FSHR ablation induces depression-like behaviors.

Alteration in reproductive hormones profile is associated with the increasing risk of menopausal depression in women. Serum follicle-stimulating hormone (FSH) level is changed during the menopause transition, while the effect of FSH on menopausal depression has remained undefined. In this study we investigated whether or how FSH affected menopausal depression in postmenopausal (ovariectomized) FSHR knockout mice (Fshr-/-). We found that Fshr-/- mice displayed aggravated depression-like behaviors, accompanied by severe oxidative stress in the whole brain, resulted from significantly reduced glutamate cysteine ligase modifier subunit (GCLm) in glutathione synthesis and glucose-6-phosphate dehydrogenase (G6PD) in NADP/NADPH transition. Importantly, administration of ROS scavenger N-acetyl cysteine (NAC, 150 mg · kg-1 · d-1, i.p. for 12 weeks) attenuated the depression-like behaviors of Fshr-/- mice. Consistent with these in vivo experiment results, we found that pretreatment with FSH (50, 100 ng/mL) dose-dependently increased protein levels of GCLm and G6PD, and decreased the ROS production in N2a mouse neuroblastoma cells. These findings demonstrate that FSH signaling is involved in pathogenesis of menopausal depression, and likely to maintain the redox-optimized ROS balance in neurons.

Novel hormone-regulated genes in visceral adipose tissue: cloning and identification of proinflammatory cytokine-like mouse and human MEDA-7: implications for obesity, insulin resistance and the metabolic syndrome.

AIMS/HYPOTHESIS: We sought to characterise novel genes dysregulated by sex hormonal imbalances that induce obesity and metabolic disorder in a setting of oestrogen deficiency and androgen dominance in follicle-stimulating hormone receptor (For [also known as Fshr]) knockout female mice. METHODS: Transcriptome analysis of mesenteric adipose tissue (MAT) of mutants revealed novel genes. One novel gene named Meda-7 was selected for study. Meda-7 was cloned from mouse and human adipose tissue; its expression, hormonal regulation and function were characterised. RESULTS: Mouse Meda-7 is richly expressed in deep visceral adipose tissue and encodes a 22 kDa secreted protein with 71% homology to human mesenteric oestrogen-dependent adipose gene- 7 (MEDA-7) protein. Both have six conserved cysteines like many cytokines. In obese patients, MEDA-7 is more abundant in omental than subcutaneous fat. Meda-7 is downregulated in For-knockout female MAT at 5 months (obese state) followed by steep upregulation at 9 months (prediabetic condition) when mutants progress towards the metabolic syndrome. Meda-7 is expressed predominantly in the stromal-vascular cell fraction. In this fraction,M1-proinflammatorymacrophages are rich in Meda-7. Meda-7 dysregulation in 5-month-old For-knockout MAT is restored by oestrogen, but treatment has no effect in older mutants. Overabundance of MEDA-7 in HEK-293 cells enhances cell proliferation via p42/44 mitogen-activated protein kinases. Secreted MEDA-7 attenuates insulin-stimulated glucose uptake in 3T3-L1 adipocytes, while downregulating glucose transporter-4 and upregulating both monocyte chemotactic protein-1 and suppressor of cytokine signalling-3. Downstream activity of the insulin signalling mediator, phospho-AKT, is also downregulated. CONCLUSIONS/INTERPRETATION: MEDA-7 is a hormone-regulated adipokine/proinflammatory cytokine that is implicated in causing chronic inflammation, affecting cellular expansion and blunting insulin response in adipocytes.

Impairments of heat shock protein expression and MAPK translocation in the central nervous system of follitropin receptor knockout mice.

