A novel transgenic model to characterize the specific effects of follicle-stimulating hormone on gonadal physiology in the absence of luteinizing hormone actions.

Gonadal function is wholly reliant on the two pituitary-derived gonadotropins, FSH and LH. Identifying the specific effects of FSH has been difficult because of the intimate relationship between LH and FSH action and inherent limitations of classic research paradigms. We describe a novel transgenic model to characterize the definitive actions of FSH alone, distinct from LH effects, created by combining transgenic FSH expression with the gonadotropin-deficient background of the hypogonadal (hpg) mouse. A tandem transgene construct encoding each alpha- and beta-subunit of human FSH, under the rat insulin II promoter, expressed biologically active heterodimers at serum levels, by immunoassay, equivalent to circulating FSH concentrations in fertile humans (0.1-25 IU/liter). Transgenic mice were crossed into the hpg mouse genotype to obtain LH-deficient animals secreting FSH alone. Testis weights of adult FSHxhpg mice were increased up to 5-fold, relative to nontransgenic hpg controls (P < 0.001). However, only transgenic males with serum FSH levels more than 1 IU/liter showed testis weights increased relative to hpg controls, indicating a physiological FSH threshold for the testicular response. Histology of enlarged FSHxhpg testes revealed round spermatids and sparse numbers of elongated spermatids, demonstrating that the testosterone-independent FSH response targeting the Sertoli cell can facilitate completion of meiosis and minimal initiation, but not completion, of spermiogenesis. Transgenic FSH also induced inhibin B secretion in FSHxhpg mice, but showed a distinct sexual dimorphism with only females exhibiting a strong FSH dose-dependent increase in serum inhibin B levels (r(2) = 0.84). In addition, ovaries of FSHxhpg females were enlarged up to 10-fold (P < 0.001), characterized by increased follicular recruitment and development to type 7 antral follicles. Thus, these findings show that the transgenic FSHxhpg mouse provides a unique model for detailed investigations of the definitive in vivo actions of FSH alone.

The promoter of murine follicle-stimulating hormone receptor: functional characterization and regulation by transcription factor steroidogenic factor 1.

The promoter of the FSH receptor (R) gene has been cloned from several species. Although some of its regulatory elements have been identified, its function still remains poorly characterized. Using transient transfections of luciferase reporter constructs, driven by various fragments of the murine (m) FSHR promoter, we identified a cell-specific promoter region. This domain is located in the distal part of the mFSHR promoter, -1,110 to -1,548 bp upstream of the translation initiation site, and it contains two steroidogenic factor 1 (SF-1) like binding sites (SLBS). The cellular levels of SF-1 mRNA and protein closely correlated in various steroidogenic cell lines with activity of the transfected mFSHR promoter/luciferase reporter construct carrying the distal activator domain. A dose-dependent increase in FSHR promoter activity was shown in nonsteroidogenic HEK 293 cells transiently transfected with SF-1 cDNA. SF-1 was found to bind to a nonconsensus 5'-CAAGGACT-3' SLBS-3 motif in the distal part of the promoter; formation of the SF-1/SLBS-3 complex could be reversed by addition of SF-1 antibody. Mutation in the SLBS-3 domain abolished the SF-1/SLBS-3 complex in gel-shift assays and led to a significant loss of SF-1-mediated mFSHR promoter activity. The second SLBS appeared to have minor role in SF-1-regulated mFSHR expression. In conclusion, we have identified a regulatory domain in the mFSHR promoter participating in the cell-specific regulation of FSHR expression. We demonstrated for the first time that the mFSHR promoter possesses functional SF-1 binding sites and thus belongs to the group of SF-1-regulated genes. These findings provide further evidence for the key role of SF-1 in the regulation of genes involved in gonadal differentiation and endocrine functions.

Regulation of cytochrome P450 aromatase gene expression in adult rat Leydig cells: comparison with estradiol production.

