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.     

Steroid metabolism in the gonads of a patient with testicular feminization. I. Metabolism of cholesterol, pregnenolone, progesterone and dehydroepiandrosterone in vitro.

The metabolism of cholesterol-4-14C, pregnenolone-4-14C, progesterone-4-14C and dehydroepiandrosterone-4-14C in a right abdominal and a left inguinal testis of a patient with testicular feminization was studied by a double isotope method in vitro. One of the main metabolites found in all incubations was testosterone. In incubations with cholesterol the delta4-pathway seems to be preferred. The rate of conversion of cholesterol to testosterone in the right testis was 1,27% and in the left testis 4,90%. Pregnenolone was converted to testosterone in the right testis at a rate of 6,61% and in the left testis at a rate of 3,23%. The conversion for testosterone using progesterone as precursor was 13,19% and 3,88% respectively and 11,97% of dehydroepiandrosterone was converted to testosterone in the right testis and 12,32% in the left testis. These findings are compared with data from the literature and conclusions are drawn.     

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.     

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.     

C-19-steroid 7α-hydroxylation by rat testes. isolation and identification of: 7α, 17β-dihydroxy-5α-androstan-3-one, 5α-androstan-3α,7α,17β-triol and 5α-androstane-3β,7α, 17β-triol

From incubations of testosterone with rat testicular homogenates in the presence of a NADPH-generating system, the following 7α-hydroxylated metabolites could be isolated and identified: 7α,17β-dihydroxy-4-androsten-3-one (7α-hydroxy-testosterone), 7α-17β-dihydroxy-5α-androstan-3-one (7α-hydroxy-Dht), 5α-androstan-3α,7α,17β-triol (7α-hydroxy-3α-A'DIOL) and 5α-androstane-3β,7α,l7β-triol (7α-hydroxy-3β-A'DIOL). To our knowledge this is the first demonstration of the formation of 5α-reduced-7α-hydroxylated metabolites of testosterone in the male gonad. These 5α-reduced-7α-hydroxylated metabolites could also be isolated after incubations of 5α-androstane-3α,17β-diol (3α-A'D10L) with testicular homogenates in the presence of a NADPH-generating system.Measured as the sum of 7α-hydroxy-testosterone, 7α-hydroxy-Dht. 7α-hydroxy-3α-A'DIOL and 7α-hydroxy-3β-A'DIOL formed using testosterone as substrate, total 7α-hydroxylase activity was six times higher in testes of mature rats than in testes from animals 23 days old. With 3α-A'DIOL as substrate total 7α-hydroxylase in the mature testis was about three times greater than in the sexually immature testis.     

Metabolism of testosterone by preparations from the rat testis

Seminiferous tubules isolated from immature and adult rats were incubated with [¹⁴C] testosterone. Androstanediol and androstenedione were the major metabolites; dihydrotestosterone and androsterone were produced in lesser amounts. Cell suspensions of spermatocytes prepared from tubules of immature rats formed dihydrotestosterone as the major metabolite of testosterone. Smaller amounts of androstanediol were formed and no androsterone was detectable. The results show that spermatocytes in common with androgen responsive tissues have the capacity to metabolize testosterone to 5α-reduced products.     

In vitro metabolism of 4-androstene-3,17-dione and testosterone by rat submaxillary gland.

Tritiated 4-androstene-3,17-dione and testosterone were incubated with submaxillary gland homogenates of male and female rats. The metabolism was predominately reductive. In 15 and 180 min incubations submaxillary tissue converted 4-androstene-3,17-dione chiefly to androsterone. Less testosterone, 17 beta-hydroxy-5 alpha-androstan-3-one, 5 alpha-androstane-3,17-dione, 5 alpha-androstane-3 alpha, 17 beta-diol, and 4-androstene-3 alpha, 17 beta-diol were also identified. Testosterone was converted to the same products plus 4-androstene-3,17-dione. 5 alpha-Androstane-3 alpha, 17 beta-diol was the major testosterone metabolite. Qualitatively the metabolism by male and female submaxillary gland was similar.     

