Clinical relevance of systematic phenotyping and exome sequencing in patients with short stature.

PurposeShort stature is a common condition of great concern to patients and their families. Mostly genetic in origin, the underlying cause often remains elusive due to clinical and genetic heterogeneity.MethodsWe systematically phenotyped 565 patients where common nongenetic causes of short stature were excluded, selected 200 representative patients for whole-exome sequencing, and analyzed the identified variants for pathogenicity and the affected genes regarding their functional relevance for growth.ResultsBy standard targeted diagnostic and phenotype assessment, we identified a known disease cause in only 13.6% of the 565 patients. Whole-exome sequencing in 200 patients identified additional mutations in known short-stature genes in 16.5% of these patients who manifested only part of the symptomatology. In 15.5% of the 200 patients our findings were of significant clinical relevance. Heterozygous carriers of recessive skeletal dysplasia alleles represented 3.5% of the cases.ConclusionA combined approach of systematic phenotyping, targeted genetic testing, and whole-exome sequencing allows the identification of the underlying cause of short stature in at least 33% of cases, enabling physicians to improve diagnosis, treatment, and genetic counseling. Exome sequencing significantly increases the diagnostic yield and consequently care in patients with short stature.

Mutations in C-natriuretic peptide (NPPC): a novel cause of autosomal dominant short stature.

PurposeC-type natriuretic peptide (CNP) and its principal receptor, natriuretic peptide receptor B (NPR-B), have been shown to be important in skeletal development. CNP and NPR-B are encoded by natriuretic peptide precursor-C (NPPC) and natriuretic peptide receptor 2 (NPR2) genes, respectively. While NPR2 mutations have been described in patients with skeletal dysplasias and idiopathic short stature (ISS), and several Npr2 and Nppc skeletal dysplasia mouse models exist, no mutations in NPPC have been described in patients to date.MethodsNPPC was screened in 668 patients (357 with disproportionate short stature and 311 with autosomal dominant ISS) and 29 additional ISS families in an ongoing whole-exome sequencing study.ResultsTwo heterozygous NPPC mutations, located in the highly conserved CNP ring, were identified. Both showed significant reductions in cyclic guanosine monophosphate synthesis, confirming their pathogenicity. Interestingly, one has been previously linked to skeletal abnormalities in the spontaneous Nppc mouse long-bone abnormality (lbab) mutant.ConclusionsOur results demonstrate, for the first time, that NPPC mutations cause autosomal dominant short stature in humans. The NPPC mutations cosegregated with a short stature and small hands phenotype. A CNP analog, which is currently in clinical trials for the treatment of achondroplasia, seems a promising therapeutic approach, since it directly replaces the defective protein.

Long-term response to growth hormone therapy in a patient with short stature caused by a novel heterozygous mutation in NPR2.

BACKGROUND: Heterozygous loss-of-function mutations in the natriuretic peptide receptor B gene (NPR2) are responsible for short stature in patients without a distinct phenotype. Some of these patients have been treated with recombinant human growth hormone (rhGH) therapy with a variable response. CASE PRESENTATION: The proband was a healthy boy who presented at the age of 5.1 years with familial short stature (height SDS of -3.1). He had a prominent forehead, a depressed nasal bridge, centripetal fat distribution and a high-pitched voice resembling that of children with GH deficiency. His hormonal evaluation showed low insulin-like growth factor-1 (IGF-1) but a normal GH peak at a stimulation test. During the first year of rhGH treatment, his growth velocity increased from 3.4 to 10.4 cm/year (height SDS change of +1.1). At the last visit, he was 8.8 years old and still on treatment, his growth velocity was 6.4 cm/year and height SDS was -1.8. RESULTS: We identified through exome sequencing a novel heterozygous loss-of-function NPR2 mutation (c.2905G>C; p.Val969Leu). Cells cotransfected with the p.Val969Leu mutant showed a significant decrease in cyclic guanosine monophosphate (cGMP) production compared to the wild type (WT), suggesting a dominant negative effect. CONCLUSIONS: This case reveals a novel heterozygous loss-of-function NPR2 mutation responsible for familial short stature and the good response of rhGH therapy in this patient.

Heterozygous NPR2 Mutations Cause Disproportionate Short Stature, Similar to Léri-Weill Dyschondrosteosis.

