Functional testing of a human PBX3 variant in zebrafish reveals a potential modifier role in congenital heart defects

Whole-genome and exome sequencing efforts are increasingly identifying candidate genetic variants associated with human disease. However, predicting and testing the pathogenicity of a genetic variant remains challenging. Genome editing allows for the rigorous functional testing of human genetic vari...

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Bibliographic Details
Published in:Disease models & mechanisms 2018-10, Vol.11 (10)
Main Authors: Farr, 3rd, Gist H, Imani, Kimia, Pouv, Darren, Maves, Lisa
Format: Article
Language:English
Subjects:
Congenital diseases
CRISPR
CRISPR-Cas9
Gene expression
Genetic variant
Genetics
Genome editing
Genomes
Health risk assessment
Heart
Modifier
Morphogenesis
Mutation
Pbx
Population
Proteins
Roles
Standard deviation
Zebra
Zebrafish
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Summary:Whole-genome and exome sequencing efforts are increasingly identifying candidate genetic variants associated with human disease. However, predicting and testing the pathogenicity of a genetic variant remains challenging. Genome editing allows for the rigorous functional testing of human genetic variants in animal models. Congenital heart defects (CHDs) are a prominent example of a human disorder with complex genetics. An inherited sequence variant in the human gene ( p.A136V) has previously been shown to be enriched in a CHD patient cohort, indicating that the p.A136V variant could be a modifier allele for CHDs. Pbx genes encode three-amino-acid loop extension (TALE)-class homeodomain-containing DNA-binding proteins with diverse roles in development and disease, and are required for heart development in mouse and zebrafish. Here, we used CRISPR-Cas9 genome editing to directly test whether this Pbx gene variant acts as a genetic modifier in zebrafish heart development. We used a single-stranded oligodeoxynucleotide to precisely introduce the human p.A136V variant in the homologous zebrafish gene ( p.A131V). We observed that zebrafish that are homozygous for p.A131V are viable as adults. However, the p.A131V variant enhances the embryonic cardiac morphogenesis phenotype caused by loss of the known cardiac specification factor, Hand2. Our study is the first example of using precision genome editing in zebrafish to demonstrate a function for a human disease-associated single nucleotide variant of unknown significance. Our work underscores the importance of testing the roles of inherited variants, not just variants, as genetic modifiers of CHDs. Our study provides a novel approach toward advancing our understanding of the complex genetics of CHDs.
ISSN:1754-8403
1754-8411
DOI:10.1242/dmm.035972