5 alpha-reductase activity in rat adipose tissue

We measured the 5 alpha-reductase activity in isolated cell preparations of rat adipose tissue using the formation of [3H]dihydrotestosterone from [3H]testosterone as an endpoint. Stromal cells were prepared from the epididymal fat pad, perinephric fat, and subcutaneous fat of male rats and from perinephric fat of female rats. Adipocytes were prepared from the epididymal fat pad and perinephric fat of male rats. Stromal cells from the epididymal fat pad and perinephric fat contained greater 5 alpha-reductase activity than did the adipocytes from these depots. Stromal cells from the epididymal fat pad contained greater activity than those from perinephric and subcutaneous depots. Perinephric stromal cells from female rats were slightly more active than those from male rats. Estradiol (10(-8) M), when added to the medium, caused a 90% decrease in 5 alpha-reductase activity. Aromatase activity was minimal, several orders of magnitude less than 5 alpha-reductase activity in each tissue studied.     

Hormonal regulation of 5 alpha-reductase activity in anterior pituitary gland microsomes of the male rat]

It was previously shown that the microsomal 5 alpha-reductase activity in the male rat pituitary was increased by castration. Subcutaneous administration of androgens to castrated rats prevented the rise in 5 alpha-reductase activity. Their relative efficiency was as follows: 5 alpha-dihydrotestosterone greater than 5 alpha-androstane-3 alpha, 17 beta-diol greater than testosterone. Under our experimental conditions 5 alpha-androstane-3 beta, 17 beta-diol and estrogens were inefficient. The rise in 5 alpha-reductase activity following castration is exclusively located in hypophysis and it is probably due to an increased of the enzyme biosynthesis.     

Regulation of the pituitary 5 alpha-reductase activity by gonadotropin releasing hormone and testosterone in the adult male rat

Intact or castrated adult male rats were treated for nine days with GnRH (10 micrograms/day), the synthetic GnRH goserelin (100 micrograms/day) or the GnRH-antagonist Org 30276 (250 or 500 micrograms/day). In some series, 1 mg testosterone propionate was administered alone, or in combination with goserelin or Org 30276. The in vitro metabolism of [1 alpha,2 alpha-3H]testosterone by pituitary and hypothalamic homogenates was investigated in combination with the estimation of plasma concentrations of testosterone and gonadotropins. No qualitative or quantitative differences were observed in hypothalamic testosterone metabolism or in the pituitary 17 beta-hydroxysteroid dehydrogenase activity. Testosterone administration to intact male rats decreased the pituitary 5 alpha-reductase activity and LH, while administered to castrated rats, it was able to suppress totally the castration-induced increase of the 5 alpha-reductase activity and of the gonadotropin secretion. The drastic decrease of the plasma levels of testosterone, observed after a prolonged treatment with GnRH, goserelin or Org 30276 was not accompanied by an increased pituitary 5 alpha-reductase activity. Injected to castrated rats, it was observed that the castration-induced increase of the pituitary 5 alpha-reductase was further stimulated by GnRH, totally suppressed by goserelin and partially suppressed by Org 30276. Concomitant administration of goserelin or Org 30276 and testosterone propionate to castrated rats resulted in a further decrease of the pituitary 5 alpha-reductase activity, compared to the castrated, GnRH-analogue treated rats. These data indicate that the pituitary 5 alpha-reductase enzyme system is controlled by both direct steroidal and indirect GnRH-mediated mechanisms.     

Enzyme assay for 5alpha-reductase type 2 activity in the presence of 5alpha-reductase type 1 activity in rat testis