The central nervous system is exposed to the chronic oxidative stress during aging when the endogenous defence weakens and the load of reactive oxygen species enhances. Sex hormones and heat shock proteins (Hsps) participate in these responses to stress. Their regulation is disturbed in aging. We assessed the expression of Hsps in hippocampus and cortex of follitropin receptor knockout (FORKO) mice, known to exhibit gender and age-dependent imbalance in sex steroids and gonadotropins. These imbalances could contribute to an impaired regulation of Hsps thereby increasing the risk of developing neurodegenerative disorders. Our study shows that, in the hippocampus the expression of Hsp70 and Hsp25 was reduced in 20-month-old FORKO mice. However, in the cortex both Hsps were significantly down regulated only in elderly females. There is a well-established co-regulation between Hsps and mitogen-activated protein kinases (MAPKs). Significant, gender-specific impairments in the translocation of phosphorylated ERK and JNK were found in the CNS structures in aged FORKO mice. Our results suggest that hormonal imbalances lead to a disturbed subcellular distribution of activated MAPKs which contribute to the impairments of signal transduction networks maintaining normal physiological functions in the cortex and hippocampus that are associated with neurodegenerative changes in aging.

Mutations along the pituitary-gonadal axis affecting sexual maturation: novel information from transgenic and knockout mice.

During the last 10 years, numerous activating and inactivating mutations have been detected in the genes encoding the two gonadotrophins, luteinising hormone (LH) and follicle-stimulating hormone (FSH), as well as their cognate receptors (R), LHR and FSHR. Because activation of the hypothalamic-pituitary-gonadal axis is a crucial event in the onset and progression of puberty, mutations affecting gonadotrophin action have major influence on this developmental process. Many of the phenotypic effects observed have been expected on the basis of the existing information about gonadotrophin action (e.g. delayed puberty), but also many unexpected findings have been made, including the lack of phenotype in women with activating LHR mutations, and the discrepancy in phenotypes of men with inactivating mutations of FSHbeta (azoospermia and infertility) and FSHR (oligozoospermia and subfertility). Some of the possible mutations, such as inactivating LHbeta and activating FSHR mutations in women, have not yet been detected. Genetically modified mice provide relevant phenocopies for the human mutations and serve as good models for studies on molecular pathogenesis of these conditions. They may also predict phenotypes of the mutations that have not yet been detected in humans. We review here briefly the effects of gonadotrophin subunit and receptor mutations on puberty in humans and contrast the information with findings on genetically modified mice with similar mutations.

Differential expression of claudin family proteins in mouse ovarian serous papillary epithelial adenoma in aging FSH receptor-deficient mutants.

Ovarian cancer is a deadly disease with long latency. To understand the consequences of loss of follicle-stimulating hormone receptor (FSH-R) signaling and to explore why the atrophic and anovulatory ovaries of follitropin receptor knockout (FORKO) mice develop different types of ovarian tumors, including serous papillary epithelial adenoma later in life, we used mRNA expression profiling to gain a comprehensive view of misregulated genes. Using real-time quantitative reverse transcription-polymerase chain reaction, protein analysis, and cellular localization, we show, for the first time, in vivo evidence that, in the absence of FSH-R signaling, claudin-3, claudin-4, and claudin-11 are selectively upregulated, whereas claudin-1 decreases in ovarian surface epithelium and tumors in comparison to wild type. In vitro experiments using a mouse ovarian surface epithelial cell line derived from wild-type females reveal direct hormonal influence on claudin proteins. Although recent studies suggest that cell junction proteins are differentially expressed in ovarian tumors in women, the etiology of such changes remains unclear. Our results suggest an altered hormonal environment resulting from FSH-R loss as a cause of early changes in tight junction proteins that predispose the ovary to late-onset tumors that occur with aging. More importantly, this study identifies claudin-11 overexpression in mouse ovarian serous cystadenoma.

Age-related neurodegenerative changes in the central nervous system of estrogen-deficient follitropin receptor knockout mice.

