Preserved Fertility in a Patient with a 46,XY Disorder of Sex Development due to a New Heterozygous Mutation in the NR5A1/SF-1 Gene: Evidence of 46,XY and 46,XX Gonadal Dysgenesis Phenotype Variability in Multiple Members of an Affected Kindred

In humans, steroidogenic factor 1 (NR5A1/SF-1) mutations have been reported to cause gonadal dysgenesis, with or without adrenal failure, in both 46,XY and 46,XX individuals. We have previously reported extreme within-family variability in affected 46,XY patients. Even though low ovarian reserve with preserved fertility has been reported in females harboring NR5A1 gene mutations, fertility has only been observed in one reported case in affected 46,XY individuals. A kindred with multiple affected members presenting gonadal dysgenesis was studied. Four 46,XY individuals presented severe hypospadias at birth, one of them associated with micropenis and cryptorchidism. The other 3 developed spontaneous male puberty, and 1 has fathered 5 children. Four 46,XX patients presented premature ovarian failure (one of them was not available for the study) or high follicle-stimulating hormone levels. Mutational analysis of the NR5A1 gene revealed a novel heterozygous mutation, c.938G→A, predicted to cause a p.Arg313Hys amino acid change. A highly conserved amino acid of the ligand-binding domain of the mature protein is affected, predicting abnormal protein function. We confirm that preserved fertility can be observed in patients with a 46,XY disorder of sex development due to heterozygous mutations in the NR5A1 gene.     

Steroidogenic factor-1 (SF-1, NR5A1) and human disease

Steroidogenic factor-1 (SF-1, Ad4BP, encoded by NR5A1) is a key regulator of adrenal and reproductive development and function. Based upon the features found in Nr5a1 null mice, initial attempts to identify SF-1 changes in humans focused on those rare individuals with primary adrenal failure, a 46,XY karyotype, complete gonadal dysgenesis and Müllerian structures. Although alterations affecting DNA-binding of SF-1 were found in two such cases, disruption of SF-1 is not commonly found in patients with adrenal failure. In contrast, it is emerging that variations in SF-1 can be found in association with a range of human reproductive phenotypes such as 46,XY disorders of sex development (DSD), hypospadias, anorchia, male factor infertility, or primary ovarian insufficiency in women. Overexpression or overactivity of SF-1 is also reported in some adrenal tumors or endometriosis. Therefore, the clinical spectrum of phenotypes associated with variations in SF-1 is expanding and the importance of this nuclear receptor in human endocrine disease is now firmly established.     

Isolated 46,XY gonadal dysgenesis in two sisters caused by a Xp21.2 interstitial duplication containing the DAX1 gene

CONTEXT: Testis development is a tightly regulated process that requires an efficient and coordinated spatiotemporal action of many factors, and it has been shown that several genes involved in gonadal development exert a dosage effect. Chromosomal imbalances have been reported in several patients presenting with gonadal dysgenesis as part of severe dysmorphic phenotypes. RESULTS: We screened for submicroscopic DNA copy number variations in two sisters with an apparent normal 46,XY karyotype and female external genitalia due to gonadal dysgenesis, and in which mutations in known candidate genes had been excluded. By high-resolution tiling bacterial artificial chromosome array comparative genome hybridization, a submicroscopic duplication at Xp21.2 containing DAX1 (NR0B1) was identified. Using fluorescence in situ hybridization, multiple ligation probe amplification, and PCR, the rearrangement was further characterized. This revealed a 637-kb tandem duplication that in addition to DAX1 includes the four MAGEB genes, the hypothetical gene CXorf21, GK, and part of the MAP3K7IP3 gene. Sequencing and analysis of the breakpoint boundaries and duplication junction suggest that the duplication originated through a coupled homologous and nonhomologous recombination process. CONCLUSIONS: This represents the first duplication on Xp21.2 identified in patients with isolated gonadal dysgenesis because all previously described XY subjects with Xp21 duplications presented with gonadal dysgenesis as part of a more complex phenotype, including mental retardation and/or malformations. Thus, our data support DAX1 as a dosage sensitive gene responsible for gonadal dysgenesis and highlight the importance of considering DAX1 locus duplications in the evaluation of all cases of 46,XY gonadal dysgenesis.     

Sex determination: a 'window' of DAX1 activity.

Traditionally, DAX1 was considered an 'anti-testis' gene because DAX1 duplications in XY individuals cause male-to-female sex reversal: dosage-sensitive sex reversal (DSS). In DSS, two active DAX1 genes on one X chromosome can abrogate testis formation. By contrast, mutations and deletions of DAX1 cause adrenal hypoplasia congenita (AHC). Although AHC patients develop testes, gonadal defects include disorganized testis cords and hypogonadotropic hypogonadism, which is not completely restored with gonadotropin or androgen therapy. Recent evidence of XY sex reversal in Dax1-deficient mice strongly supports a role for Dax1 as a 'pro-testis' gene. Therefore, perhaps DAX1/Dax1 acts within a 'window' of activity, outside of which testis formation does not occur. Here, we discuss the function and possible mechanisms of DAX1 action in male gonadogenesis.     

