A Novel Missense Variant of HOXD13 Caused Atypical Synpolydactyly by Impairing the Downstream Gene Expression and Literature Review for Genotype-Phenotype Correlations.

Ruiji Guo,Yu An,Bin Sun,Jiateng Zhou,Hailei Mao,Bin Wang,Xia Fang

doi:10.3389/fgene.2021.731278

Ruiji Guo, Yu An + Show 5 more

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https://doi.org/10.3389/fgene.2021.731278

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Abstract

Synpolydactyly (SPD) is a hereditary congenital limb malformation with distinct syndactyly designated as SPD1, SPD2, and SPD3. SPD1 is caused by mutations of HOXD13, which is a homeobox transcription factor crucial for limb development. More than 143 SPD patients have been reported to carry HOXD13 mutations, but there is a lack of genotype–phenotype correlation. We report a novel missense mutation of c. 925A > T (p.I309F) in an individual with atypical synpolydactyly inherited from her father with mild clinodactyly and three other different alanine insertion mutations in HOXD13 identified by whole exome sequencing (WES) in 12 Chinese SPD families. Unlike polyalanine extension, which tends to form α-helix and causes protein aggregation in the cytoplasm as shown by molecular simulation and immunofluorescence, the c. 925A > T mutation impairs downstream transcription of EPHA7. We compiled literature findings and analyzed genotype–phenotype features in 173 SPD individuals of 53 families, including 12 newly identified families. Among the HOXD13-related individuals, mutations were distributed in three regions: polyalanine, homeobox, and non-homeobox. Polyalanine extension was the most common variant (45%), followed by missense mutations (32%) mostly in the homeobox compared with the loss-of-function (LOF) variants more likely in non-homeobox. Furthermore, a more severe degree and classic SPD were associated with polyalanine mutations although missense variants were associated with brachydactyly and syndactyly in hands and feet and LOF variants with clinodactyly in hands. Our study broadens the HOXD13 mutation spectrum and reveals the profile of three different variants and their severity of SPD, the genotype–phenotype correlation related to the HOXD13 mutation site provides clinical insight, including for genetic counseling.

Highlights

(SPD) is a rare congenital limb deformity characterized by a fusion of adjacent digits and partial or complete digital duplication within the webs
We investigated the pathogenic mechanisms of aggregate formation within the cells, polymerization-free energy changes, and transcription regulation caused by the HOXD13 mutations
A total of nine kinds of human diseases were reported to be associated with alanine repeat mutations, including SPD (HOXD13) (Goff and Tabin, 1997), blepharophimosis syndrome (FOXL2) (Baere et al, 2003), cleidocranial dysplasia (RUNX2) (Mundlos et al, 1997), congenital central hypoventilation syndrome (PHOX2b) (Jeanne et al, 2003), holoprosencephaly type 5 (ZIC2) (Brown et al, 2001), hand-foot-genital syndrome (HOXA13) (Boris et al, 2002), growth hormone deficiency (SOX3) (Laumonnier et al, 2002), Paddington syndrome (ARX) (Petter et al, 2002), and oculopharyngeal muscular dystrophy (OPMD, PABPN1) (Brais et al, 1998)

Summary

Introduction

(SPD) is a rare congenital limb deformity characterized by a fusion of adjacent digits and partial or complete digital duplication within the webs. Synpolydactyly affects the 3/4 fingers and the 4/5 toes (Malik and Grzeschik, 2010). Most non-syndromic synpolydactyly cosegregates with a mutation in the HOXD13 gene on chromosome 2q31 and is categorized as Synpolydactyly type 1 (SPD1, OMIM 186000), which is known as syndactyly type II (SD II), according to the nomenclature of Temtamy and McKuisck (Temtamy and McKusick, 1978). Other rare genetic synpolydactyly comprises SPD2 (OMIM608180) caused by FBLN1 gene mutation on chromosome 22q13.31 and SPD3 (OMIM610234), which is mapped to locus 14q11.2-q12 (Malik et al, 2006; Malik and Grzeschik, 2010)

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