Regulation of aromatase gene expression in purified rat Leydig cells has not yet been investigated. Therefore, using a highly specific quantitative RT-PCR method, we have measured the amount of cytochrome P450 aromatase (P450arom) mRNA and aromatase activity in mature rat Leydig cells submitted to various treatments during 24 h. Estradiol production was enhanced in a dose-related manner in the presence of testosterone, the maximum (28% increase) being obtained with 200 ng/ml. Related to the P450arom mRNA levels, a decrease was observed in the presence of low concentrations (50 and 100 ng/ml) of testosterone, then a 20% increase of the amount of transcripts was recorded for the higher concentrations (200-500 ng/ml). The same result was obtained in the presence of 5alpha-dihydrotestosterone (an androgen resistant to aromatase activity). The addition of ovine LH (oLH; 0.1-50 ng/ml) to the Leydig cell culture medium induced a dose-related augmentation of estradiol output up to 10 ng/ml oLH, although a decrease was observed with 50 ng/ml when compared with maximal values. mRNA levels slightly decreased in the presence of low concentrations (0.1-1 ng/ml) of oLH, an effect that was abolished by the addition of testosterone; mRNA levels were increased by oLH (5-10 ng/ml) 35 and 75% respectively in the absence and presence of testosterone (when compared with Leydig cells incubated without treatment). With 50 ng/ml oLH, a large augmentation (twofold) of the P450arom mRNA level either without or with testosterone was observed. Dibutyryl cyclic AMP (1 mM) mimicked the effect of oLH. The half-life of the P450arom mRNAs was twofold increased in the presence of testosterone and oLH when compared with the half-life in the absence of treatment (5.8+/-0.6 h). Taken together, our data have demonstrated that, in freshly isolated Leydig cells from mature rat testes, the regulation of aromatase expression and enzymatic activity is under LH (through cyclic AMP) and steroid control; moreover seminiferous tubule-secreted factor(s) are also involved. Therefore, rat Leydig cell aromatase is controlled at both transcriptional and post-transcriptional steps by endocrine and/or locally produced modulators.

Adrenocortical tumorigenesis in transgenic mice: the role of luteinizing hormone receptor and transcription factors GATA-4 and GATA-61.

Transgenic (TG) mice, bearing the Simian Virus 40 T-antigen (Tag) under a 6-kb fragment of the murine inhibin alpha-subunit promoter (inhalpha), develop gonadal tumors of granulosa or Leydig cell origin with 100% penetrance by the age of 5-7 months. When these TG mice were gonadectomized prepubertally, between 21-25 days of life, adrenal gland tumors were observed in each mouse by the age of 5-7 months. No adrenal tumors were detected in any intact TG, gonadectomized or intact or control non-TG littermates. The adrenocortical tumors appeared to originate from the X-zone of the adrenal cortex. If functional gonadectomy was induced by GnRH antagonist treatment or by cross-breeding of the TG mice into hypogonadotropic hpg genetic background, neither gonadal nor adrenal tumorigenesis appeared. This prompted a hypothesis that adrenal tumor development in inhalpha/Tag TG mice is related to elevated gonadotropin secretion, which is the most obvious difference between the surgical and functional gonadectomy models. The adrenal tumors and a cell line (Calpha1) derived from them, was found to express luteinizing hormone receptor (LHR), but no FSHR, and hCG treatment stimulated their proliferation. No FSHR was found in the adrenal glands. On the basis of this it was suggested that expression of the potent oncogene T-antigen, allow LH in adrenocortical cells to function as a tumor promoter, and induction of high level functional LHR expression in adrenal tumors. Given the induction of expression and regulation of the GATA-4 and GATA-6 zinc finger family of transcription factors in the gonads by gonadotropins, it was in our interest to explore their expression in the adrenals. We utilized the inalpha/Tag TG mouse model and pathological human adrenal samples to explore the role of GATA-4 and GATA-6 in adrenocortical tumorigenesis. Abundant GATA-6 mRNA expression was found in normal control adrenal cortex during mouse development, whereas GATA-4 mRNA was undetectable. In striking contrast to this, GATA-6 was absent from murine adrenocortical tumors, while GATA-4 mRNA expression was dramatically upregulated in the murine adrenal tumors as well as in human adrenocortical carcinomas. Taken together, these results suggest different roles for GATA-4 and GATA-6 in the adrenal gland, and implicate GATA-4 in adrenal LHR expression and tumorigenesis. Immunohistochemical detection of GATA-4 may serve as a useful marker in differential diagnosis of human adrenal tumors. In addition, the inhalpha/Tag TG model will be helpful for exploring the molecular mechanisms underlying adrenocortical tumorigenesis, ectopic LHR expression in adrenals and the GATA-4/LHR interaction that is related to adrenal tumorigenesis in TG mice.

Aromatase expression in male germ cells.

