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Dihydroceramide- and ceramide-profiling provides insights into human cardiometabolic disease etiology

Clemens Wittenbecher, Rafael R. C. Cuadrat, Luke Johnston, Fabian Eichelmann, Susanne Jäger, Olga Kuxhaus, Marcela Prada, Fabiola Del Greco M, Andrew A. Hicks, P Hoffman, Jan Krumsiek, Frank B. Hu, Matthias B. Schulze

2022Nature Communications57 citationsDOIOpen Access PDF

Abstract

Metabolic alterations precede cardiometabolic disease onset. Here we present ceramide- and dihydroceramide-profiling data from a nested case-cohort (type 2 diabetes [T2D, n = 775]; cardiovascular disease [CVD, n = 551]; random subcohort [n = 1137]) in the prospective EPIC-Potsdam study. We apply the novel NetCoupler-algorithm to link a data-driven (dihydro)ceramide network to T2D and CVD risk. Controlling for confounding by other (dihydro)ceramides, ceramides C18:0 and C22:0 and dihydroceramides C20:0 and C22:2 are associated with higher and ceramide C20:0 and dihydroceramide C26:1 with lower T2D risk. Ceramide C16:0 and dihydroceramide C22:2 are associated with higher CVD risk. Genome-wide association studies and Mendelian randomization analyses support a role of ceramide C22:0 in T2D etiology. Our results also suggest that (dh)ceramides partly mediate the putative adverse effect of high red meat consumption and benefits of coffee consumption on T2D risk. Thus, (dihydro)ceramides may play a critical role in linking genetic predisposition and dietary habits to cardiometabolic disease risk.

Topics & Concepts

CeramideMendelian randomizationType 2 diabetesDiseaseConfoundingMedicineSphingolipidGenome-wide association studyInternal medicineDiabetes mellitusBioinformaticsEndocrinologyBiologyGeneticsGenotypeGenetic variantsGeneSingle-nucleotide polymorphismApoptosisSphingolipid Metabolism and SignalingPeroxisome Proliferator-Activated ReceptorsDiet, Metabolism, and Disease