Steroid metabolism in testicular tissue of genetic mutant mice

The conversion of testosterone and progesterone to other products was studied in testes of normal BALB/C mice, testieular, feminized (Tfm o⁺) and testicular feminized mice carrying the protective (o^hv) gene. The formation of testosterone from progesterone was 11 ± 1.3% in normal mice, 2.20 ± 0.8% in (Tfm o^hv) and 0.8 ± 0.2% in (Tfm o⁺ mice. With androstenedione as substrate, both (Tfm o⁺) and (Tfm o^hv) synthesized testosterone equally well. Testicular progesterone metabolism was also compared between normal and sex reversed (sxr) mice. The data suggested that the 17β hydroxysteroid dehydrogenase was more active in normal mice whereas the testes from the sex reversed (Tfm o^hv) gave higher conversions to androstenedione. Some conversion to dihydrotestosterone and androstanediol was found in all the testicular incubations.     

Testosterone metabolism by isolated human axillary corynebacterium spp.: A gaschromatographic mass-spectrometric study

Transformations of [4-¹⁴C]testosterone have been studied in Corynebacterium spp. isolated from the axillae of men. Metabolites have been separated by TLC and capillary gas chromatography and have been identified by gas chromatography-mass spectrometry (GC-MS). The introduction of a clean-up step using Florisil columns, prior to TLC, removed Tween-80 which co-extracted from the medium with the metabolites. This procedure greatly improved TLC resolution.Testosterone was converted enzymically to 5α- and 5β-DHT, identification being assisted by the inclusion of [3,4-¹³C]testosterone in some incubations. Other metabolites formed enzymically were 4-androstene-3,17-dione, 5β-androstane-3,17-dione, 3β-hydroxy-5β-androstan-17-one and 5β-androstane-3α.l7α-diol. Some spontaneous breakdown of [¹⁴C]testosterone occurred giving rise to 5α(β)-DHT, androstanediol and a monohydroxy-diketo-androstene, the latter being reduced enzymically to 2 monohydroxy-diketo-androstanes. Under the conditions used, no clear evidence has been obtained for the formation of 5α-androst-16-en-3-one, an odorous steroid that occurs in the axillae of men; the possible reasons why we were unable to prove the biosynthesis of this compound are discussed.     

On the regulation of rat testicular steroidogenesis. Short term effect of luteinizing hormone and cycloheximide in vivo and Ca2+ in vitro on steroid production in cell-free systems.

An attempt has been made to correlate the rapid effect of luteinizing hormone on testicular steroid production in vivo with testicular steroid concentrations and in vitro steroid production rates in testis tissue preparations. Within 20 min after intravenous administration of 25 mug luteinizing hormone, increases were observed in testosterone concentrations in testicular venous plasma and in whole testis tissue and in pregnenlone concentrations isolated testis mitochondrial fractions. Testosterone production by whole testis homogenates and pregnenolone production by isolated mitochondrial fractions were significantly increased within 5 min after in vivo administration of luteinizing hormone. Injection of cycloheximide 10 min prior to luteinizing hormone prevented the stimulating effect of luteinizing hormone to steroid levels in testicular venous plasma and testis tissue and on steroid production rates by preparations of rat testis tissue. Cycloheximide treatment of control animals did not significantly alter testosterone concentrations and testosterone production rates vitro, although mitochondrial pregnenolone concentrations and production rates were decreased. Testosterone production by whole testis homogenates as well as the pregnenolone production by isolated mitochondrial fractions obtained from luteinizing hormone treated testes and control glands showed a biphasic time curve A period (5-10 min) of high steroid production was followed by a period lower steroid production. Addition of 25 mug luteinizing hormone or 10(-8)--10(-5) M adenosine 3':5'-monophosphate (cyclic AMP) to the incubation medium had no effect pregnenolone production by isolated mitochondrial fractions. Administration of leuteinizing hormone in vivo markedly enhance the stimulating effect of Ca2+ on testosterone production by whole testis homogenates and on pregnenolone production by isolated mitochondrial fractions.     

