like the cytoplasmic androgen-receptor complexes in rat testis, nuclear androgen-protein complexes are heat labile and dissociate slowly at 0 degrees C. androgens fail to accumulate in testis nuclei of the Stanley-Gumbreck androgen insensitive rat, a species lacking cytoplasmic androgen receptors in testis and other androgen target tissues.     

Strain differences in rat liver (UDP-glucuronyltransferase activity towards androsterone.

Male Donryu, Wistar King rats showed discontinuous variations in hepatic microsomal UDP-glucuronyltransferase activities towards androsterone, but not towards testosterone, bilirubin, phenolphthalein and 4-nitrophenol. Fresh microsomal fraction with a low transferase activity towards androsterone formed 0.049--0.080 nmole of glucuronide/min per mg of protein, whereas fresh microsomal fraction with a high transferase activity towards androsterone formed 0.335--0.557 nmol of glucuronide/min per mg of protein. The microsomal fraction with low enzyme activity towards androsterone was not stimulated by treatment with Triton X-100 or freezing and thawing. In contrast, male Long Evans and Sprague-Dawley rats did not exhibit such diversity.     

Testosterone induces a rapid stimulation of endocytosis,amino acid and hexose transport in mouse kidney cortex

Testosterone induced a rapid (<1 min) stimulation of endocytosis, amino acid and hexose transport, measured by the temperature-sensitive uptake of HRP, ¹⁴C-AIB and ³H-DG, in mouse kidney cortex slices. The hormonal increment in uptake persisted for at least 60–120 min, showed time-, energy-, and Na⁺-dependence, and varied with substrate and testosterone concentration. Testosterone was maximally effective at 10^?8 to 10^?7 M. Peroxidase histochemistry indicated that the hormonal increase in HRP uptake is restricted to proximal tubules. Testosterone was more effective than DHT, whereas cyproterone acetate, androsterone and dexamethasone had little or no stimulating effect on this uptake. Kidney slices from androgen-insensitive $\text{tfm}\text{Y}$ mice did not respond to testosterone. The rapid increase in endocytosis, amino acid and hexose transport may represent a direct, receptor-mediated response of the surface membrane of target cells to testosterone.     

In vitro metabolism of testosterone by cultured Sertoli cells and the effect of FSH.

Cultures of Sertoli cells isolated from testes of 18-and 36-day-old Long Evans rats were used to investigate their capacity to metabolize testosterone and the effect of FSH on such metabolism. Three different approaches were used: 1) investigation of the metabolism of radiolabeled testosterone under saturating substrate conditions; 2) study of the metabolism of radiolabeled testosterone utilizing trace amounts of high specific activity substrates; 3) the utilization of radioimmunoassay for measurement of estradiol-17 beta. The following steroids were isolated and identified by recrystallization to constant specific acitvity from the control and FSH-treated cultures; testosterone (unconverted substrate), androstenedione, dihydrotestosterone, 3 alpha-hydroxy-5 alpha-androstan-17-one and 5 alpha-androstane-3 alpha, 17 beta-diol. Radioimmunoassay data suggests that the Sertoli cells produce an estradiol-17 beta-like compound from unlabeled testosterone and that this production is stimulated by FSH. However, the radioactive metabolite from all our studies that behaved chromatographically like estradiol--17 beta failed to crystallize to constant specific activity, while in each experiment, authentic radiolabeled estradiol-17 beta added as recovery tracer did. The data demonstrate that : 1) cultures of Sertoli cells from immature rats have 5 alpha-reductase, 3 alpha- and 17 beta-hydroxysteroid oxidoreductase activities; 2) these enzymes may be affected by FSH; 3) based on radiolabeled metabolic techniques, Sertoli cells were unable to biotransform testosterone to estradiol-17 beta even in the presence of FSH.     

