The Primate Gut Microbiota Contributes to Interspecific Differences in Host Metabolism

Overview

Journal Microb Genom

Specialties Genetics
Microbiology

Date 2024 Dec 2

PMID 39620695

Authors

Elizabeth K Mallott

Sahana Kuthyar

Won Lee

Derek Reiman

Hongmei Jiang

Sriram Chitta

E Alexandria Waters

Brian T Layden

Ronen Sumagin

Laura D Manzanares

Guan-Yu Yang

Maria Luisa Savo Sardaro

Stanton Gray

Lawrence E Williams

Yang Dai

James P Curley

Chad R Haney

Emma R Liechty

Christopher W Kuzawa

Katherine R Amato

Affiliations

Soon will be listed here.

Abstract

Because large brains are energetically expensive, they are associated with metabolic traits that facilitate energy availability across vertebrates. However, the biological underpinnings driving these traits are not known. Given its role in regulating host metabolism in disease studies, we hypothesized that the gut microbiome contributes to variation in normal cross-vertebrate species differences in metabolism, including those associated with the brain's energetic requirements. By inoculating germ-free mice with the gut microbiota (GM) of three primate species - two with relatively larger brains and one with a smaller brain - we demonstrated that the GM of larger-brained primates shifts host metabolism towards energy use and production, while that of smaller-brained primates stimulates energy storage in adipose tissues. Our findings establish a causal role of the GM in normal cross-host species differences in metabolism associated with relative brain size and suggest that the GM may have been an important facilitator of metabolic changes during human evolution that supported encephalization.

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