Plasma SRAGE Acts As a Genetically Regulated Causal Intermediate in Sepsis-associated Acute Respiratory Distress Syndrome

Overview

Journal Am J Respir Crit Care Med

Specialty Critical Care

Date 2019 Sep 6

PMID 31487195

Citations 43

Authors

Tiffanie K Jones

Rui Feng

V Eric Kerchberger

John P Reilly

Brian J Anderson

Michael G S Shashaty

Fan Wang

Thomas G Dunn

Thomas R Riley

Jason Abbott

Caroline A G Ittner

David C Christiani

Carmen Mikacenic

Mark M Wurfel

Lorraine B Ware

Carolyn S Calfee

Michael A Matthay

Jason D Christie

Nuala J Meyer

Affiliations

Soon will be listed here.

Abstract

Acute respiratory distress syndrome (ARDS) lacks known causal biomarkers. Plasma concentrations of sRAGE (soluble receptor for advanced glycation end products) strongly associate with ARDS risk. However, whether plasma sRAGE contributes causally to ARDS remains unknown. Evaluate plasma sRAGE as a causal intermediate in ARDS by Mendelian randomization (MR), a statistical method to infer causality using observational data. We measured early plasma sRAGE in two critically ill populations with sepsis. The cohorts were whole-genome genotyped and phenotyped for ARDS. To select validated genetic instruments for MR, we regressed plasma sRAGE on genome-wide genotypes in both cohorts. The causal effect of plasma sRAGE on ARDS was inferred using the top variants with significant associations in both populations ( < 0.01, > 0.02). We applied the inverse variance-weighted method to obtain consistent estimates of the causal effect of plasma sRAGE on ARDS risk. There were 393 European and 266 African ancestry patients in the first cohort and 843 European ancestry patients in the second cohort. Plasma sRAGE was strongly associated with ARDS risk in both populations (odds ratio, 1.86; 95% confidence interval [1.54-2.25]; 2.56 [2.14-3.06] per log increase). Using genetic instruments common to both populations, plasma sRAGE had a consistent causal effect on ARDS risk with a β estimate of 0.50 (95% confidence interval [0.09-0.91] per log increase). Plasma sRAGE is genetically regulated during sepsis, and MR analysis indicates that increased plasma sRAGE leads to increased ARDS risk, suggesting plasma sRAGE acts as a causal intermediate in sepsis-related ARDS.

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