Abstract
The K1 and K10 associated genodermatoses are characterized by clinical symptoms of mild to severe redness, blistering and hypertrophy of the skin. In this paper, we set out to computationally investigate the structural and functional effects of missense mutations on the 2B domain of K1/K10 heterodimer and its consequences in disease phenotype. We modeled the structure of the K1/K10 heterodimer based on crystal structures for the human homolog K5/K14 heterodimer, and identified that the missense mutations exert their effects on stability and assembly competence of the heterodimer by altering physico-chemical properties, interatomic interactions, and inter-residue atomic contacts. Comparative structural analysis between all the missense mutations and SNPs showed that the location and physico-chemical properties of the substituted amino acid are significantly correlated with phenotypic variations. In particular, we find evidence that a particular SNP (K10, p.E443K) is a pathogenic nsSNP which disrupts formation of the hydrophobic core and destabilizes the heterodimer through the loss of interatomic interactions. Our study is the first comprehensive report analyzing the mutations located on 2B domain of K1/K10 heterodimeric coiled-coil complex.
Highlights
Genodermatoses are inherited skin disorders primarily caused by mutation of keratin genes
The structural quality of the K1/K10 homology model was validated with Ramachandran plots and root mean square deviation (RMSD) of the alignments using PROCHECK and VADAR
The results clearly suggest that the missense mutations on the 2B domain of K1/K10 cause genodermatoses by disrupting the inter-atomic hydrogen bond, hydrophobic interactions, and interatomic steric clashes
Summary
Genodermatoses are inherited skin disorders primarily caused by mutation of keratin genes. Mutations in K1/K10 cause a large group of clinically and genetically heterogeneous genodermatoses characterized by keratinocyte fragility, blistering, and thickening of the palmoplantar epidermis [1]. Keratins are a family of structurally related heterodimers, which act as cytoskeletal scaffolding in all epithelial cells. Keratins can form a heteropolymer of either type I (acidic, K9-K20, 17q11-q21) or type II (neutral-basic, K1-K8, 12q11-q13) which are expressed in a tissue and differentiation-specific pattern. K1/K10 is expressed in the suprabasal cells of stratified and cornified epithelia, including palms and soles. Three hundred and fifty unique keratin mutations across 21 keratin genes, leading to 40 types of genodermatoses have been reported [2]
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