Abstract
BackgroundForkhead box (FOX) proteins are a family of transcription factors. Mutations of three FOX genes, including FOXP1, FOXP2, and FOXG1, have been reported in neurodevelopmental disorders (NDDs). However, due to the lack of site‐specific statistical significance, the pathogenicity of missense mutations of these genes is difficult to determine.MethodsDNA and RNA were extracted from peripheral blood lymphocytes. The mutation was detected by single‐molecule molecular inversion probe‐based targeted sequencing, and the variant was validated by Sanger sequencing. Real‐time quantitative PCR and western blot were performed to assay the expression of the mRNA and protein. To assess the pattern of disorder‐related missense mutations of NDD‐related FOX genes, we manually curated de novo and inherited missense or inframeshift variants within FOXP1, FOXP2, and FOXG1 that co‐segregated with phenotypes in NDDs. All variants were annotated by ANNOVAR.ResultsWe detected a novel de novo missense mutation (NM_001244815: c.G1444A, p.E482K) of FOXP1 in a patient with intellectual disability and severe speech delay. Real‐time PCR and western blot revealed a dramatic reduction of mRNA and protein expression in patient‐derived lymphocytes, indicating a loss‐of‐function mechanism. We observed that the majority of the de novo or transmitted missense variants were located in the FOX domains, and 95% were classified as pathogenic mutations. However, 10 variants were located outside of the FOX domain and were classified as likely pathogenic or variants of uncertain significance.ConclusionOur study shows the pathogenicity of missense and inframeshift variants of NDD‐related FOX genes, which is important for clinical diagnosis and genetic counseling. Functional analysis is needed to determine the pathogenicity of the variants with uncertain clinical significance.
Highlights
In 1990, Weigel and his colleagues identified a DNA binding domain (DBD) that was similar to HNF‐3 transcription factors (Weigel & Jackle, 1990)
To identify and annotate the published missense and inframeshift variants within the three neurodevelopmental disorders (NDDs)‐related Forkhead box (FOX) genes (FOXP1, NM_001244814.1; FOXP2, NM_014491.3; FOXG1, NM_005249.4), we analyzed the de novo variants curated in a database that integrates genome‐wide sequencing studies with large‐scale cohorts, especially for NDDs
We identified a de novo missense variant (p.E482K) in FOXP1 in an individual with intellectual disability (ID)
Summary
In 1990, Weigel and his colleagues identified a DNA binding domain (DBD) that was similar to HNF‐3 transcription factors (Weigel & Jackle, 1990) This domain was defined as a novel transcription factor family called forkhead box (FOX) proteins. Due to a lack of site‐specific statistical significance, the pathogenicity of many variants, especially de novo missense and inframeshift variants, remains to be determined. This situation significantly challenges clinical diagnosis practice and genetic counseling. By gene‐panel sequencing, we detected a novel de novo missense variant within FOXP1 in a patient with ID and speech delay With this initial finding, we systematically curated all reported disorder‐related missense variants in three NDD‐related FOX genes (FOXP1, FOXP2, FOXG1) from the literature. We subsequently investigated the distribution pattern of a missense variants and assigned the pathogenicity to each missense variant
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