Abstract
Whole exome sequencing (WES) has become an increasingly common technique for identifying the genetic cause of Mendelian genetic diseases. However, it may fail to detect the complex regions of the genome. Here, we investigated the genetic etiology of a pedigree with autosomal dominant polycystic kidney disease (ADPKD) using a combination of WES, multiplex ligation-dependent probe amplification (MLPA), Sanger sequencing, and long-read sequencing (LRS). Initially, WES of the proband revealed a heterozygous variant c.7391G>C in PKD1 Exon 18, along with a heterozygous deletion of the 17th and 18th exons of PKD1 detected by exome-based copy number variation (CNV) analysis. MLPA confirmed the PKD1 heterozygous deletion of Exon 18. Except for c.7391G>C, Sanger sequencing identified four other heterozygous variants (c.7278T>C, c.7288C>T, c.7344C>G, and c.7365C>T) in Exon 18 of PKD1. Subsequently, LRS uncovered seven clustered substitution variants (c.7209+28C>T, c.7210-16C>T, c.7278T>C, c.7288C>T, c.7344C>G, c.7365C>T, and c.7391G>C), with six of them omitted by WES due to interference from PKD1 pseudogenes. Combining LRS results with cosegregation of the pedigree analysis, we found these variants were in cis and converted from PKD1 pseudogenes, covering a region of at least 282 bp. Notably, the paralogous sequence variants of c.7288C>T introduced a premature stop codon of PKD1, leading to a function loss, and were classified as pathogenic (PVS1+PS4+PM2) according to the ACMG/AMP guideline. Our study highlights the limitations of WES/MLPA and the importance of utilizing complementary tools like LRS for comprehensive variant detection in PKD1.