The relative abundance and physiological role of 5alpha-reductase (5alphaR) isoforms in rat testis, in particular 5alpha-reductase Type 2 (5alphaR2) are poorly understood. Investigation of 5alphaR2 activity using enzyme kinetic studies was hampered by the high concentrations of 5alpha-reductase Type 1 (5alphaR1) in rat testis. Therefore, an assay was developed which exploited the differences in pH optima of the two isoforms. The 5alphaR assays measured the conversion of 3[H]-testosterone to 5alpha-reduced metabolites (dihydrotestosterone+3alpha-Androstanediol) at pH 5.0 and 7.0. To compensate for the overlap of 5alphaR1 activity at pH 5.0, the amount of 5alphaR1 activity at pH 5.0 was determined by measuring recombinant rat 5alphaR1 expressed in COS-7 cells at pH 5.0 and 7.0. The amount of activity at pH 5.0 that was attributed to 5alphaR1 was determined to be 12.4+/-1.4% (mean+/-S.D., n=14). The 5alphaR2 assay was validated by determining recombinant rat 5alphaR2 activity in the presence of recombinant rat 5alphaR1 activity in COS cells. A 99.3+/-14.7% recovery of 5alphaR2 activity was obtained when comparing 5alphaR2 activity recovered versus activity added. 5alphaR1 and 5alphaR2 activities were then assayed in rat testis extracts from 30, 75 and 147 days. Both isoforms markedly declined (50-100-fold) over this age range, with 5alphaR1 as the predominant isoform. In conclusion, an enzymatic assay that detects 5alphaR2 activity in the presence of high concentrations of 5alphaR1 was developed and is applicable in the measurement of 5alphaR2 activity in rat testis.     

The activity of 3 alpha- and 3 beta-hydroxysteroid dehydrogenases and 5 alpha-reductase, together with androgen levels in male rat pituitary during sexual maturation

In all subcellular pituitary fractions, 3 alpha-hydroxysteroid dehydrogenase (3 alpha-ol dehydrogenase) activity is high (1 to 3 pmol/mg/h) with NADH or NADPH as cofactor, and 3 beta-hydroxysteroid dehydrogenase (3 beta-ol dehydrogenase) activity much lower. The highest activity of the latter (0.15 pmol/mg/h) is detected in cytosol with NADH as cofactor. During sexual maturation, cytosolic (NADH-dependent) 3 alpha- and 3 beta-ol dehydrogenase activities remain constant, whereas the 5 alpha-reductase activity is maximum at 37 days. The levels of different pituitary androgens were evaluated by radioimmunoassay. At 28 days, testosterone level is 4 ng/g of tissue, then after 42 days the level remains between 4.5 and 6 ng/g at a level higher than the DHT level. In all cases during the maturation of the rat, the different 5 alpha-reduced androgens are in the same ratio: DHT greater than 3 alpha-diol greater than 3 beta-diol, and the sum of these three 5 alpha-reduced androgens decreases between the 28th and the 90th day.     

17 alpha-oxidoreductase activity in kidneys of male and female mice of various ages

Male and female mice at 0-120 days of age were used. Homogenates of kidneys were incubated with [14C]4-androstene-3,17-dione, and 17 alpha-oxidoreductase activity per g tissue was examined. The activities of 17 alpha-oxidoreductase in the kidneys of both sexes increased markedly with age during sexual development by up to 150-fold and reached the maximum values (2700 and 1500 nmol/g/h in male and female kidneys, respectively) at 60 days of age. In the adult male mouse kidney, the activity in isolated cortex fractions was 14 times as high as the activity in isolated medulla fractions; in the medulla fractions renal tubules from the cortex accounted for 3-15% of the total tissue. Furthermore, histochemical examination showed the activity present only in the cortex, at which much higher levels in the tubules than in the glomerulus. Activity at 35-120 days of age was significantly higher in male kidneys than in female kidneys. The difference appears to be induced by testicular androgens during sexual development, since neonatal castration in males resulted in decreases of activity to levels similar to those in female kidneys. However, castration at 60 days of age showed no significant effect on the activity. The present results show that the activity per g tissue of 17 alpha-oxidoreductase in the mouse kidney increases markedly with age, and that the activity is largely confined to the renal tubules of the cortex.     

Testosterone 5 alpha-reductase in rat brain

We describe a simple procedure for the microassay of testosterone 5 alpha-reductase in homogenates of rat brain. This enzyme converts testosterone to dihydrotestosterone. We have used this assay to characterize the enzymatic activity and to map its distribution. The apparent Km is 4.1 x 10(-6) M and the Vmax is 85.6 pmol/mg protein/h. The pH optimum is broad and extends from pH 6.0 to 8.0. For the brain regions surveyed, testosterone 5 alpha-reductase activity varied over a 10-fold range. The highest activities were observed in homogenates of the midbrain and pons (37-39 pmol/mg protein/h). The lowest were seen in homogenates of the thalamus, caudate nucleus, frontal cortex, hippocampus, hypothalamus, olfactory tubercle, and preoptic area (3-7 pmol/mg protein/h).     