Effect of injection of gonadotrophin-releasing hormone on testicular steroidogenesis in the hypogonadal (hpg) mouse

Hypogonadal (hpg) mice were injected once daily with 10 ng, 50 ng or 1 microgram GnRH for 5, 10 or 20 days or 12 times daily with 4.2 ng GnRH for 5 days. Basal and hCG-stimulated production in vitro of androstenedione, testosterone and 5 alpha-androstane-3 alpha,17 beta-diol (androstanediol) were measured by radioimmunoassay. All doses of GnRH increased testicular weight and in-vitro androgen production although seminal vesicle weights were unchanged and serum testosterone concentrations remained undetectable. After 5 days' treatment androstenedione and androstanediol were the dominant androgens produced, the latter indicating the presence of high levels of 5 alpha-reductase. By 20 days testosterone production was predominant after treatment with higher doses of GnRH. Total androgen production (androstenedione + testosterone + androstanediol) after 5 and 10 days was similar at all concentrations of GnRH used. After 20 days' treatment total androgen production was significantly greater with 50 ng GnRH/day than with 10 or 1000 ng/day. Multiple daily injections of 4.2 ng GnRH (total dose 50 ng/day) had no greater effect on androgen production in vitro compared to single daily injections of 50 ng. This suggests that under the conditions used in this study the testis does not require pulsatile release of the gonadotrophins. The pattern of [3H]pregnenolone metabolism was measured after 5 days injection of 50 ng GnRH/day. Compared to control hpg animals there was a significant increase in formation of C19 steroids, synthesis being solely through the 4-ene pathway. These results show that GnRH treatment of hpg mice will induce testicular steroidogenesis.(ABSTRACT TRUNCATED AT 250 WORDS)     

5alpha-reduced C21 steroids are substrates for human cytochrome P450c17

The 5alpha-reduction of testosterone in target tissues is a key step in androgen physiology; however, 5alpha-reduced C(19) steroids are sometimes synthesized in testis via a pathway that does not involve testosterone as an intermediate. We studied the metabolism of 5alpha-reduced C(21) steroids by human cytochrome P450c17 (hCYP17), the enzyme responsible for conversion of C(21) steroids to C(19) steroids via its 17alpha-hydroxylase and 17,20-lyase activities. hCYP17 17alpha-hydroxylates 5alpha-pregnan-3,20-dione, but little androstanedione is formed by 17,20-lyase activity. hCYP17 also 17alpha-hydroxylates 5alpha-pregnan-3alpha-ol-20-one and the 5alpha-pregnan-3alpha,17alpha-diol-20-one intermediate is rapidly converted to androsterone by 17,20-lyase activity. Furthermore, 5alpha-pregnan-3alpha,17alpha-diol-20-one is a better substrate for the 17,20-lyase reaction than the preferred substrate 17alpha-hydroxypregnenolone and cytochrome b(5) stimulates androsterone formation only 3-fold. Both 5alpha-pregnan-3alpha-ol-20-one and 5alpha-pregnan-3alpha,17alpha-diol-20-one bind to hCYP17 with higher affinity than does progesterone. We conclude that 5alpha-reduced, 3alpha-hydroxy-C(21) steroids are excellent, high-affinity substrates for hCYP17. The brisk metabolism of 5alpha-pregnan-3alpha,17alpha-diol-20-one to androsterone by CYP17 explains how, when 5alpha-reductases are present, the testis can produce C(19) steroids androsterone and androstanediol from 17alpha-hydroxyprogesterone without the intermediacy of androstenedione and testosterone.     

Androgen metabolism in somatic and germinal tissues of the sea star Asterias vulgaris.

1. Cell-free homogenates of male and female pyloric caeca, body wall, testis and ovary were incubated with radiolabeled 3H-androstenedione. 2. Pyloric caeca had highest rates of androstenedione conversion. The predominant metabolites in the pyloric caeca were testosterone, 5 alpha-androstane-3 beta, 17 beta-diol and 5 beta-androstane-3 beta, 17 beta-diol. 3. In body wall, testicular and ovarian homogenates, androstenedione was converted primarily to testosterone and also to 5 alpha-androstanedione and epiandrosterone. 4. Qualitative and quantitative differences in androgen metabolism in somatic and germinal tissues may be related to tissue-specific regulation of cellular metabolism.     

