Mapping of breakpoints in balanced chromosomal translocations by shallow whole-genome sequencing points toEFNA5,BAHD1andPPP2R5Eas novel candidates for genes causing human Mendelian disorders

BackgroundMapping the breakpoints in de novo balanced chromosomal translocations (BCT) in symptomatic individuals provides a unique opportunity to identify in an unbiased way the likely causative genetic defect and thus find novel human disease candidate genes. Our aim was to fine-map breakpoints of de novo BCTs in a case series of nine patients.MethodsShallow whole-genome mate pair sequencing (SGMPS) together with long-range PCR and Sanger sequencing. In one case (BCT disruptingBAHD1andRET) cDNA analysis was used to verify expression of a fusion transcript in cultured fibroblasts.ResultsIn all nine probands 11 disrupted genes were found, that is,EFNA5, EBF3, LARGE, PPP2R5E, TXNDC5, ZNF423, NIPBL, BAHD1, RET, TRPS1andSLC4A10. Five subjects had translocations that disrupted genes with so far unknown (EFNA5, BAHD1, PPP2R5E, TXNDC5) or poorly delineated impact on the phenotype (SLC4A10,two previous reports of BCT disrupting the gene). The four genes with no previous disease associations (EFNA5, BAHD1, PPP2R5E, TXNDC5), when compared with all human genes by a bootstrap test, had significantly higher pLI (pEFNA5, BAHD1andPPP2R5Ewere particularly good candidates for novel disease loci. The pathomechanism forBAHD1may involve deregulation of expression due to fusion withRETpromoter.ConclusionSGMPS in symptomatic carriers of BCTs is a powerful approach to delineate novel human gene–disease associations.