Prolactin involvement in regulation of testicular 5 alpha-reductase activity in the immature rat

Treatment of intact immature (25-day-old) rats with bromoergocryptine (BR), which suppressed prolactin (Prl) secretion, decreased testicular 5 alpha-reductase activity, whereas treatment with Prl increased the enzyme activity in BR-treated animals. Serum luteinizing hormone (LH) concentrations were not reduced by BR treatment or elevated by Prl, suggesting that the BR and Prl effects on enzyme activity were not due to alterations in LH secretion. Hypophysectomy (at 21 days of age) caused a dramatic decrease in testicular 5 alpha-reductase activity, and treatment with LH partially reversed this effect. Treatment of hypophysectomized animals with Prl alone had no effect on the enzyme activity but enhanced the effect of LH. Testosterone propionate, given to hypophysectomized animals in a regimen that increased testicular testosterone to concentrations at least as high as those in intact (sham-hypophysectomized) controls, had no effect on enzyme activity, whether given alone or in combination with LH. These results indicate that Prl is involved, along with LH, in maintaining the high 5 alpha-reductase activity of the prepubertal rat testis; the action of Prl, apparently requiring the presence of LH, may be to decrease the rate of degradation of the enzyme. The data also suggest that the action of LH on testicular 5 alpha-reductase activity is not mediated by its stimulation of testosterone production.     

Inhibition of testosterone 5alpha-reductase activity and growth of accessory sex tissues in castrated male mice

The steroid 4-androsten-3-one-17beta-carboxylic acid (17betaC) reduced the growth-promoting actions of testosterone, but not those of DHT in accessory sex tissues of castrated mice. The 5alpha-reduction of testosterone to DHT in these tissues was also reduced by 17betaC treatment, suggesting that DHT formation is a required step in the mechanism of action of testosterone.     

Solubilization and partial characterization of rat epididymal delta 4-steroid 5 alpha-reductase (cholestenone 5 alpha-reductase).

Epididymal delta 4-steroid 5 alpha-reductase (cholestenone 5 alpha-reductase), the enzyme that catalyses the conversion of testosterone into the biologically active metabolite dihydrotestosterone (17 beta-hydroxy-5 alpha-androstan-3-one), is a membrane-bound enzyme found in both nuclear and microsomal subcellular fractions. In order to characterize epididymal delta 4-steroid 5 alpha-reductase, it was first necessary to solubilize the enzymic activity. Of the various treatments tested, a combination of 0.5% (w/v) Lubrol WX, 0.1 M-sodium citrate and 0.1 M-KCl maintained enzymic activity at control values and solubilized 66% of total epididymal delta 4-steroid 5 alpha-reductase activity in an active and stable form. The sedimentation coefficient of solubilized delta 4-steroid 5 alpha-reductase, as determined in continuous sucrose density gradients, was greater for the microsomal than for the nuclear enzyme (11.6S compared with 10.1S). Although the apparent Km values of the enzyme for testosterone were similar in nuclear and microsomal subcellular fractions (range 1.75 x 10(-7) - 4.52 x 10(-7)M), the apparent Km of the enzyme for NADPH was about 30-fold greater for the microsomal enzyme than for the nuclear enzyme. The apparent Km of the enzyme for either substrate was not significantly altered after solubilization. The relative capacity of steroids to inhibit the enzymic activity, the pH optima and the effects of Ca2+ and Mg2+ were similar for membrane-bound and solubilized delta 4-steroid 5 alpha-reductase in both the nuclear and the microsomal fractions. The results reported demonstrate that epididymal delta 4-steroid 5 alpha-reductase can be solubilized in an active and stable form with no significant changes in the kinetic characteristics of the enzyme after solubilization; furthermore, kinetic and molecular-size differences observed for the nuclear and the microsomal forms of the enzyme suggest that there may exist at least two forms of epididymal delta 4-steroid 5 alpha-reductase.     