The cytochrome P450 aromatase (P450arom) is the terminal enzyme responsible for the formation of estrogens from androgens. According to the age, aromatase activity has been measured in immature and mature rat Leydig cells, as well as in Sertoli cells whereas in pig, ram and human the aromatase is mainly present in Leydig cells. In the rat testis, we have immunolocalised the P450arom not only in Leydig cells but also in germ cells and especially in elongated spermatids. Related to the stage of germ cell maturation, we have shown that the level of P450arom mRNA transcripts decreases, it is much more abundant in younger than in mature germ cells whereas the aromatase activity is two- to four-fold greater in spermatozoa when compared to the two other enriched-germ cell preparations. Moreover, we have reported the existence of alternative splicing events of P450arom mRNA in pachytene spermatocytes and round spermatids giving rise to two isoforms lacking the last coding exon which, therefore, cannot encode functional aromatase molecules. In rat germ cells, the aromatase gene expression is not only under androgen control but also subjected to cytokine (TNFalpha) and growth factor (TGFbeta) regulation. In the bank-vole testis, we have evidenced a synchronisation between a fully developed spermatogenesis and a strong positive immunoreactivity for both P450arom and estrogen receptor (ERbeta) in spermatids. Therefore, the aromatase gene expression and its translation in a fully active protein in rodent germ cells evidence an additional site for estrogen production within the testis. Our recent data showing that human ejaculated spermatozoa expressed specific transcripts for P450arom reinforced the observations reported in germ cells of other mammalian species. Together with the widespread distribution of ERs in testicular cells these data bring enlightenments on the hormonal regulation of male reproductive function. Indeed these female hormones (or the ratio androgens/estrogens) do play a physiological role (either directly on germ cells or via testicular somatic cells) in the maintenance of male gonadal functions and obviously, several steps are concerned particularly the spermatid production and the epididymal sperm maturation.

Sources of oestrogen in the testis and reproductive tract of the male.

The cytochrome P450 aromatase (P450arom) is the terminal enzyme responsible for the irreversible transformation of androgens into oestrogens and is present in the endoplasmic reticulum of various tissues throughout at least the phylum of vertebrates. The CYP 19 gene is unique and its expression is regulated in a tissue and more precisely in a cell-specific fashion via the alternative use of several promoters located in the first exons. The P450arom has been immunolocalized in germ cells of the mouse, brown bear and rooster. According to age, aromatase activity has been measured in immature and mature rat Leydig cells as well as in Sertoli cells, whereas in the pig, ram and human aromatase is mainly present in Leydig cells. In the adult rat testis, four complementary approaches (RTPCR, in situ hybridization, immunocytochemistry and the tritiated water assay) demonstrate that not only somatic cells but also mature germ cells represent a source of oestrogen synthesis. Taking into account the widespread distribution of oestrogen receptors (ER alpha & ER beta) in testicular cells and the genital tract of the male on the one hand, and the cross-talk between sex steroids and growth factors, and between membrane receptors and nuclear receptors for steroids on the other hand, it is anticipated that understanding of the pathophysiological roles of these 'female' hormones in the male will advance understanding of the hormonal regulation of male reproductive function. One of the future goals is to define oestrogen-targeted genes in the male gonad and indeed, a lot of work is now focused on this specific area in order to clarify the role of oestrogens in the reproductive tract of the male as well as to elucidate the regulation of aromatase gene expression.

Follicle-stimulating hormone ligand and receptor mutations, and gonadal dysfunction.

In contrast to the general contention, infertility can be an inherited condition. Some of the genetic causes of male and female infertility have turned out to be due to inactivating mutations in the gonadotropin and gonadotropin receptor genes. The topic of the present text is to review current knowledge on mutations affecting the function of follicle-stimulating hormone (FSH). This gonadotropin, by binding to its specific G protein-coupled cell membrane receptor (FSHR), is important for normal gonadal function. Mutations affecting gonadotropin genes are extremely rare, but recent genetic studies have revealed that the pathogenesis of subfertility or infertility can be due to mutations in the FSH receptor (FSHR) gene. While mutations affecting FSHR are sporadic, polymorphism of the FSHR gene seems to be a common phenomenon. To date, six inactivating and only one activating mutation have been detected in the FSHR gene. In contrast to LHR gene, the majority of these mutations affect the extracellular domain of the receptor. Together with animal models using the transgenic and knock-out approaches, systematic analysis of alterations in the FSHR gene increases our knowledge on the structure and function of the FSHR and demonstrates that the integrity of each FSHR segment is required for proper expression of the fully active protein and for normal gonadal function. Mutations in the FSHR gene have different consequences in the reproductive function depending on the sex of the patient: while normal ovarian function is critically dependent on FSH, male fertility is possible with minimal or absent FSH action.