Age-related neurodegenerative conditions are characterized by neuronal death and degeneration that lead to a progressive functional decline. Among the factors influencing degenerative processes during aging are altered levels of neurotrophic ovarian steroid 17beta-estradiol (E2). The follitropin receptor knockout (FORKO) female mouse displays hormonal imbalance characterized by very low levels of circulating E2 and high levels of testosterone. FORKO mice (24 days and 20 months) were used to investigate structural and functional changes in the central nervous system. We now show that the lifelong depletion of the sex hormone E2 in female FORKO mice correlates with abnormal behavior associated with defined alterations in brain morphology early in life, especially in aged animals. Immunohistochemical studies showed significant increases in the size and number of immunoreactive glial fibrillary acidic protein glial cells found in several brain regions (cortex and hippocampus) and a dramatic decline in estrogen receptors alpha and beta in the amygdala of FORKO females. These changes were associated with increased signs of anxiety in these animals. In the present study, we provide evidence that the chronic depletion of sex hormone E2 from early development leads to neural impairments in adult and aged FORKO mice that are associated with hypertrophy of glial cells, cell loss in distinct brain regions, and abnormal behavior. We suggest that the hormonal imbalance found in the female FORKO mouse provides an experimental paradigm for the study of morphological correlates of the behavioral changes that often accompany menopause in women.

The menopausal mouse: a new neural paradigm of a distressing human condition.

Progressive and long-term sex hormone imbalance in the FSH-R haploinsufficient menopausal mouse leads to degenerative changes in the CNS associated with increased anxiety. The brain region most affected by aging in these mice is the hippocampus. Choline acetyltransferase (ChAT) enzymatic activity and synapsin immunoreactivity are reduced at 20 months of age. Neurons in the dentate gyrus show signs of progressive degenerative changes, hypertrophy and glyosis, and subsequent cell shrinkage and death. These results suggest that the menopausal mouse mimics degenerative changes in the hippocampus of hormonally imbalanced aging humans. We propose using this animal model to test the effectiveness of potential therapeutics in paradigms of accelerated aging.

Developmental and molecular aberrations associated with deterioration of oogenesis during complete or partial follicle-stimulating hormone receptor deficiency in mice.

Targeted disruption of the mouse FSH receptor gene (FSH-R) that mediates the action of the FSH results in a gene dose-related ovarian phenotype in the developing as well as the adult animal. While null females (FORKO) are sterile, the haplo-insufficient mice experience early reproductive senescence. The purpose of this study was to first record changes in oocyte development in the null FORKO and haplo-insufficient mice. Oocyte growth is significantly retarded in the null mutants with thinner zona pellucida in preantral follicles, but thicker zona pellucida in secondary follicles. This morphometric change indicates developmental aberrations in coordination of the germ cell (oocyte) and the somatic granulosa cell (GC) compartments. Markers for primordial germ cell proliferation and oocyte growth, such as the c-Kit/Kit-ligand and bone morphogenetic protein-15 (BMP-15) were downregulated in both null and +/- ovaries, suggesting disrupted communication between oocyte and GCs. Extensive changes in the expression of other oocyte-specific gene products like the zona pellucida glycoproteins (zona pellucida A, B, and C) indicate major alteration in the extracellular matrix surrounding the germ cells. This led to leaky germ cells that allowed infiltration of somatic cells. These results show that the loss of FSH-R signaling alters the follicular environment, where oocyte-granulosa interactions are perturbed, creating an out-of-phase germ cell and somatic cell development. We believe that these data provide an experimental paradigm to explore the mechanisms responsible for preserving the structural integrity and quality of oocytes at different ages.

Failure of normal Leydig cell development in follicle-stimulating hormone (FSH) receptor-deficient mice, but not FSHbeta-deficient mice: role for constitutive FSH receptor activity.

