grant

Obesogenic diet-induced intestinal epithelium repair responses link dysbiosis and cardiovascular disease

Organization VANDERBILT UNIVERSITY MEDICAL CENTERLocation NASHVILLE, UNITED STATESPosted 12 Jan 2022Deadline 31 Dec 2026
NIHUS FederalResearch GrantFY202621+ years oldASCVDAccelerationAddressAdultAdult HumanAerobicAffectAminesAtherosclerosisAtherosclerotic Cardiovascular DiseaseAutomobile DrivingBlood monocyteCardiac DiseasesCardiac DisordersCardiovascular DiseasesCessation of lifeCholineChronicCirculationColiform BacilliColonComplexDataDeathDevelopmentDietDiseaseDisorderEnteric BacteriaEnterobacteriaEnterobacteriaceaeEpithelial CellsEventExposure toGI microbiotaGastrointestinal microbiotaGoalsHealthHeart DiseasesHigh Fat DietHyperplasiaHyperplasticIn VitroInflammatoryIntermediary MetabolismIntestinalIntestinal DiseasesIntestinal DisorderIntestinesInvestigatorsKnowledgeLinkMarrow monocyteMediatingMetabolic ProcessesMetabolismModelingMolecularMucosaMucosal TissueMucous MembraneObesityOxidesPathway interactionsPopulationProductionResearch PersonnelResearchersRespirationRoleSaturated Fatty AcidsStudy modelsTaxonTestingadiposityadulthoodamineatheromatosisatherosclerosis riskatherosclerotic diseaseatherosclerotic riskatherosclerotic vascular diseasebowelbowel inflammationcardiovascular disease riskcardiovascular disordercardiovascular disorder riskcolonic cryptcorpulenceday shiftdevelopmentaldiet-associated obesitydiet-induced obesitydiet-related obesitydietsdrivingdysbacteriosisdysbiosisdysbioticenteric microbial communityenteric microbiotaepithelial repairexperimentexperimental researchexperimental studyexperimentsgastrointestinal microbial floragut communitygut dysbiosisgut floragut inflammationgut microbe communitygut microbial communitygut microbial compositiongut microbial consortiagut microbiotagut microbioticgut microfloraheart disorderhost-associated microbeshost-associated microbial communitieshost-associated microbiotahost-associated microorganismsin vivoinflamed bowelinflamed gutinflamed intestineinnovateinnovationinnovativeinsightinterestintestinal epitheliumintestinal floraintestinal inflammationintestinal microbiotaintestinal microfloraintestinal tract microfloraintestine diseaseintestine disordermicrobialmicrobial imbalancemicrobiota compositionmitochondrial dysfunctionmonocytemouse modelmurine modelnight shiftnight worknovelobesigenicobesity-promoting dietobesogenicobesogenic Western-style dietobesogenic dietobesogenic high fat dietobesogenic western dietpathwaypro-obesity dietrecruitrespiratory mechanismresponseshift workshiftworksocial role
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Full Description

PROJECT SUMMARY
An obesogenic Western-style (HF) diet causes low-grade intestinal inflammation, intestinal microbiota
imbalance, and an increased risk of cardiovascular disease. However, our knowledge about the pathways
producing each of these different disease manifestations is incomplete, making it difficult to see connections.
Experiments proposed in this application are aimed at addressing this critical gap in knowledge. Our long-range
goal is to elucidate molecular mechanisms that make the gut microbiota a liability during non-communicable
diseases. This application aims to study the mechanisms through which HF diet drives gut dysbiosis and
determine whether the resulting imbalance escalates the production of microbial metabolites that increase the
risk for cardiovascular disease. Our central hypothesis is that mitochondrial dysfunction induced by an
obesogenic HF diet activates epithelial repair responses (e.g., crypt hyperplasia), which in turn drives an
expansion of facultative anaerobic Enterobacteriaceae, a taxon known to produce metabolites that accelerate
atherosclerosis. To test our hypothesis, we will determine whether mitochondrial dysfunction-induced monocyte
recruitment promotes colonic epithelium repair responses (specific aim 1). We will identify the role of colonic
epithelium repair responses in driving HF diet-induced Enterobacteriaceae expansion (specific aim 2). We will
also elucidate the mechanism by which HF diet-induced Enterobacteriaceae expansion increases circulating
trimethylamine N-oxide (TMAO) levels and promotes cardiovascular disease (specific aim 3). By defining the
complex order of events that links these disease manifestations, we expect the completion of the proposed
experiments to usher in a decisive conceptual advance to understand how HF diet increases cardiovascular
disease risk.

Grant Number: 5R01DK131104-05
NIH Institute/Center: NIH
Principal Investigator: Mariana Byndloss

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