Erroneous prenatal diagnosis of congenital adrenal hyperplasia owing to a duplication of the CYP21A2 gene.

Congenital adrenal hyperplasia (CAH) is an autosomal recessive disorder where steroidogenesis in the adrenal cortex is impaired. The most common form is caused by 21-hydroxylase deficiency (21OHD). Classical 21OHD is characterized by glucocorticoid and mineralocorticoid deficiency and by overproduction of adrenal androgens. The diagnosis rests on biochemical and genetic analyses. In families with history of CAH, prenatal genetic diagnosis is offered. We herein present a case of an infant whose parents were identified to carry mutations on the CYP21A2 gene. The fetal DNA analysis demonstrated that the fetus carried a paternal exon 8 (Q318X) mutation and a maternal exon 8 (R356X) mutation. The fetus was presumed to be affected with CAH, yet his clinical presentation at birth was not consistent with the diagnosis. Repeated genetic analysis identified a paternal CYP21A2 gene duplication with Q318X mutation on one copy of CYP21A2. We conclude that a duplication of the CYP21A2 gene should be suspected when clinical and hormonal findings do not support the genetic diagnosis. Furthermore, because individuals with Q318X mutation frequently have a duplication of the CYP21A2 gene, when Q318X is detected, it is important to distinguish the severe point mutation in single gene copy alleles from the non-deficient variant in gene-duplicated alleles.

Two novel translocation breakpoints upstream of SOX9 define borders of the proximal and distal breakpoint cluster region in campomelic dysplasia.

The semilethal skeletal malformation syndrome campomelic dysplasia (CD) with or without XY sex reversal is caused by mutations within the SOX9 gene on 17q24.3 or by chromosomal aberrations (translocations, inversions or deletions) with breakpoints outside the SOX9 coding region. The previously published CD translocation breakpoints upstream of SOX9 fall into two clusters: a proximal cluster with breakpoints between 50-300 kb and a distal cluster with breakpoints between 899-932 kb. Here, we present clinical, cytogenetic and molecular data from two novel CD translocation cases. Case 1 with karyotype 46,XY,t(1;17)(q42.1;q24.3) has characteristic symptoms of CD, including mild tibial bowing, cryptorchidism and hypospadias. By standard fluorescence in situ hybridization (FISH) and by high-resolution fiber FISH, the 17q breakpoint was mapped 375 kb from SOX9, defining the centromeric border of the proximal breakpoint cluster region. Case 2 with karyotype 46,X,t(Y;17)(q11.2;q24.3) has the acampomelic form of CD and complete XY sex reversal. By FISH and somatic cell hybrid analysis, the 17q breakpoint was mapped 789 kb from SOX9, defining the telomeric border of the distal breakpoint cluster region. We discuss the structure of the 1 Mb cis-control region upstream of SOX9 and the correlation between the position of the 14 mapped translocation breakpoints with respect to disease severity and XY sex reversal.

Paternal uniparental isodisomy of chromosome 20q--and the resulting changes in GNAS1 methylation--as a plausible cause of pseudohypoparathyroidism.

Heterozygous inactivating mutations in the GNAS1 exons (20q13.3) that encode the alpha-subunit of the stimulatory G protein (Gsalpha) are found in patients with pseudohypoparathyroidism type Ia (PHP-Ia) and in patients with pseudo-pseudohypoparathyroidism (pPHP). However, because of paternal imprinting, resistance to parathyroid hormone (PTH)-and, sometimes, to other hormones that require Gsalpha signaling-develops only if the defect is inherited from a female carrier of the disease gene. An identical mode of inheritance is observed in kindreds with pseudohypoparathyroidism type Ib (PHP-Ib), which is most likely caused by mutations in regulatory regions of the maternal GNAS1 gene that are predicted to interfere with the parent-specific methylation of this gene. We report a patient with PTH-resistant hypocalcemia and hyperphosphatemia but without evidence for Albright hereditary osteodystrophy who has paternal uniparental isodisomy of chromosome 20q and lacks the maternal-specific methylation pattern within GNAS1. Since studies in the patient's fibroblasts did not reveal any evidence of impaired Gsalpha protein or activity, it appears that the loss of the maternal GNAS1 gene and the resulting epigenetic changes alone can lead to PTH resistance in the proximal renal tubules and thus lead to impaired regulation of mineral-ion homeostasis.

Endogenous expression of Müllerian inhibiting substance in early postnatal rat sertoli cells requires multiple steroidogenic factor-1 and GATA-4-binding sites.

Müllerian inhibiting substance (MIS) is a key element required to complete mammalian male sex differentiation. The expression pattern of MIS is tightly regulated in fetal, neonatal, and prepubertal testes and adult ovaries and is well conserved among mammalian species. Although several factors have been shown to be essential to MIS expression, its regulatory mechanisms are not fully understood. We have examined MIS promoter activity in 2-day postnatal primary cultures of rat Sertoli cells that continue to express endogenous MIS mRNA. Using this system, we found that the region between human MIS-269 and -192 is necessary for full MIS promoter activity. We identified by DNase I footprint and electrophoretic mobility-shift analyses a distal steroidogenic factor-1 (SF-1)-binding site that is essential for full promoter activity. Mutational analysis of this new distal SF-1 site and the previously identified proximal SF-1 site showed that both are necessary for transcriptional activation. Moreover, the proximal promoter also contains multiple GATA-4-binding sites that are essential for functional promoter activity. Thus multiple SF-1- and GATA-4-binding sites in the MIS promoter are required for normal tissue-specific and developmental expression of MIS.

Diagnostic utility of Müllerian inhibiting substance determination in patients with primary and recurrent granulosa cell tumors.