Previous studies have suggested that FSH may be involved in regulation of Leydig cell function. We have examined this directly using two mouse models with null mutations in either the FSH beta-subunit (FSHbetaKO mice) or the FSH receptor (FSHRKO mice). Circulating LH levels were normal in adult FSHbetaKO mice, but were significantly increased in FSHRKO mice. Intratesticular testosterone levels increased normally in FSHbetaKO mice from birth to adulthood, whereas testosterone levels in FSHRKO mice failed to increase normally after puberty and were significantly reduced in adult animals. This was associated with reduced levels of mRNA encoding cytochrome P450 side-chain cleavage, 3beta-hydroxysteroid dehydrogenase type VI, and steroidogenic acute regulatory protein in FSHRKO mice. Leydig cell number was normal in FSHbetaKO mice during development, but in FSHRKO mice Leydig cell number increased slowly after puberty and was significantly reduced in the adult animal. Transfection studies showed that the FSHR exhibits constitutive activity in the absence of agonist stimulation. The results indicate, therefore, that Sertoli cells regulate the development of Leydig cell number and that constitutive activity within the FSHR is sufficient to stimulate this process. The presence of the hormone itself is not required when circulating LH levels are adequate.

Chronic estrogen deficiency leads to molecular aberrations related to neurodegenerative changes in follitropin receptor knockout female mice.

The follitropin receptor knockout (FORKO) mouse undergoes ovarian failure, thereby providing an animal model to investigate the consequences of the depletion of circulating estrogen in females. The estrogen deficiency causes marked defects in the female reproductive system, obesity, and skeletal abnormalities. In light of estrogen's known pleiotropic effects in the nervous system, our study examined the effects of genetically induced estrogen-testosterone imbalance on this system in female FORKO mice. Circulating concentrations of 17-beta-estradiol (E2) in FORKO mice are significantly decreased (FORKO -/-: 1.13+/-0.34 pg/ml; wild-type +/+: 17.6+/-3.5 pg/ml, P<0.0001, n=32-41); in contrast, testosterone levels are increased (-/-: 37.7+/-2.3 pg/ml; wild-type +/+: 3.9+/-1.7 pg/ml, P<0.005, n=25-33). The focus was on the activities of key enzymes in the central cholinergic and peripheral nervous systems, on dorsal root ganglia (DRGs) capacity for neurite outgrowth, and on the phosphorylation state of structural neurofilament (NF) proteins. Choline acetyltransferase activity was decreased in several central cholinergic structures (striatum 50+/-3%, hippocampus 24+/-2%, cortex 12+/-3%) and in DRGs (11+/-6%). Moreover, we observed aberrations in the enzymatic activities of mitogen-activated protein kinases (extracellular-regulated kinase and c-Jun N-terminal kinase) in the hippocampus, DRGs, and sciatic nerves. Hippocampal and sensory ganglia samples from FORKO mice contained hyper-phosphorylated NFs. Finally, explanted ganglia of FORKO mice displayed decreased neurite outgrowth (20-50%) under non-treated conditions and when treated with E2 (10 nM). Our results demonstrate that genetic depletion of circulating estrogen leads to biochemical and morphological changes in central and peripheral neurons, and underlie the importance of estrogen in the normal development and functioning of the nervous system. In particular, the findings suggest that an early and persisting absence of the steroid leads to neurodegenerative changes and identify several key enzymes that may contribute to the process. This model provides a system to explore the consequences of circulating estrogen deprivation and other hormonal imbalances in the nervous system.

Emergence of uterine pathology during accelerated biological aging in FSH receptor-haploinsufficient mice.