Inhibitory effects of stress-activated nitric oxide on antioxidant enzymes and testicular steroidogenesis

The messenger role of nitric oxide (NO) in immobilization stress-induced inhibition of testicular steroidogenesis has been previously suggested. In accord with this, here, we show that the intratesticular injection of isosorbide dinitrate (ISDN; 2x2.5 mg/testis), an NO donor, mimicked the action of stress on serum testosterone concentrations and hCG-stimulated testosterone production in rat testicular tissue. When added in vitro, ISDN inhibited testicular 3beta-hydroxysteroid dehydrogenase and 17alpha-hydroxylase/lyase. Immobilization stress and injections of ISDN also decreased the activity of catalase, glutathione peroxidase, glutathione transferase, and glutathione reductase in the interstitial compartment of testis. When stressed rats were treated concomitantly with bilateral intratesticular injections of N(omega)-nitro-L-arginine methyl ester, a non-selective NOS inhibitor (2x600 microg/testis), the activities of antioxidative enzymes, as well as serum testosterone concentration, were partially normalized. These results indicate that stress-induced stimulation of the testicular NO signalling pathway leads to inhibition of both steroidogenic and antioxidant enzymes.     

Comparison of urinary creatine with other biomarkers for the detection of 2-methoxyethanol-induced testicular damage

Abstract

This study has compared different biomarkers of testicular damage, in particular evaluating urinary creatine as a non-invasive marker. Male rats were exposed to various doses of 2-methoxyethanol, a known testicular toxicant. Pathological damage, testis weight, urinary creatine and creatinine, serum lactate dehydrogenase, isozyme C4 (LDH-C4), and serum testosterone were determined. 2-Methoxyethanol caused dose-dependent pathological damage to the testes which was detectable at the lowest dose (100 mg kg^?1). Urinary creatine excretion was significantly raised at all doses but testis weight was only significantly decreased at the highest two doses (500, 750 mg kg^?1). Serum testosterone was only significantly decreased at 500 mg kg^?1 and LDH-C4 was not significantly increased at any dose. Therefore urinary creatine was the most sensitive marker of 2-methoxethanol-induced testicular damage and dysfunction.     

Conjugation of androgens and estrogens by human breast tumors in vitro

The metabolism of ³H-androstenedione (Δ⁴ -A) and ³H-estriol (E³) was studied in 12 human breast tumors. Part of each tumor was analyzed for estrogen receptor content. Aliquots of tumor homogenates were incubated for 2 hr separately with ³H-δ⁴-A and ³H-E₃ in the presence of appropriate cofactors. No distinct differences emerged in the profiles of the unconjugated metabolites of ³H-δ⁴-A, the major compounds in the approximate order of descendence being androsterone, androstanedione, testosterone, 5α-androstane-3α,17β-diol, epiandrosterone, and dihydrotestosterone. One tumor homogenate from an infiltrating lobular carcinoma converted ³H-Δ⁴-A to glucosiduronate metabolites (11%), of which androsterone, 6.4%; testosterone, 1.6%; and androstanediol, 0.6% predominated. The homogenate of this tumor and two other tumors converted ³H-E₃ to ³H-E₃-3S. Conversions of E₃ to E₃-3S In the other tumor homogenates were less than 0.6%. No correlation between receptor content and the capability of the tumor to conjugate Δ⁴-A or E₃ evolved. However, correlations between steroid hormone metabolism and tumor histopathology may exist.     

Biosynthesis of steroids from cholesterol-14C by human adrenal carcinoma tissue

Slices prepared from human adrenal carcinoma tissue obtained froa a 51 year old female with virilism were incubated with cholesterol-4-¹⁴C (l) in the presence and absence of ACTH or cyclic AMP. The tissue homogenates were analyzed for steroids by the reverse isotope dilution method. Purification and identification of the radio-active metabolites were achieved by column, paper and thin-layer chromatography, derivative formation and crystallization to constant specific activity. Cholesterol-¹⁴C was converted to pregnenolone-¹⁴C (0.75%), progesterone- ¹⁴C (0.17%) and dehydroepiandrosterone-¹⁴C(0.15%). No evidence was found for the formation of labeled 17-hydroxyprogesterone, androstenedione, testosterone, and estrogens. Addition of ACTH to the incubations resulted in a two-fold inoreas of radioactive pregnenolone-¹⁴C and or dehydroepiandrosterone-¹⁴C. A two-fold increase of progesterone-¹⁴C synthesis was found in cyclic AMP-stimulated incubations.     