OBJECTIVES: In this study we evaluated changes in serum Müllerian inhibiting substance (MIS) concentration in a large number of patients with granulosa cell tumors (GCT) to determine whether MIS is elevated at the time of presentation and whether MIS is an index of successful surgical resection and management of recurrences. METHODS: We retrospectively reviewed MIS levels from 17 subjects prior to tumor resection and studied serial MIS samples from 56 subjects following initial tumor resection. Clinical follow-up information was available for 36 of those with postoperative MIS values. Serum MIS was measured by an ELISA. MIS values were compared to a combination of normative values previously established in our laboratory and from more recently obtained samples from older pre- and postmenopausal women, using this assay. RESULTS: Serum MIS was elevated pre-operatively in 6 of 8 (75%) subjects with juvenile GCTs and in 7 of 9 (78%) of those with adult GCTs relative to age-matched controls (76% for both types combined). Post-operative clinical correlation was available for 36 patients. There was no clinical recurrence in 21 subjects with normal or undetectable postoperative values, and incompletely resectable tumor or recurrence was identified in 6 of 15 patients with elevated postoperative values. CONCLUSIONS: The results of this study demonstrate that postoperative serum MIS concentrations may be used to evaluate the completeness of tumor removal following initial surgery and that serial MIS determinations may allow the detection of recurrences.

Von Hippel-Lindau disease maps to the region of chromosome 3 associated with renal cell carcinoma.

Von Hippel-Lindau disease (VHL) is an autosomal dominant disorder with inherited susceptibility to various forms of cancer, including hemangioblastomas of the central nervous system, phaeochromocytomas, pancreatic malignancies, and renal cell carcinomas. Renal cell carcinomas constitute a particularly frequent cause of death in this disorder, occurring as bilateral and multifocal tumours, and presenting at an earlier age than in sporadic, non-familial cases of this tumour type. We report here that the VHL gene is linked to the locus encoding the human homologoue of the RAF1 oncogene, which maps to chromosome 3p25 (ref. 4). Crossovers with the VHL locus suggest that the defect responsible for the VHL phenotype is not a mutation in the RAF1 gene itself. An alternative or prior event to oncogene activation in tumour formation may be the inactivation of a putative 'tumour suppressor' which can be associated with both the inherited and sporadic forms of the cancer. Sporadic renal cell carcinomas have previously been associated with the loss of regions on chromosome 3p (refs 5, 6). Consequently, sporadic and VHL-associated forms of renal cell carcinoma might both result from alterations causing loss of function of the same 'tumour suppressor' gene on this chromosome.

Linkage analysis in von Recklinghausen neurofibromatosis (NF1) with DNA markers for chromosome 17.

The mutant gene causing von Recklinghausen neurofibromatosis (NF1) was recently shown to map to chromosome 17. We have used additional markers for chromosome 17 to narrow further the location of the gene defect. A preliminary multipoint linkage analysis suggests that the NF1 gene is located on the long arm of chroomsome 17, flanked by D17Z1 and NGFR. Linkage analysis with the human oncogene homolog erbA1, which maps to this region, suggests that this cancer-related gene is not the primary cause of NF1.

DNA linkage analysis in Von Recklinghausen neurofibromatosis.

We have used DNA linkage analysis in 11 families with Von Recklinghausen neurofibromatosis (VRNF) in order to search for the chromosomal localisation of the defective gene causing this serious neurological disorder. Three groups of polymorphic DNA markers were used: (1) markers for chromosome 22, because of possible allelic genetic heterogeneity between VRNF and bilateral acoustic neurofibromatosis; (2) markers near the centromere of chromosome 4, since there was preliminary evidence for linkage between the VRNF gene and Gc; and (3) oncogenes and growth factors as possible candidate genes for VRNF. Our data exclude close linkage between any of these markers and the gene for VRNF.

Genetic linkage of von Recklinghausen neurofibromatosis to the nerve growth factor receptor gene.

von Recklinghausen neurofibromatosis (VRNF) is one of the most common inherited disorders affecting the human nervous system. VRNF is transmitted as an autosomal dominant defect with high penetrance but variable expressivity. The disorder is characterized clinically by hyperpigmented patches of skin (café au lait macules, axillary freckles) and by multiple tumors of peripheral nerve, spinal nerve roots, and brain (neurofibromas, optic gliomas). These tumors can cause disfigurement, paralysis, blindness, and death. We have determined the chromosomal location of the VRNF gene by genetic linkage analysis using DNA markers. The VRNF gene is genetically linked to the locus encoding nerve growth factor receptor, located on the long arm of chromosome 17 in the region 17q12----17q22. However, crossovers with the VRNF locus suggest that a mutation in the nerve growth factor receptor gene itself is unlikely to be the fundamental defect responsible for the VRNF phenotype.

Common pathogenetic mechanism for three tumor types in bilateral acoustic neurofibromatosis.

Bilateral acoustic neurofibromatosis (BANF) is a genetic defect associated with multiple tumors of neural crest origin. Specific loss of alleles from chromosome 22 was detected with polymorphic DNA markers in two acoustic neuromas, two neurofibromas, and one meningioma from BANF patients. This indicates a common pathogenetic mechanism for all three tumor types. The two neurofibromas were among three taken from the same patient, and both showed loss of identical alleles demonstrating that the same chromosome suffered deletion in both tumors. The third neurofibroma from this patient showed no detectable loss of heterozygosity, which suggests the possibility of a more subtle mutational event that affects chromosome 22. In the two acoustic neuromas, only a portion of chromosome 22 was deleted, narrowing the possible chromosomal location of the gene that causes BANF to the region distal to the D22S9 locus in band 22q11. The identification of progressively smaller deletions on chromosome 22 in these tumor types may well provide a means to clone and characterize the defect.