Host and Gut Microbial Tryptophan Metabolism and Type 2 Diabetes: an Integrative Analysis of Host Genetics, Diet, Gut Microbiome and Circulating Metabolites in Cohort Studies

Overview

Journal Gut

Specialty Gastroenterology

Date 2021 Jun 15

PMID 34127525

Citations 85

Authors

Qibin Qi

Jun Li

Bing Yu

Jee-Young Moon

Jin C Chai

Jordi Merino

Jie Hu

Miguel Ruiz-Canela

Casey Rebholz

Zheng Wang

Mykhaylo Usyk

Guo-Chong Chen

Bianca C Porneala

Wenshuang Wang

Ngoc Quynh Nguyen

Elena V Feofanova

Megan L Grove

Thomas J Wang

Robert E Gerszten

Josee Dupuis

Jordi Salas-Salvado

Wei Bao

David L Perkins

Martha L Daviglus

Bharat Thyagarajan

Jianwen Cai

Tao Wang

JoAnn E Manson

Miguel A Martinez-Gonzalez

Elizabeth Selvin

Kathryn M Rexrode

Clary B Clish

Frank B Hu

James B Meigs

Rob Knight

Robert D Burk

Eric Boerwinkle

Robert C Kaplan

Affiliations

Soon will be listed here.

Abstract

Objective: Tryptophan can be catabolised to various metabolites through host kynurenine and microbial indole pathways. We aimed to examine relationships of host and microbial tryptophan metabolites with incident type 2 diabetes (T2D), host genetics, diet and gut microbiota.

Method: We analysed associations between circulating levels of 11 tryptophan metabolites and incident T2D in 9180 participants of diverse racial/ethnic backgrounds from five cohorts. We examined host genome-wide variants, dietary intake and gut microbiome associated with these metabolites.

Results: Tryptophan, four kynurenine-pathway metabolites (kynurenine, kynurenate, xanthurenate and quinolinate) and indolelactate were positively associated with T2D risk, while indolepropionate was inversely associated with T2D risk. We identified multiple host genetic variants, dietary factors, gut bacteria and their potential interplay associated with these T2D-relaetd metabolites. Intakes of fibre-rich foods, but not protein/tryptophan-rich foods, were the dietary factors most strongly associated with tryptophan metabolites. The fibre-indolepropionate association was partially explained by indolepropionate-associated gut bacteria, mostly fibre-using . We identified a novel association between a host functional variant (determining lactase persistence) and serum indolepropionate, which might be related to a host gene-diet interaction on gut , a probiotic bacterium significantly associated with indolepropionate independent of other fibre-related bacteria. Higher milk intake was associated with higher levels of gut and serum indolepropionate only among genetically lactase non-persistent individuals.

Conclusion: Higher milk intake among lactase non-persistent individuals, and higher fibre intake were associated with a favourable profile of circulating tryptophan metabolites for T2D, potentially through the host-microbial cross-talk shifting tryptophan metabolism toward gut microbial indolepropionate production.

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