A fully functional FSH receptor (Fshr) is required for ovarian follicular development and fertility. Fshr null females are sterile because of failure of follicular maturation, ovulation, and estrogen deficiency. Because Fshr-haploinsufficient females also begin to show age-dependent reproductive deficits that mimic biological aging, we have investigated the changes that occur in the uterus of these mice. The uterine weight in 12-month-old Fshr +/- mice increased 2-fold, and most retired breeders (those that stopped breeding earlier than our wild-type females) developed unilateral uterine masses that appeared similar to several abnormalities that also occur in women and associated with infertility. Curiously, there was a tendency for most of the abnormality to occur in the right horn. Up to 25% of the virgin Fshr-haploinsufficient mice also developed pathology. These transformations were not present in either wild-type mice or the estrogen-deficient Fshr null females at any age. In haploinsufficient females, estrogen and progesterone were reduced and testosterone was elevated in circulation by 1 yr. Fshr-haploinsufficient mice developed an imbalance of progesterone receptor isoforms A and B in the uterus. This alteration of progesterone receptors along with an increase in LH receptors in the uterus may contribute to the induction of high frequency of uterine pathology. Angiogenesis, vascular abnormality, and adenomyosis appeared to be increased in the uterine horn bearing pathological mass. The Fshr-haploinsufficient mice might help in understanding the molecular basis of induction of uterine pathology and tissue patterning.

The FORKO mouse as a genetic model for exploring estrogen replacement therapy.

OBJECTIVE: To evaluate how chronically estrogen deficient female FORKO mice with genetic disruption of the FSH receptor respond to estrogen therapy. STUDY DESIGN: Subcutaneous estrogen agonist or antagonist therapy was initiated to study reproductive tissue response, adipose tissue mass and plasma lipid profiles. RESULTS: Within 36-48 hours of agonist administration, the classic measures of estrogenic activity were evident in the uterus and vagina. Older animals also responded to therapy during a 10-day period, indicating that estrogen receptor signaling systems are unaffected by aging. In these obese mutants, this short treatment decreased adipose tissue in all areas and corrected lipid abnormalities. Tamoxifen, a nonsteroidal mixed estrogen agonist and antagonist, had marginal effects on the uterus and body fat of FORKO mice, indicating differences in interaction. CONCLUSION: In FORKO mice lacking ovarian estrogen, the receptors remain fully functional. Hence, this is a useful model for studying estrogen replacement therapy and helps resolve questions related to efficacy and actions.

Functional characterization of the human FSH receptor with an inactivating Ala189Val mutation.

An Ala189Val mutation of the human FSH receptor (FSHR) has been found to cause hypergonadotrophic ovarian failure with arrest of follicular maturation in women, and suppressed spermatogenesis in men. We have now characterized the molecular mechanisms of the receptor inactivation. Wild-type and mutant FSHR cDNAs were expressed in monkey kidney (COS-7) cells and murine granulosa tumour (KK-1) cells. Similar steady-state levels of FSHR mRNA were found in COS-7 and KK-1 cells transfected with both types of FSHR cDNA. Conspicuously, immunofluorescence and confocal microscopy studies revealed that whereas the wild-type receptor could be readily detected on the plasma membrane, most of the mutated protein was intracellularly sequestered. Ligand binding studies confirmed the greatly reduced cell surface expression of the mutant FSHR. A low level of mutated receptors were expressed at the cell surface, as shown by ligand binding and cAMP response. The capacity of these receptors to evoke another second messenger response, that of inositol trisphosphate (IP3), was almost totally lost. This finding may be related to the clinical picture of the patients, i.e. blockade of follicular maturation. There is a highly conserved stretch of five amino acids (Ala-Phe-Asn-Gly-Thr) in the region of the mutation in all glycoprotein hormone receptors. We therefore created the same Ala to Val transition in the human LHR and studied its functional consequences. Similar functional alterations, i.e. intracellular sequestration and attenuated signal transduction, were found, as with mutated FSHR. Hence, this particular mutation in the conserved extracellular region of glycoprotein hormone receptors induces a conformational change that suppresses cell membrane targeting of the mutated receptor, probably through altered intracellular folding.

The role of follicle-stimulating hormone in spermatogenesis: lessons from knockout animal models.

