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De novo mutations implicate novel genes in systemic lupus erythematosus

Research output: Contribution to journalArticle

Venu Pullabhatla, Amy L. Roberts, Myles J. Lewis, Daniele Mauro, David L. Morris, Christopher A. Odhams, Philip Tombleson, Ulrika Liljedahl, Simon Vyse, Michael A. Simpson, Sascha Sauer, Emanuele de Rinaldis, Ann Christine Syvänen, Timothy J. Vyse

Original languageEnglish
Pages (from-to)421-429
Number of pages9
JournalHuman Molecular Genetics
Volume27
Issue number3
Early online date21 Nov 2017
DOIs
Accepted/In press14 Nov 2017
E-pub ahead of print21 Nov 2017
Published1 Feb 2018

King's Authors

Abstract

The omnigenic model of complex disease stipulates that the majority of the heritability will be explained by the effects of common variation on genes in the periphery of core disease pathways. Rare variant associations, expected to explain far less of the heritability, may be enriched in core disease genes and thus will be instrumental in the understanding of complex disease pathogenesis and their potential therapeutic targets. Here, using complementary whole-exome sequencing, highdensity imputation, and in vitro cellular assays, we identify candidate core genes in the pathogenesis of systemic lupus erythematosus (SLE). Using extreme-phenotype sampling, we sequenced the exomes of 30 SLE parent-affected-offspring trios and identified 14 genes with missense de novo mutations (DNM), none of which are within the>80 SLE susceptibility loci implicated through genome-wide association studies. In a follow-up cohort of 10, 995 individuals of matched European ancestry, we imputed genotype data to the density of the combined UK10K-1000 genomes Phase III reference panel across the 14 candidate genes. Gene-level analyses indicate three functional candidates: DNMT3A, PRKCD, and C1QTNF4.We identify a burden of rare variants across PRKCD associated with SLE risk (P=0.0028), and across DNMT3A associated with two severe disease prognosis sub-phenotypes (P=0.0005 and P=0.0033). We further characterise the TNF-dependent functions of the third candidate gene C1QTNF4 on NF-κB activation and apoptosis, which are inhibited by the p.His198Gln DNM. Our results identify three novel genes in SLE susceptibility and support extreme-phenotype sampling and DNM gene discovery to aid the search for core disease genes implicated through rare variation.

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