Differential regulation of rat testicular 5alpha-reductase type 1 and 2 isoforms by testosterone and FSH.

Testosterone is metabolised to the more potent androgen, dihydrotestosterone, by the 5alpha-reductase (5alphaR) enzyme. We previously showed that 5alpha-reduced androgens are important for maintaining androgen action on rat spermatogenesis when testicular testosterone concentrations are reduced. This study investigated expression and activity of the 5alphaR isoforms, type 1 (5alphaR-1) and type 2 (5alphaR-2), in the rat during hormone manipulation in order to understand the factors that regulate the testicular concentration of 5alphaR and testicular 5alpha-reduced androgen biosynthesis. Testicular 5alphaR-1 and 5alphaR-2 mRNA and enzyme activity were measured by real-time PCR and specific enzyme assays respectively. Hormone levels were first suppressed using two models of gonadotrophin suppression: testosterone and oestradiol treatment (LH/testosterone deficiency) or GnRH immunisation (LH/testosterone and FSH deficiency). Hormones were then either restored or suppressed for 6 days by a variety of hormonal treatments. 5alphaR-1 mRNA and enzyme activity increased when testosterone was suppressed, yet restoration of testosterone decreased 5alphaR-1 mRNA and enzyme activity, suggesting that testosterone negatively regulates 5alphaR-1. suppression of FSH decreased 5alphaR-1 mRNA yet FSH administration increased 5alphaR-1 mRNA, but no changes in 5alphaR-1 activity were observed within the 6 day period. In contrast to 5alphaR-1, testosterone did not affect the testicular concentration of 5alphaR-2 mRNA or activity, but there was evidence for modulation of 5alphaR-2 activity by FSH. Measurement of testicular androgens revealed that 5alphaR-1 was primarily responsible for the production of 5alpha-reduced metabolites. It is concluded that the 5alphaR isoforms in rat testis are differentially regulated by testosterone and FSH: testosterone negatively regulated 5alphaR-1 mRNA and enzyme activity but had no affect on 5alphaR-2, whereas FSH positively regulated 5alphaR-1 mRNA and appeared to regulate 5alphaR-2.

Identification of specific sites of hormonal regulation in spermatogenesis in rats, monkeys, and man.

A detailed understanding of the hormonal regulation of spermatogenesis is required for the informed assessment and management of male fertility and, conversely, for the development of safe and reversible male hormonal contraception. An approach to the study of these issues is outlined based on the use of well-defined in vivo models of gonadotropin/androgen deprivation and replacement, the quantitative assessment of germ cell number using stereological techniques, and the directed study of specific steps in spermatogenesis shown to be hormone dependent. Drawing together data from rat, monkey, and human models, we identify differences between species and formulate an overview of the hormonal regulation of spermatogenesis. There is good evidence for both separate and synergistic roles for both testosterone and follicle-stimulating hormone (FSH) in achieving quantitatively normal spermatogenesis. Based on relatively selective withdrawal and replacement studies, FSH has key roles in the progression of type A to B spermatogonia and, in synergy with testosterone, in regulating germ cell viability. Testosterone is an absolute requirement for spermatogenesis. In rats, it has been shown to promote the adhesion of round spermatids to Sertoli cells, without which they are sloughed from the epithelium and spermatid elongation fails. The release of mature elongated spermatids from the testis (spermiation) is also under FSH/testosterone control in rats. Data from monkeys and men treated with steroidal contraceptives indicate that impairment of spermiation is a key to achieving azoospermia. The contribution of 5alpha-reduced androgens in the testis to the regulation of spermatogenesis is also relevant, as 5alpha-reduced androgens are maintained during gonadotropin suppression and may act to maintain low levels of germ cell development. These concepts are also discussed in the context of male hormonal contraceptive development.

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.

Testosterone-dependent restoration of spermatogenesis in adult rats is impaired by a 5alpha-reductase inhibitor.

Germ cell development (spermiogenesis in particular) in the adult rat is known to be testosterone dependent. Recently we proposed a role for the 5alpha reduction of testosterone to dihydrotestosterone (DHT) in the short-term restoration of round spermatid maturation when testicular testosterone levels are experimentally lowered. The current study aimed to further characterize the involvement of 5alpha-reductase in the restoration of spermatogenesis by investigating the short- and long-term restoration of specific germ cell populations by testosterone in the presence or absence of a 5alpha-reductase inhibitor (L685,273). Spermatogenesis in adult rats was suppressed for 8 weeks using 3-cm testosterone and 0.4-cm estradiol silastic implants (testosterone-estradiol [TE] treatment); spermatogenesis was then restored by administration of increasing doses of testosterone with or without a competitive 5alpha-reductase inhibitor or with the androgen receptor antagonist flutamide. Animals were then killed after either 4 days or 6 weeks of treatment so that we could study the short- and long-term restorations of spermatogenesis. Stereological analysis showed that germ cell development between late pachytene spermatocytes to round spermatids in stage VII during either short- or long-term restoration was not affected by 5alpha-reductase inhibition, but it was affected by flutamide. The conversion of round spermatids between stages VII and VIII was restored by testosterone treatment, but this restoration was prevented by flutamide. Both the short- and long-term restorations of this midspermiogenic event were significantly decreased when 5alpha-reductase was inhibited. After long-term restoration of spermatogenesis, elongated spermatids were restored to 42% of control but were significantly suppressed to 20% of control by coadministration of the 5alpha-reductase inhibitor because of a reduction in the number of round spermatids progressing between stages VII and VIII. The results demonstrate that the 5alpha-reduction of testosterone is particularly important for progression through midspermiogenesis, because this phase of germ cell development is more sensitive to withdrawal of androgens. We suggest that testicular 5alpha-reductase activity is important for the restoration or maintenance of low levels of sperm production in a hormonally based contraceptive setting.