Heterozygous mutation of steroidogenic factor-1 in 46,XY subjects may mimic partial androgen insensitivity syndrome

CONTEXT: The clinical and biological features of Sertoli cell and Leydig cell dysfunction are usually investigated when characterizing disorders of sex development in 46,XY individuals: This allows gonadal dysgenesis, a defective development of the gonad, to be distinguished from defects restricted to androgen synthesis or sensitivity. In humans, mutations in steroidogenic factor-1 (SF-1), one of the critical factors involved in testis development, have been reported to cause gonadal dysgenesis with or without adrenal failure in 46,XY individuals. OBJECTIVE: We report a SF-1 mutation that caused ambiguous genitalia associated with strikingly different hormonal phenotypes in two affected 46,XY children from the same family. METHODS: Hormonal evaluation included testosterone (T), anti-Mullerian hormone (AMH), inhibin B, FSH, and LH measurements during the first weeks of life, a period when physiological activation of the gonadotropin-gonadal system occurs. Direct DNA sequencing of the coding sequence of the SF-1 and the androgen receptor (AR) genes was performed. RESULTS: Both 46,XY children had ambiguous genitalia with no Mullerian structures and no adrenal insufficiency. The older child showed normal elevation of T (up to 7.6 nmol/liter, 2.2 ng/ml), AMH (504 pmol/liter, 70.6 ng/ml), inhibin B (245 pg/ml), FSH, and LH during the first weeks, which led to a presumptive diagnosis of partial androgen insensitivity syndrome. The AR sequence was, however, normal. In the second child, T, AMH, and inhibin B were low, suggesting gonadal dysgenesis. In both children and their mother, a c.536delC frameshift mutation in the SF-1 gene was found. This mutation terminates translation at position 295, removing the ligand-binding domain and the activation function 2 (AF-2) domain, a critical domain for SF-1 transactivating activity. CONCLUSIONS: The usual markers of testis dysgenesis may be normal in 46,XY individuals with SF-1 mutation. Screening for SF-1 mutation should be performed in subjects with apparent partial androgen insensitivity syndrome and no mutation in the AR gene.     

Clinical and genetic heterogeneity of congenital adrenal hypoplasia due to NR0B1 gene mutations

Introduction X‐linked adrenal hypoplasia congenita (AHC) is a rare disorder caused by mutations or complete deletion of the NR0B1 gene that encodes the DAX‐1 protein, an orphan member of the nuclear receptor superfamily. AHC is characterized by adrenal insufficiency in infancy and early childhood. Later, hypogonadotropic hypogonadism (HH) manifests as pubertal failure. Patients and methods We evaluated the clinical, endocrine and molecular characteristics of 12 AHC patients from 5 families diagnosed between 1984 and 2007 in Israel. Results Most of the boys (10/12) presented with signs of adrenal insufficiency such as salt wasting and failure to thrive during the neonatal period. Aldosterone deficiency usually preceded cortisol deficiency requiring early mineralocorticoid therapy. Serum cortisol levels in the first weeks of life varied from very low to high levels (<2·76 to >1776 nmol/l). Five boys showed signs of precocious sexual development during infancy and childhood, including enlargement of the penis and testes. In four patients the initial diagnoses were erroneous. Molecular analysis of the NR0B1 gene identified point mutations in six patients including a novel splice site mutation in one patient and his family (IVS1‐1G→C). Contiguous gene deletion was found in six patients from two families who manifested impaired mental development. Conclusions In X‐linked AHC caused by different molecular defects in NR0B1 gene, the clinical spectrum of the disease is quite variable and precocious sexual development is a prominent feature. Genetic testing is indicated in boys presenting with salt‐wasting with or without cortisol deficiency if congenital adrenal hyperplasia has been ruled out.     

Severe loss-of-function mutations in the adrenocorticotropin receptor (ACTHR, MC2R) can be found in patients diagnosed with salt-losing adrenal hypoplasia

OBJECTIVE: Familial glucocorticoid deficiency type I (FGD1) is a rare form of primary adrenal insufficiency resulting from recessive mutations in the ACTH receptor (MC2R, MC2R). Individuals with this condition typically present in infancy or childhood with signs and symptoms of cortisol insufficiency, but disturbances in the renin-angiotensin system, aldosterone synthesis or sodium homeostasis are not a well-documented association of FGD1. As ACTH stimulation has been shown to stimulate aldosterone release in normal controls, and other causes of hyponatraemia can occur in children with cortisol deficiency, we investigated whether MC2R changes might be identified in children with primary adrenal failure who were being treated for mineralocorticoid insufficiency. DESIGN: Mutational analysis of MC2R by direct sequencing. PATIENTS: Children (n = 22) who had been diagnosed with salt-losing forms of adrenal hypoplasia (19 isolated cases, 3 familial), and who were negative for mutations in DAX1 (NR0B1) and SF1 (NR5A1). RESULTS: MC2R mutations were found in three individuals or kindred (I: homozygous S74I; II: novel compound heterozygous R146H/560delT; III: novel homozygous 579-581delTGT). These changes represent severely disruptive loss-of-function mutations in this G-protein coupled receptor, including the first reported homozygous frameshift mutation. The apparent disturbances in sodium homeostasis were mild, manifest at times of stress (e.g. infection, salt-restriction, heat), and likely resolved with time. CONCLUSIONS: MC2R mutations should be considered in children who have primary adrenal failure with apparent mild disturbances in renin-sodium homeostasis. These children may have been misdiagnosed as having salt-losing adrenal hypoplasia. Making this diagnosis has important implications for treatment, counselling and long-term prognosis.     