Circadian rhythm of acid phosphatase activity in rat liver microsomes and dependence of NADH 5 alpha-reductase on phosphatase activity

The specific activity of acid phosphatase in male and female rats follows a circadian rhythm. Preincubation of liver microsomes with testosterone led to an increase of phosphatase activity and a loss of circadian rhythm. NADH 5 alpha-reductase was inactivated by several animal and bacterial acid and alkaline phosphatases while the acid phosphatase from potatoes was ineffective. The extent of inhibition depends on the course of circadian rhythm of NADH 5 alpha-reductase activity. Preincubation of microsomes in the presence of testosterone inhibited the NADH 5 alpha-reduction of testosterone. No such inhibition was observed after preincubation of microsomes with progesterone.     

5alpha-reductase isoenzymes 1 and 2 in the rat testis during postnatal development

The pubertal initiation of spermatogenesis is reliant on androgens, and during this time, 5alpha-reduced androgens such as dihydrotestosterone (DHT) are the predominant androgens in the testis. Two 5alpha-reductase (5alphaR) isoenzymes (5alphaR1 and 5alphaR2) have been identified, which catalyze the conversion of testosterone to the more potent androgen DHT. The present study aimed to investigate the developmental pattern of 5alphaR isoenzymes and their relationship to the production of 5alpha-reduced androgens in the postnatal rat testis. Both 5alphaR1 and 5alphaR2 isoenzyme mRNAs were measured by real-time polymerase chain reaction, isoenzyme activity levels by specific assays, and testicular androgens by radioimmunoassay after high-performance liquid chromatographic separation. Both 5alphaR1 and 5alphaR2 mRNAs and activity levels were low in the 10-day-old (prepubertal) testis, peaked between Days 20 and 40 during puberty, and then declined to low levels at 60-160 days of age. The developmental pattern of both 5alphaR isoenzyme activity levels was mirrored by the testicular production of 5alpha-reduced metabolites. Although 5alphaR1 was greater than 5alphaR2 at all ages, it is likely, given the substrate preferences of the two, that both isoenzymes contribute to the pubertal peak of 5alpha-reduced androgen biosynthesis. The peak in 5alphaR isoenzymes and 5alpha-reduced metabolite production coincided with the first wave of spermatogenesis in the rat, suggesting a role for 5alpha-reduced metabolites in the initiation of spermatogenesis. This was explored by acute administration of a 5alphaR inhibitor (L685,273) to immature rats. The L685,273 markedly suppressed testicular 5alphaR activity during puberty by 75%-86%. However, a marked increase was observed in testicular testosterone levels (in the absence of changes in LH), and no decrease was observed in the absolute levels of 5alpha-reduced metabolites. Therefore, whether the formation of DHT in the presence of low testosterone levels in the pubertal testis is required for the initiation of spermatogenesis cannot be tested using 5alphaR inhibitors. We conclude that both 5alphaR1 and 5alphaR2 isoenzymes are involved in the peak of 5alpha-reduced androgen biosynthesis in the testis during the pubertal initiation of spermatogenesis.     

Absence of 5 alpha-reductase in plasma membranes of the hypothalamus in male rats]

No 5alpha-reductase activity was found in plasmic membranes from male rats hypothalami. Contrary to all expectation, it was found that 5alpha-dihydrotestosterone which was synthetized in microsomes or nuclei, was accumulated in plasmic membranes. The significance of this fact is at the moment unknown.     

Selective inhibition of the 5 alpha-reductase of the rat epididymis.

The effect of several synthetic steroids belonging either to the 4-aza-3-oxo-steroid family or to androstene and androstane derivatives was investigated "in vitro" on the epididymal as well as prostatic 5 alpha-reductase activity. For this purpose rat caput epididymis and prostate were incubated with the different steroidal compounds at molar concentrations of 10(-7), 10(-6), and 10(-5) in the presence of labelled testosterone as substrate. The steroids 4-MA (17 beta, N,N-diethyl-carbamoyl-4-aza-5 alpha-androstan-3-one) and 4-OH-A (4-hydroxy-androstenedione), already known to be effective 5 alpha-reductase inhibitors at the level of the prostate, have been used as reference molecules. The 5 alpha-reductase activity was evaluated by measuring pg of dihydrotestosterone (DHT) formed in 2 h of incubation by mg of tissue. The steroids A, B, C, F, G and I inhibit the formation of DHT in the rat epididymis although to different extents; they are also equally effective on the formation of DHT in the rat prostate. The steroids D, E, H and L are devoid of any inhibitory property on the formation of DHT in both the rat epididymis and prostate. The most interesting results were obtained with compound M which exhibits a dose-dependent and significant inhibitory effect on the formation of DHT in the epididymis, but it is inactive at the level of the prostate. These findings suggest that it is possible (a) to selectively interfere with the 5 alpha-reductase of the epididymis without affecting that present in the prostate, and (b) consequently to envisage new ways to regulate male fertility.     