[Male germ cells. A new source of estrogens in the mammalian testis]. / Les cellules germinales mâles. Une nouvelle source d'estrogènes dans le testicule des mammifères.

Cytochrome P450 aromatase (P450arom), which catalyzes irreversible transformation of androgens into estrogens, has been immunolocalized in mouse, brown bear and rooster germ cells. In the immature rat, P450arom is found in Sertoli cells while in the mature rat it is found in Leydig cells. In the pig, ram, and human, it is mainly present in Leydig cells. Our purpose was first to investigate the testicular presence of cytochrome P450arom mRNA in adult rat germ cells using RT-PCR. The amplified product from germ cells showed 100% homology with the corresponding fragments of the rat ovary cDNAs and was detectable not only in rat Leydig and Sertoli cells but also in pachytene spermatocytes, round spermatids and testicular spermatozoa. In purified Leydig cells and pachytene spermatocytes the P450arom mRNA level was 10-fold higher than in Sertoli cells. The amount of P450arom mRNA transcript decreased according to the stage of germ cell maturation, being more elevated in younger than in mature germ cells. By contrast, the aromatase activity in the microsomal fractions was 2- to 4-fold greater in spermatozoa than in the other enriched germ cell preparations studied. We also demonstrated the presence of a 55kDa protein in a mixed germ cell preparation and have been able to immunolocalize the P450arom on mature rat testicular slices, namely in Leydig cells and elongated spermatids. The overall data confirm the presence of a functional cytochrome P450arom in the male rat testis and consequently, the existence of an additional source of estrogens within the genital tract of the male which may likely suggest a physiological role for these hormones in the regulation of spermatogenesis.

Alternative splicing events in the coding region of the cytochrome P450 aromatase gene in male rat germ cells.

Expression of cytochrome P450 mRNA in rat germ cells was characterized by reverse transcription PCR with various primers located at the 3'-end of the coding region. At least two unusual isoforms (Ex10-S and INT) of P450 aromatase (P450arom) mRNA were expressed. Analysis of their sequences demonstrated that an alternative splicing event occurred first at the exon-intron boundary of the GT consensus sequence of the last coding exon, and second in the internal 5' donor inside exon 9 used as a minor cryptic splicing site. These isoforms lacked the last coding exon which contained the heme-binding domain; in addition, for the Ex10-S transcript, the catalytic domain was also absent because of a frameshift in the open reading frame. The deduced amino acid sequences led to truncated P450arom polypeptides without the heme-binding domain, which were probably unable to convert androgens into estrogens. Adult rat germ cells are able to express P450arom mRNA, which is then translated into a biologically active enzyme which is involved in estrogen production. Moreover, for the first time, we report the existence of alternative splicing events of P45Oarom mRNA in pachytene spermatocytes and round spermatids, which probably cannot encode functional aromatase molecules.

Expression and immunolocalization of functional cytochrome P450 aromatase in mature rat testicular cells.

Aromatase activity has been measured in Leydig cells and Sertoli cells from both immature and mature rats. Cytochrome P450 aromatase (P450arom) has been immunolocalized in germ cells of the rodent, bear, and rooster. Our purpose was to investigate expression of and to immunolocalize P450arom in adult rat testicular cells. After Western blotting with a specific anti-cytochrome P450arom antibody, we demonstrated the presence of a 55-kDa protein in mature rat seminiferous tubules and crude germ cell preparations. Immunoreactive aromatase was detected both in cultured rat Leydig cells and in testis sections (interstitial tissue and elongated spermatids showed positive immunoreactivity for P450arom). We next used reverse transcription-polymerase chain reaction to localize and quantify the P450arom mRNA in the various testicular cells. In rat Leydig cells, the amount of P450arom mRNA was 15 times higher than in Sertoli cells (34.1+/-3.2 to 2.3 +/-0.2 x 10(-3) amol/10(6) cells, respectively). In pachytene spermatocytes, round spermatids, and testicular spermatozoa the P450arom mRNA levels were 38.7+/-8.1, 20.4+/-3.8, and < 1.3 x 10(-3) amol/10(6) cells, respectively. The aromatase activity was 2.5-4 times higher in testicular spermatozoa (8.48+/-1.98 fmol/10(6) cells per hour) than in other germ cells. These results indicate that in mature rats, not only Leydig cells and Sertoli cells but also germ cells have the capacity to express functional P450arom. According to the germ cell maturation state, there was an inverse relationship between P450arom mRNA content and the biological activity of the protein. The expression of the functional P450arom in mature rat germ cells confirms the existence of an additional source of estrogens within the genital tract of the male.

