Genotype/phenotype correlations in 538 congenital adrenal hyperplasia patients from Germany and Austria: discordances in milder genotypes and in screened versus prescreening patients.

Congenital adrenal hyperplasia (CAH) due to CYP21A2 gene mutations is associated with a variety of clinical phenotypes (salt wasting, SW; simple virilizing, SV; nonclassical, NC) depending on residual 21-hydroxylase activity. Phenotypes and genotypes correlate well in 80-90% of cases. We set out to test the predictive value of CAH phenotype assignment based on genotype classification in a large multicenter cohort. A retrospective evaluation of genetic data from 538 CAH patients (195 screened) collected from 28 tertiary centers as part of a German quality control program was performed. Genotypes were classified according to residual 21-hydroxylase activity (null, A, B, C) and assigned clinical phenotypes correlated with predicted phenotypes, including analysis of Prader stages. Ultimately, concordance of genotypes with clinical phenotypes was compared in patients diagnosed before or after the introduction of nationwide CAH-newborn screening. Severe genotypes (null and A) correlated well with the expected phenotype (SW in 97 and 91%, respectively), whereas less severe genotypes (B and C) correlated poorly (SV in 45% and NC in 57%, respectively). This was underlined by a high degree of virilization in girls with C genotypes (Prader stage >1 in 28%). SW was diagnosed in 90% of screening-positive babies with classical CAH compared with 74% of prescreening patients. In our CAH series, assigned phenotypes were more severe than expected in milder genotypes and in screened vs prescreening patients. Diagnostic discrimination between phenotypes based on genotypes may prove overcome due to the overlap in their clinical presentations.

Targeted Resequencing of Putative Growth-Related Genes Using Whole Exome Sequencing in Patients with Severe Primary IGF-I Deficiency.

BACKGROUND/AIMS: To elucidate the genetic causes of severe primary insulin-like growth factor-I deficiency (SPIGFD) by systematic, targeted, next-generation sequencing (NGS)-based resequencing of growth-related genes. METHODS: Clinical phenotyping followed by NGS in 17 families including 6 affected sib pairs. RESULTS: We identified disease-causing, heterozygous, de novo variants in HRAS (p.Gly13Cys) and FAM111A (p.Arg569His) in 2 male patients with syndromic SPIGFD. A previously described homozygous GHR nonsense variant was detected in 2 siblings of a consanguineous family (p.Glu198*). Furthermore, we identified an inherited novel variant in the IGF2 gene (p.Arg156Cys) of a maternally imprinted gene in a less severely affected father and his affected daughter. We detected 2 other novel missense variants in SH2B1 and SOCS2, both were inherited from an unaffected parent. CONCLUSIONS: Screening of growth-related genes using NGS-based, large-scale, targeted resequencing identified disease-causing variants in HRAS, FAM111A, and GHR. Considering the increased risk of subjects with HRAS mutations for neoplasms, close clinical monitoring and a thorough discussion of the risk/benefit ratio of the treatment with recombinant IGF-I is mandatory. Segregation analysis proved to be critical in the interpretation of potential SPIGFD-associated gene variations.