Formation of 5 alpha-products as major C19-steroids in estrogen-responsive mouse Leydig cell tumor lines

Homogenates of estrogen-responsive mouse Leydig cell tumors (T 124958-R and T 22137) or 28- and 120-day-old mouse testes were incubated with [3H]progesterone or [14C]4-androstene-3,17-dione in the presence of NADPH, and progesterone metabolism and enzyme activities were estimated. The growth of T 124958-R tumor transplanted in BALB/c mice was markedly stimulated by estrogenization of host mice, but the growth of T 22137 tumor was evidently suppressed by the estrogenization. The major C21-17-OH-steroids and C19-steroids formed from progesterone by both tumors and the testes of immature mice were 5 alpha-steroids, such as 3 alpha,17-dihydroxy-5 alpha-pregnan-20-one, 5 alpha-androstane-3,17-dione, androsterone, 3 beta-hydroxy-5 alpha-androstan-17-one and 5 alpha-androstane-3 alpha,17 beta-diol. In contrast, the major steroids formed by the testes of adult mice were testosterone and 4-androstene-3,17-dione, and no or little 5 alpha-steroids were produced. 5 alpha-Reductase activities in both tumor cells (40-50 nmol/l X 10(8) cells per h) were also found to be approx. 5-6 times higher than that in Leydig cells of adult mouse testes (8 nmol/l X 10(8) Leydig cells per h), though 17-hydroxylase activity was much higher in the Leydig cells of adult testes (730 nmol/l X 10(8) Leydig cells per h) than in both tumor cells (1-7 nmol/l X 10(8) cells per h). Furthermore, the presence of significant amounts of endogenous androsterone and/or 5 alpha-androstane-3 alpha,17 beta-diol was demonstrated in both tumors by radioimmunoassay. The present results demonstrate for the first time that C19-5 alpha-steroids are major C19-steroid products (immature type of testicular androgen production) in Leydig cell tumor lines.     

Oxidation-reduction potentials and spectral properties of some cytochromes from Thiobacillus versutus (A2)

Antibodies raised against rat hepatic epoxide hydrolase (EC 3.3.2.3) and glutathione S-transferases (EC 2.5.1.18) B, C and E were used to determine the presence and localizations of these epoxide-metabolizing enzymes in testes of sexually immature and mature Wistar and Holtzman rats. Unlabeled antibody peroxidase-antiperoxidase staining for each enzyme was readily detected in rat testes at the light microscopic level. Although significant strain-related differences were not apparent, staining intensity for certain enzymes differed markedly between Leydig cells and seminiferous tubules. Leydig cells of immature and mature rats were stained much more intensely for epoxide hydrolase and glutathione S-transferases B and E than were seminiferous tubules, whereas Sertoli cells, spermatogonia, spermatocytes and spermatids, as well as Leydig cells, were stained intensely by the anti-glutathione S-transferase C. Age-related differences in staining for glutathione S-transferase B were not obvious, while the anti-glutathione S-transferase C stained seminiferous tubules more intensely in immature rats, and antibodies to epoxide hydrolase and glutathione S-transferases C and E stained Leydig cells much more intensely in mature rats. These observations thus demonstrate that testes of both sexually immature and mature rats contain epoxide hydrolase and glutathione S-transferases. Except for glutathione S-transferase C in immature rats, Leydig cells appear to contain much higher levels of enzymes than do seminiferous tubules. During sexual maturation, the testicular level of glutathione S-transferase B appears to remain constant, while levels of epoxide hydrolase and glutathione S-transferases C and E increase within Leydig cells and the level of glutathione S-transferase C decreases within seminiferous tubules.     

A stereological and histopathological study of the effects of exposure of male rat testes to mercury vapor

Mercury is ubiquitous in the environment; it is an occupational pollutant and a potential toxicant. We investigated the effects of exposure of rat testes to mercury vapor (Hg⁰). Twelve male rats were divided into two groups of six: the rats of the Hg⁰ group were exposed to mercury (1 mg/m³/day) in a chamber for six weeks; the control group rats were housed under the same conditions without exposure to Hg⁰. After the experimental period, the testes were removed, sections of testis were evaluated histopathologically after hematoxylin and eosin staining, and stereologically using the Cavalieri principle and optical fractionator methods. We found significant decreases in the total volume of testis, diameters of seminiferous tubules and total volume of seminiferous tubules. Significant decreases were detected in the numbers of Sertoli cells, spermatogonia, spermatocytes and spermatids of the Hg⁰ group compared to the control group. In the Hg⁰ exposed group, spermatogenic cells were degenerated and seminiferous tubules were atrophied.