The development of knockout mouse models for the FSH-beta subunit, the FSH receptor, and LH-receptor performed in different laboratories has confirmed and extended our knowledge concerning the critical role of these hormone-signaling systems in spermatogenesis. In this article, we summarize the phenotypic changes observed in male FSH receptor knockout (FORKO) mice. Young FORKO males have underdeveloped testis with 50% reduction in Sertoli cells, suggesting that FSH-R signaling is required very early for gonadal development, maturity, and function. These mice experience delayed puberty with postponement in the formation of round spermatids. Adult males show reduction in serum testosterone levels despite normal circulating LH concentration, indicating disturbances in Sertoli-Leydig cell communication. As a consequence of reduced sperm production and sperm quality, adult FORKO males have reduced fertility. Aberrant sperm from FORKO males have retention of cytoplasmic droplets and inadequate DNA compaction, hallmarks of infertility in many species including man. Interestingly, these changes are also experimentally inducible in FSH- and/or FSH-R-immunized male bonnet monkeys, creating a state of infertility. Reports of human mutations in FSH-beta and the FSH receptor also indicate that spermatogenesis is dependent on this system. Further investigations in FORKO males should be helpful in uncovering the downstream genes involved in sustaining Sertoli cell function and maintenance of the quantitative and qualitative aspects of spermatogenesis. This might pave the way for treatment of male infertility and contraception.

O papel dos receptores das gonadotrofinas na reproduçäo feminina / Role of gonadotropins receptors in female reproduction

As açöes fundamentais das gonadotrofinas hipofisárias na vida sexual reprodutiva de ambos os sexos dependem da integridade estrutural e funcional dos seus respectivos receptores, Os receptores das gonadotrofinas localizados na membrana citoplasmàtica säo membros da grande família dos receptores acoplados à proteína G e apresentam uma estrutura comum caracterizada por uma extensa porçäo extracelular e setes hélices transmembranas. A recente identificaçäo de mutaçöes inativadoras e ativadoras de ocorrência natural nos genes dos receptores do LH e do FSH contribuíram para a maior compreensäo de estados patológicos gonadais. Neste trabalho, revisamos os aspectos moleculares dos defeitos dos genes dos receptores das gonadotrofinas e suas implicaçöes fenotípicas no sexo feminino. Nas mulheres com mutaçöes inativadoras em homozigose nestes genes, sintomas freqüentes como alteraçöes menstruais (amenorréia secundária e oligoamenorréia) e infertilidade podem alertar o endocrinologista para o estabelecimento do diagnõsti-co definitivo da resistência ovariana ao LH ou ao FSH.

Ovarian pathology and high incidence of sex cord tumors in follitropin receptor knockout (FORKO) mice.

In this investigation we describe our observations of the status of the aging ovary in mice with disruption of the receptor for FSH. Knockout mice at 3-5 months of age are acyclic and sterile, with very small, underdeveloped ovaries. Thus, they exhibit hypergonadotropic-hypogonadism with high levels of circulating FSH similar to the postmenopausal state in women. By 12 months more than 92% of these animals developed various kinds of ovarian pathology, including neoplasms of sex cord-stromal type as well as cysts. Interestingly, the majority of tumors were located in the right ovary, with the contralateral ovary remaining unaffected but atrophic. The ovary from heterozygotes also showed pathology after 15 months. None of the age-matched wild-type mice that remained fertile developed any sign of ovarian tumors. Circulating LH and FSH levels were increased in follitropin receptor knockout mice and remained severalfold higher in tumor-bearing animals. The histological appearances of ovarian tumors were similar to the pathology observed in some types of sex cord-stromal neoplasms in women. The tumor burden caused weight loss and cachexia in follitropin receptor knockout mice. Based on these characteristics as well as the high incidence of ovarian pathology in the aging mutant, we propose that the loss of the FSH receptor signaling mechanisms predispose the ovary to molecular and structural changes leading to tumor formation. Hence, in the intact and fertile animal, FSH receptor signaling offers a protective mechanism that is lost upon reproductive senescence (menopause in women). Further studies are warranted in this genetic model to explore the molecular changes underlying the development of ovarian neoplasia.

