Multi-omics phenotyping of the gut-liver axis reveals metabolic perturbations from a low-dose pesticide mixture in rats

Robin Mesnage,Emma Bourne,Romy Daniëlle Zwittink,Jean-Michel Panoff,Michael N Antoniou,Laura Falcioni,Caroline Amiel,Fiorella Belpoggi,Charles A Mein,Emanuel Savage,Quinten Raymond Ducarmon,Daniele Mandrioli,Maxime Teixeira,Mariam Ibragim

doi:10.1038/s42003-021-01990-w

Abstract

Health effects of pesticides are not always accurately detected using the current battery of regulatory toxicity tests. We compared standard histopathology and serum biochemistry measures and multi-omics analyses in a subchronic toxicity test of a mixture of six pesticides frequently detected in foodstuffs (azoxystrobin, boscalid, chlorpyrifos, glyphosate, imidacloprid and thiabendazole) in Sprague-Dawley rats. Analysis of water and feed consumption, body weight, histopathology and serum biochemistry showed little effect. Contrastingly, serum and caecum metabolomics revealed that nicotinamide and tryptophan metabolism were affected, which suggested activation of an oxidative stress response. This was not reflected by gut microbial community composition changes evaluated by shotgun metagenomics. Transcriptomics of the liver showed that 257 genes had their expression changed. Gene functions affected included the regulation of response to steroid hormones and the activation of stress response pathways. Genome-wide DNA methylation analysis of the same liver samples showed that 4,255 CpG sites were differentially methylated. Overall, we demonstrated that in-depth molecular profiling in laboratory animals exposed to low concentrations of pesticides allows the detection of metabolic perturbations that would remain undetected by standard regulatory biochemical measures and which could thus improve the predictability of health risks from exposure to chemical pollutants.

Highlights

Health effects of pesticides are not always accurately detected using the current battery of regulatory toxicity tests
The aim of this study was to test the toxicity in vivo of a mixture of pesticides, the residues of which are among those most frequently found in the EU food chain
We presented fold changes (FC) for the metabolites that were found to have their variable importance in projection (VIP) scores > 2 in the orthogonal partial least squares discriminant analysis (OPLS-DA) analyses

Summary

Introduction

Health effects of pesticides are not always accurately detected using the current battery of regulatory toxicity tests. Serum and caecum metabolomics revealed that nicotinamide and tryptophan metabolism were affected, which suggested activation of an oxidative stress response. This was not reflected by gut microbial community composition changes evaluated by shotgun metagenomics. Studies suggest that pesticides are major contributors to the development of a wide range of chronic diseases at environmental levels of exposure in human populations[6,7,8,9,10,11,12]. Among the different strategies to study chemical mixtures[16], some authors have proposed to estimate toxic effects by simulating real-life exposures in laboratory animals[17]

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