Localization of a 5alpha-reductase activity in the nuclear membranes of the anterior hypophysis of normal and castrated adult male rats]

A 5alpha-reductase activity may be found in purified nuclei from anterior pituitary of intact or castrated male rats. When nuclear membranes are separated from nucleoplams this enzymic activity is recovered in nuclear membranes. Following 7 days of castration, the 5alpha-reductase activity in nuclear membranes is increased by 105 % with regard to the activity in nuclear membranes from intact animals.     

Different mechanisms of regulation of nuclear reduced nicotinamide-adenine dinucleotide phosphate-dependent 3-oxo steroid 5alpha-reductase activity in rat liver, kidney and prostate

The regulatory mechanisms involved in the control of the nuclear NADPH-dependent 3-ketosteroid 5α-reductase (5α-reductase) activity were studied in liver, kidney and prostate. The substrate used was [1,2-³H]androst-4-ene-3,17-dione (androstenedione) (for liver and kidney) or [4-¹⁴C]androstenedione (for prostate). The hepatic nuclear 5α-reductase activity was greater in female than in male rats, was greater in adult than in prepubertal female rats, increased after castration of male rats, but was not affected by treatment with testosterone propionate or oestradiol benzoate. These regulatory characteristics are in part different from those previously described for the hepatic microsomal 5α-reductase. The renal nuclear metabolism of androstenedione, i.e. 5α reduction and 17β-hydroxy steroid reduction, was relatively unaffected by sex, age, castration and treatment with testosterone propionate. However, treatment of castrated male rats with oestradiol benzoate led to a significant increase in the 5α-reductase activity and a significant decrease in the 17β-hydroxy steroid reductase activity. Finally, the nuclear 5α-reductase activity in prostate was androgen-dependent, decreasing after castration and increasing after treatment with testosterone propionate. In conclusion, the nuclear 5α-reductase activities in liver, kidney and prostate seem to be under the control of distinctly different regulatory mechanisms. The hypothesis is presented that whereas the prostatic nuclear 5α-reductase participates in the formation of a physiologically active androgen, 5α-dihydrotestosterone, this may not be the true function of the nuclear 5α-reductase in liver and kidney. These enzymes might rather serve to protect the androgen target sites in the chromatin from active androgens (e.g. testosterone) by transforming them into less active androgens (e.g. 5α-androstane-3,17-dione and/or 5α-dihydrotestosterone).     

Testicular 3 alpha-hydroxysteroid oxidoreductase activity in the developing male rat.

In the testes, 17β-hydroxy-5α-androstan-3-one (dihydrotestosterone, DHT) is converted to 5α-androstane-3α,17β-diol (3α-diol) by the enzyme 3α-hydroxysteroid oxidoreductase (3α-HSO). This steroid has been shown to possess biological activity in the male rat. The secretion of 3α-diol is much greater in the prepubertal animal than in the adult. This study is designed to quantitate the activity of 3α-HSO in the cytosol fraction of testes from male rats throughout sexual development. Following homogenizatlon of whole testes, the 105,000 × g supernatant or cytosol fraction was incubated with ³H DHT and varying concentrations of unlabelled DHT in the presence of 0.25μm NADPH. The incubation was carried out at 34°C for 10 min at a pH of 7.4. The K_m of 3α-HSO in testicular cytosol was calculated to be 1.25μM. The specific activity of testicular cytosol 3α-HSO, expressed as pmoles of 3α-diol converted from DHT per min per mg testicular cytosol protein, was high in young rats from 10 to 22 days of age, and was followed by a decline between day 22 and 37, with activity remaining low throughout adulthood. Total testicular cytosol activity of 3α-HSO, expressed as nmoles of 3α-diol converted from DHT per min per pair of testes, gradually increased from day 10 to day 60 and remained high in the adult rat. In the post-pubertal period, a possible lack of available substrate, DHT, or possible endogenous testicular regulatory mechanisms acting on 3α-HSO activity might account for the actual decrease in 3α-diol concentration in the blood and testes of mature rats.