CONTEXT: SHOX mutations have been detected in approximately 70% of Léri-Weill dyschondrosteosis (LWD) and approximately 2.5% of idiopathic short stature (ISS) cases, suggesting the implication of other genes or loci. The recent identification of NPR2 mutations in ISS suggested that NPR2 mutations may also be involved in disproportionate short stature. OBJECTIVE: The objective of the study was to investigate whether NPR2 mutations can account for a proportion of the cases referred for LWD and ISS in whom no SHOX mutation was detected. PATIENTS AND METHODS: We undertook NPR2 mutation screening in 173 individuals referred for suspected LWD and 95 for ISS, with no known defect in SHOX or its enhancers. Intracellular localization and natriuretic peptide precursor C-dependent guanylate cyclase activity were determined for the identified NPR2 variants. RESULTS: Eight NPR2 variants were identified in nine individuals, seven referred for suspected LWD and two for ISS. Six were demonstrated to affect NPR-B cell trafficking and/or its ability to synthesize cyclic GMP (cGMP) under response to natriuretic peptide precursor C/brain natriuretic peptide stimulation. All pathogenic mutations were detected in the suspected LWD referral group (∼3%). Interestingly, one of these patients is currently being treated with recombinant human GH and in contrast to previous reports is showing a positive response to the treatment. CONCLUSIONS: NPR2 mutations account for approximately 3% of patients with disproportionate short stature and/or clinical or radiographic indicators of SHOX deficiency and in whom no SHOX defect has been identified. However, no patient has yet presented with Madelung deformity. Thus, NPR2 should be screened in the SHOX-negative LWD referrals.

NPPB and ACAN, two novel SHOX2 transcription targets implicated in skeletal development.

SHOX and SHOX2 transcription factors are highly homologous, with even identical homeodomains. Genetic alterations in SHOX result in two skeletal dysplasias; Léri-Weill dyschondrosteosis (LWD) and Langer mesomelic dysplasia (LMD), while no human genetic disease has been linked to date with SHOX2. SHOX2 is, though, involved in skeletal development, as shown by different knockout mice models. Due to the high homology between SHOX and SHOX2, and their functional redundancy during heart development, we postulated that SHOX2 might have the same transcriptional targets and cofactors as SHOX in limb development. We selected two SHOX transcription targets regulated by different mechanisms: 1) the natriuretic peptide precursor B gene (NPPB) involved in the endochondral ossification signalling and directly activated by SHOX; and 2) Aggrecan (ACAN), a major component of cartilage extracellular matrix, regulated by the cooperation of SHOX with the SOX trio (SOX5, SOX6 and SOX9) via the protein interaction between SOX5/SOX6 and SHOX. Using the luciferase assay we have demonstrated that SHOX2, like SHOX, regulates NPPB directly whilst activates ACAN via its cooperation with the SOX trio. Subsequently, we have identified and characterized the protein domains implicated in the SHOX2 dimerization and also its protein interaction with SOX5/SOX6 and SHOX using the yeast-two hybrid and co-immunoprecipitation assays. Immunohistochemistry of human fetal growth plates from different time points demonstrated that SHOX2 is coexpressed with SHOX and the members of the SOX trio. Despite these findings, no mutation was identified in SHOX2 in a cohort of 83 LWD patients with no known molecular defect, suggesting that SHOX2 alterations do not cause LWD. In conclusion, our work has identified the first cofactors and two new transcription targets of SHOX2 in limb development, and we hypothesize a time- and tissue-specific functional redundancy between SHOX and SHOX2.

SHOX interacts with the chondrogenic transcription factors SOX5 and SOX6 to activate the aggrecan enhancer.

SHOX (short stature homeobox-containing gene) encodes a transcription factor implicated in skeletal development. SHOX haploinsufficiency has been demonstrated in Leri-Weill dyschondrosteosis (LWD), a skeletal dysplasia associated with disproportionate short stature, as well as in a variable proportion of cases with idiopathic short stature (ISS). In order to gain insight into the SHOX signalling pathways, we performed a yeast two-hybrid screen to identify SHOX-interacting proteins. Two transcription factors, SOX5 and SOX6, were identified. Co-immunoprecipitation assays confirmed the existence of the SHOX-SOX5 and SHOX-SOX6 interactions in human cells, whereas immunohistochemical studies demonstrated the coexpression of these proteins in 18- and 32-week human fetal growth plates. The SHOX homeodomain and the SOX6 HMG domain were shown to be implicated in the SHOX-SOX6 interaction. Moreover, different SHOX missense mutations, identified in LWD and ISS patients, disrupted this interaction. The physiological importance of these interactions was investigated by studying the effect of SHOX on a transcriptional target of the SOX trio, Agc1, which encodes one of the main components of cartilage, aggrecan. Our results show that SHOX cooperates with SOX5/SOX6 and SOX9 in the activation of the upstream Agc1 enhancer and that SHOX mutations affect this activation. In conclusion, we have identified SOX5 and SOX6 as the first two SHOX-interacting proteins and have shown that this interaction regulates aggrecan expression, an essential factor in chondrogenesis and skeletal development.