Abstract
PurposeRAX2 encodes a homeobox-containing transcription factor, in which four monoallelic pathogenic variants have been described in autosomal dominant cone-dominated retinal disease.MethodsExome sequencing in a European cohort with inherited retinal disease (IRD) (n = 2086) was combined with protein structure modeling of RAX2 missense variants, bioinformatics analysis of deletion breakpoints, haplotyping of RAX2 variant c.335dup, and clinical assessment of biallelic RAX2-positive cases and carrier family members.ResultsBiallelic RAX2 sequence and structural variants were found in five unrelated European index cases, displaying nonsyndromic autosomal recessive retinitis pigmentosa (ARRP) with an age of onset ranging from childhood to the mid-40s (average mid-30s). Protein structure modeling points to loss of function of the novel recessive missense variants and to a dominant-negative effect of the reported dominant RAX2 alleles. Structural variants were fine-mapped to disentangle their underlying mechanisms. Haplotyping of c.335dup in two cases suggests a common ancestry.ConclusionThis study supports a role for RAX2 as a novel disease gene for recessive IRD, broadening the mutation spectrum from sequence to structural variants and revealing a founder effect. The identification of biallelic RAX2 pathogenic variants in five unrelated families shows that RAX2 loss of function may be a nonnegligible cause of IRD in unsolved ARRP cases.
Highlights
The development of the vertebrate eye is a well-coordinated multistep process regulated by the interplay of genetic networks and interactions with the extracellular environment
Biallelic RAX2 sequence and structural variants were found in five unrelated European index cases, displaying nonsyndromic autosomal recessive retinitis pigmentosa (ARRP) with an age of onset ranging from childhood to the mid-40s
This study supports a role for RAX2 as a novel disease gene for recessive inherited retinal disease (IRD), broadening the mutation spectrum from sequence to structural variants and revealing a founder effect
Summary
The development of the vertebrate eye is a well-coordinated multistep process regulated by the interplay of genetic networks and interactions with the extracellular environment. During early development of the vertebrate central nervous system, the eye field forms centrally within the anterior neural plate, containing all the progenitors of the neural-derived eye structures.[1] This field is defined by the area where the expression domains of a set of eye field transcription factors (TFs) overlap. TFs such as Pax[6], Rax, Six[3], and Lhx[2] are homeobox-containing proteins that constitute a regulatory network to specify retinal progenitor cells, giving rise to eye structures such as the neural retina and the retinal pigment epithelium (RPE).[2] In particular, members of the retinal homeobox (Rax) gene family are among the earliest markers of the eye field, playing a pivotal role during vertebrate eye development.
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