Genetic and functional analysis of Raynaud’s syndrome implicates loci in vasculature and immunity

Anniina Tervi(Institute for Molecular Medicine Finland), Markus Ramste(Stanford University), Erik Abner(University of Tartu), Paul Cheng(Stanford University), Jacqueline M. Lane(Broad Institute), Matthew Maher(Broad Institute), Jesse Valliere(Broad Institute), Vilma Lammi(Institute for Molecular Medicine Finland), Satu Strausz(Institute for Molecular Medicine Finland), Juha Riikonen(Institute for Molecular Medicine Finland), Trieu Nguyen(Stanford University), Gabriella E. Martyn(Stanford Health Care), Maya U. Sheth(Stanford Health Care), Fan Xia(Stanford Health Care), Mauro Lago‐Docampo(Stanford Medicine), Wenduo Gu(Stanford University), Tōnu Esko(University of Tartu), Richa Saxena(Broad Institute), Matti Pirinen(Institute for Molecular Medicine Finland), Aarno Palotie(Broad Institute), Samuli Ripatti(Institute for Molecular Medicine Finland), Nasa Sinnott-Armstrong(Fred Hutch Cancer Center), Mark J. Daly(Broad Institute), J Engreitz(Broad Institute), Marlene Rabinovitch(Stanford University), Caroline A. Heckman(Institute for Molecular Medicine Finland), Thomas Quertermous(Stanford University), Samuel E. Jones(Institute for Molecular Medicine Finland), Hanna M. Ollila(Institute for Molecular Medicine Finland)
Cell Genomics
August 13, 2024
10.1016/j.xgen.2024.100630
Cited by 5Open Access
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Abstract

Raynaud's syndrome is a dysautonomia where exposure to cold causes vasoconstriction and hypoxia, particularly in the extremities. We performed meta-analysis in four cohorts and discovered eight loci (ADRA2A, IRX1, NOS3, ACVR2A, TMEM51, PCDH10-DT, HLA, and RAB6C) where ADRA2A, ACVR2A, NOS3, TMEM51, and IRX1 co-localized with expression quantitative trait loci (eQTLs), particularly in distal arteries. CRISPR gene editing further showed that ADRA2A and NOS3 loci modified gene expression and in situ RNAscope clarified the specificity of ADRA2A in small vessels and IRX1 around small capillaries in the skin. A functional contraction assay in the cold showed lower contraction in ADRA2A-deficient and higher contraction in ADRA2A-overexpressing smooth muscle cells. Overall, our study highlights the power of genome-wide association testing with functional follow-up as a method to understand complex diseases. The results indicate temperature-dependent adrenergic signaling through ADRA2A, effects at the microvasculature by IRX1, endothelial signaling by NOS3, and immune mechanisms by the HLA locus in Raynaud's syndrome.

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