Report of fertility in a woman with a predominantly 46,XY karyotype in a family with multiple disorders of sexual development

CONTEXT: We report herein a remarkable family in which the mother of a woman with 46,XY complete gonadal dysgenesis was found to have a 46,XY karyotype in peripheral lymphocytes, mosaicism in cultured skin fibroblasts (80% 46,XY and 20% 45,X) and a predominantly 46,XY karyotype in the ovary (93% 46,XY and 6% 45,X). PATIENTS: A 46,XY mother who developed as a normal woman underwent spontaneous puberty, reached menarche, menstruated regularly, experienced two unassisted pregnancies, and gave birth to a 46,XY daughter with complete gonadal dysgenesis. RESULTS: Evaluation of the Y chromosome in the daughter and both parents revealed that the daughter inherited her Y chromosome from her father. Molecular analysis of the genes SOX9, SF1, DMRT1, DMRT3, TSPYL, BPESC1, DHH, WNT4, SRY, and DAX1 revealed normal male coding sequences in both the mother and daughter. An extensive family pedigree across four generations revealed multiple other family members with ambiguous genitalia and infertility in both phenotypic males and females, and the mode of inheritance of the phenotype was strongly suggestive of X-linkage. CONCLUSIONS: The range of phenotypes observed in this unique family suggests that there may be transmission of a mutation in a novel sex-determining gene or in a gene that predisposes to chromosomal mosaicism.     

Novel DAX1 mutations in X-linked adrenal hypoplasia congenita and hypogonadotrophic hypogonadism

OBJECTIVE: Mutations of the DAX1 gene (Dosage-sensitive sex reversal-Adrenal hypoplasia congenita critical region on the X chromosome gene 1), which encodes a novel orphan nuclear receptor, have been identified in patients with X-linked adrenal hypoplasia congenita (AHC) and hypogonadotrophic hypogonadism (HHG). We have investigated two kindreds with AHC and HHG for DAX1 mutations. METHODS: Two kindreds with five affected males, four carrier females and four unaffected males were investigated. The gonadotrophin deficiency in three of the boys was observed to be partial until mid-puberty. DAX1 mutations in the entire 1413 bp coding region were sought by DNA sequence analysis. RESULTS: Two DAX1 mutations, situated within exon 1, were detected. These consisted of an insertional mutation at codon 183 that led to a frameshift and a premature Stop at codon 184, and a missense mutation Leu278Pro that involved a highly conserved leucine residue within the proposed ligand binding domain. Co-segregation of these mutations with the disease in each family, and their absence from 107 alleles in 73 (39 males and 34 females) unrelated control individuals, was demonstrated by allele specific oligonucleotide hybridization (ASO) analysis for the insertional mutation, and by Ban I restriction endonuclease analysis for the missense mutation. CONCLUSIONS: Two novel DAX1 mutations have been detected in two families with adrenal hypoplasia and hypogonadotrophic hypogonadism. The finding of partial gonadotrophin deficiency in the affected males from these families is notable and an early recognition of such a possibility in a patient, which may be facilitated by DAX1 mutational analysis, may help to prevent the sequelae of delayed androgen replacement therapy.     

Mutations in the desert hedgehog (DHH) gene in patients with 46,XY complete pure gonadal dysgenesis

Mutations of SRY are the cause of complete pure gonadal dysgenesis (PGD) in 10-15% of patients. In the remaining individuals, it has been suggested that mutations in other genes involved in the testis-determining pathway could be causative. We describe the first report in which three cases of 46,XY complete PGD are attributed to mutations of the Desert hedgehog (DHH) gene. DHH was sequenced using genomic DNA from paraffin-embedded gonadal tissue from six patients with complete 46,XY PGD. Mutations were found in three patients: a homozygous mutation in exon 2, responsible for a L162P, and a homozygous 1086delG in exon 3. Mutated individuals displayed 46,XY complete PGD, differentiating from the only previously described patient with a homozygous DHH mutation, who exhibited a partial form of PGD with polyneuropathy, suggesting that localization of mutations influence phenotypic expression. This constitutes the first report where mutations of DHH are associated with the presence of 46,XY complete PGD, demonstrating that the genetic origin of this entity is heterogeneous and that disorders in other genes, different from SRY, involved in the testis-determining pathway are implicated in abnormal testicular differentiation in humans. These data extend previous reports demonstrating DHH is a key gene in gonadal differentiation.