Edinburgh Research Explorer Mutations in STRA6 cause a broad spectrum of malformations including anophthalmia, congenital heart defects, diaphragmatic hernia, alveolar capillary dysplasia, lung hypoplasia, and mental retardation

We observed two unrelated consanguineous families with malformation syndromes sharing anophthalmia and distinct eyebrows as common signs, but differing for alveolar capillary dysplasia or complex congenital heart defect in one and diaphragmatic hernia in the other family. Homozygosity mapping revealed linkage to a common locus on chromosome 15, and pathogenic homozygous mutations were identified in STRA6, a member of a large group of “stimulated by retinoic acid” genes encoding novel transmembrane proteins, transcription factors, and secreted signaling molecules or proteins of largely unknown function. Subsequently, homozygous STRA6 mutations were also demonstrated in 3 of 13 patients chosen on the basis of significant phenotypic overlap to the original cases. While a homozygous deletion generating a premature stop codon (p.G50AfsX22) led to absence of the immunoreactive protein in patient’s fibroblast culture, structural analysis of three missense mutations (P90L, P293L, and T321P) suggested significant effects on the geometry of the loops connecting the transmembrane helices of STRA6. Two further variations in the C-terminus (T644M and R655C) alter specific functional sites, an SH2-binding motif and a phosphorylation site, respectively. STRA6 mutations thusdefine a pleiotropic malformation syndrome representing the first human phenotype associated with mutations in a gene from the “ STRA” group. helix, now starting at H291 and changing the topology of the respective loop. Therefore, the P293L mutation is predicted to cause an extension of the helix by three residues, thus affecting the structure and orientation of the respective loop. Moreover, it is important to note that V319 is also the N-terminal residue of an extremely short loop (maximum predicted length between aa 319 and aa 326), in which a second mutation (T321P) has been identified.

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