[In vitro gene expression of aromatase in rat testicular cells]. / Expression in vitro du gène de l'aromatase dans les cellules testiculaires du rat.

The ability of the male gonad to convert androgens into estrogens is well known; the microsomal enzymatic complex involved in this transformation is named aromatase and is composed of a specific cytochrome P450 aromatase (P450arom) and a ubiquitous reductase. Using a highly specific RT-PCR method we have measured the amount of P450arom mRNA in purified Leydig and Sertoli cells prepared from 20, 40 and 70-80 day-old rats. The amount of P450arom mRNA in the Leydig cells is independent of age (40 x 10(-3) attomoles/micrograms of total RNA); in contrast, in the immature rat Sertoli cells, after 5 days of culture the amount of P450arom mRNA is 20-fold lower when compared to that of 20-day-old rat Sertoli cells (71 x 10(-3) attomoles/micrograms of total RNA). Nevertheless, irrespective of the age, the addition of either FSH or dbcAMP for 6 h increases the level of P450arom mRNA in the rat Sertoli cell preparations. Therefore, we evidenced that during testicular maturation not only the Leydig cells but also the Sertoli cells of the rat have the capacity to express the gene for cytochrome P450 aromatase.

Cytochrome P450 aromatase in male germ cells.

The ability of the male gonad to convert androgens into estrogens is well known; the microsomal enzymatic complex involved in this transformation is named aromatase and is composed of a specific cytochrome P450 aromatase (P450arom) and an ubiquitous reductase. According to age, aromatase activity has been already measured in immature and mature rat Leydig cells as well as in Sertoli cells. Recently, in different studies, a cytochrome P450arom has even been immunolocalized not only in Leydig cells but also in germ cells of mouse, brown bear and rooster whereas in pig, ram and human the aromatase is mainly present in Leydig cells. Our purpose was to investigate the testicular cell distribution of cytochrome P450arom mRNA in adult rat using RT-PCR. With two highly specific primers located on exons 8 and 9, we have been able to amplify a 289 bp aromatase fragment not only in Leydig cells and Sertoli cells but also in highly-enriched preparations of pachytene spermatocytes, round spermatids and testicular spermatozoa. These amplified products showed 100% homology with the corresponding fragment of the rat ovary cDNA. In parallel, using an anti-human cytochrome P450arom antibody we have demonstrated the presence of a 55 kDa protein in seminiferous tubules and crude germ cells (pachytene spermatocytes and round spermatids) of the mature rat. After incubation with tritiated androstenedione, the aromatase activity in the microsomal fractions of purified testicular spermatozoa was 2.96 pmoles/mg/h and was found to be 5-fold higher when compared to that of either purified pachytene spermatocytes or round spermatids. Using a quantitative RT-PCR method with a standard cDNA 29 bp shorter, we have compared the amount of cytochrome P450arom mRNA in mature rat Leydig cells and Sertoli cells. In purified Leydig cells from mature rats the P450arom mRNA level was: 36 x 10(-3) amoles/microgram RNA whereas in Sertoli cells the mRNA level was 10 fold lower. In pachytene spermatocytes, round spermatids and testicular spermatozoa the P450arom mRNA levels were respectively 367, 117 and < 1 x 10(-3) amoles/microgram RNA. Therefore, we evidenced that not only the Leydig cells but also the Sertoli cells of the rat during the testicular maturation have the capacity to express the gene of the cytochrome P450 aromatase. More importantly a biologically active cytochrome P450 aromatase is also present in germ cells (pachytene spermatocytes, round spermatids and spermatozoa). The existence of an additional source of estrogens within the genital tract of the male is now well documented and that suggests a putative role for these hormones during the male germ cell development and maturation not only in the testis but also in the epididymis.