Estrogen deficiency, obesity, and skeletal abnormalities in follicle-stimulating hormone receptor knockout (FORKO) female mice.

Targeted disruption of the receptor for glycoprotein hormone, FSH (FSH-R) causes a gene dose-related endocrine and gametogenic abnormality in female mice. The resulting FSH-R knockout (FORKO) mutants have disordered estrous cycles, ovulatory defects, and atrophic uterus. The heterozygous animals that initially show reduced fertility undergo early reproductive senescence and stop breeding altogether. Lack of FSH-R signaling in females causes severe ovarian underdevelopment producing chronic estrogen deficiency. This was accompanied by increases in serum testosterone levels. Ovarian aromatase gene transcription and translation are unaltered in the mutants. Early loss of estrogen in the null mutants leads to obesity and skeletal abnormalities that intensify with age producing (kyphosis), a hunchback appearance. Both these changes also become apparent in older heterozygous mice coincident with early reproductive senescence. The expression of nuclear estrogen receptor(s) alpha and beta genes and the corresponding proteins in the ovary and uterus of FORKO mice appear to be intact. The loss of ovarian estrogen creates an imbalance in A and B forms of the progesterone receptor in the uterus of both heterozygotes and null mutants. Some of the changes we have documented here in FORKO mice are reminiscent of the ovarian dysfunction and other major symptoms that are usually associated with estrogen deficiency. In null mutants, estradiol-17beta administration promptly induced uterine growth and reversed the accumulation of adipose tissue indicating that estrogen receptors are functional. Thus, the phenotypes evident in these genetically altered FSH-R mutants may provide an experimental system to explore the effects of estrogenic compounds on different targets including the ovary in a nonsurgical setting.

Mutations in the follicle-stimulating hormone-beta (FSH beta) and FSH receptor genes in mice and humans.

Follicle-stimulating hormone (FSH), a dimeric glycoprotein synthesized in the anterior pituitary gland, is important for the production of sex steroids and gametes. FSH-beta (FSH beta) and FSH receptor (FSHR) knockout mice display impaired ovarian follicular development and infertility in females and small testes, oligospermia, and fertility in males. Humans with FSH beta gene mutations tend to have a more severe phenotype than those with FSHR gene mutations, although infertility and varying degrees of impaired sex steroid production occur in both types of mutations. Data from human and mouse mutations in the FSH beta and FSHR genes suggest that FSH is necessary for normal pubertal development and fertility in males and females.

Men homozygous for an inactivating mutation of the follicle-stimulating hormone (FSH) receptor gene present variable suppression of spermatogenesis and fertility.

Gonadal function is controlled by the two pituitary gonadotropins, luteinizing hormone (LH) and follicle-stimulating hormone (FSH). While LH mainly regulates gonadal steroidogenesis, FSH is considered essential for folliculogenesis in the female and spermatogenesis in the male. We recently discovered that an inactivating point mutation in the FSH receptor (R) gene causes a recessively inherited form of hypergonadotropic ovarian failure in homozygous females. This 566C-->T mutation, predicting an alanine to valine substitution, is located in exon 7 of the FSHR gene, in the region encoding the extracellular domain of the receptor molecule. Functional testing showed a clear-cut reduction in ligand binding and signal transduction by the mutated receptor. Hence, lack of FSH function is incompatible with ovarian follicular maturation and female fertility. In the male, FSH is generally considered essential for the pubertal initiation of spermatogenesis and maintenance of quantitatively normal sperm production in adults. We report here the first characterization of males homozygous for an inactivating FSHR mutation. They have variable degrees of spermatogenic failure, but, surprisingly, do not show azoospermia or absolute infertility. These results question the essential role of FSH for the initiation of spermatogenesis, and demonstrate that FSH is more important for female than for male fertility.