Metabolic pathways for androstanediol formation in immature rat testis microsomes

Metabolic routes from progesterone to androstanediol in washed rat testicular microsomes were investigated, with special emphasis on the importance of 4-ene-3-oxosteroids, as well as the effect of a minimal effective dose of human chorionic gonadotropin on these transformations. Incubation of equimolar concentrations of a mixture of [¹⁴C]progesterone and 17α-hydroxy[³H]progesterone resulted in a large preference of 17α-hydroxyprogesterone over progesterone as substrate for androstanediol formation. Incubation of [³H]progesterone together with [¹⁴C]androstenedione resulted in the inhibition of C-17,20-lyase and in a low ¹⁴C/³H ratio in androstanediol, indicating the preference of progesterone over androstenedione as substrate for androstanediol production. When a mixture of 17α-hydroxyl[³H]progesterone and [¹⁴C]androstenedione was incubated with the microsomes, a more than 8-fold preference of 17α-hydroxyprogesterone as substrate for androstanediol production was found. The minimal dose of human chorionic gonadotropin stimulated testosterone production but inhibited androstanediol formation and effected, in some instances, a change in the metabolic routes. It is concluded that androstanediol is produced preferentially through 17-hydroxylated C-21 steroids, and also, to a lesser extent, through C-19 steroids.     

D-Aspartic acid and nitric oxide as regulators of androgen production in boar testis

D-Aspartic acid (D-Asp) and nitric oxide (NO) are two biologically active molecules playing important functions as neurotransmitters and neuromodulators of nerve impulse and as regulators of hormone production by endocrine organs. We studied the occurrence of D-Asp and NO as well as their effects on testosterone synthesis in the testis of boar. This model was chosen for our investigations because it contains more Leydig cells than other mammals. Indirect immunofluorescence applied to cryostat sections was used to evaluate the co-localization of D-Asp and of the enzyme nitric oxide synthase (NOS) in the same Leydig cells. D-Asp and NOS often co-existed in the same Leydig cells and were found, separately, in many other testicular cytotypes. D-Asp level was dosed by an enzymatic method performed on boar testis extracts and was 40+/-3.6 nmol/g of fresh tissue. NO measurement was carried out using a biochemical method by NOS activity determination and expressed as quantity of nitrites produced: it was 155.25+/-21.9 nmol/mg of tissue. The effects of the two molecules on steroid hormone production were evaluated by incubating testis homogenates, respectively with or without D-Asp and/or the NO-donor L-arginine (L-Arg). After incubation, the testosterone presence was measured by immunoenzymatic assay (EIA). These in vitro experiments showed that the addition of D-Asp to incubated testicular homogenates significantly increased testosterone concentration, whereas the addition of L-Arg decreased the hormone production. Moreover, the inclusion of L-Arg to an incubation medium of testicular homogenates with added D-Asp, completely inhibited the stimulating effects of this enantiomer. Our results suggest an autocrine action of both D-Asp and NO on the steroidogenetic activity of the Leydig cell.     

Testicular binding of 125I-HCG in developing estrogenized and androgenized rats.

The present work describes changes seen in the binding of 125I-HCG by testis homogenates of rats injected at the age of three days with 400 microgram estradiol-17beta-dipropionate, or 250 microgram testosterone propionate. Estrogenized and androgenized male rats showed a marked decrease of gonadotropin binding in testis at the 30th, 45th and 60th postnatal day. These results show that delayed sexual maturation of male rats treated with estrogen and androgen in the neonatal period is also related to pubertal decrease of testicular gonadotropin receptors.