grant

Targeting bacterial proteases involved in PAR signaling to treat inflammatory bowel diseases

Organization STANFORD UNIVERSITYLocation STANFORD, UNITED STATESPosted 21 Sept 2021Deadline 31 Jul 2026
NIHUS FederalResearch GrantFY2025AffectAntiproteasesAssayBacteriaBacterial ToxinsBioassayBiochemicalBiologicalBiological AssayBiologyBody TissuesBody Weight decreasedCF2RCaCo2Caco-2 CellsCell BodyCell Communication and SignalingCell Culture SystemCell SignalingCell modelCellsCellular modelChemical FractionationChemicalsClinicalCollectionCrohn diseaseCrohn'sCrohn's diseaseCrohn's disorderDataDiarrheaDiseaseDisorderEndopeptidase InhibitorsEndopeptidase-Activated ReceptorsEnzyme GeneEnzymesEpitheliumEsteroproteasesEventF2RF2R geneFITC-dextranFRACNFatigueFractionationFractionation RadiotherapyFutureG Protein-Complex ReceptorG Protein-Coupled Receptor GenesG-Protein-Coupled ReceptorsGI commensalGI microbiomeGI microbiotaGPCRGastrointestinal DiseasesGastrointestinal microbiotaGene ExpressionGoalsGranulomatous EnteritisHealthHumanHuman Cell LineInflammationInflammatoryInflammatory Bowel DiseasesInflammatory Bowel DisorderIntracellular Communication and SignalingLC/MSLack of EnergyLigandsLinkMaintenanceMapsMeasuresMediatingMicrobiologyModelingModern ManMolecular ConfigurationMolecular ConformationMolecular StereochemistryN-terminalNH2-terminalNutrientOrganoidsPAR1PainPainfulPathogenesisPathologyPatientsPeptidase InhibitorsPeptidasesPeptide Hydrolase InhibitorsPeptide HydrolasesPeptide Peptidohydrolase InhibitorsPermeabilityPhenotypePhysiologicPhysiologicalPlayPositionPositioning AttributeProcessProtease AntagonistsProtease GeneProtease InhibitorProtease-Activated ReceptorsProteasesProtein CleavageProteinase InhibitorsProteinase-Activated ReceptorsProteinasesProteolysisProteolytic EnzymesProteomicsQualifyingReceptor ActivationReceptor ProteinReceptor SignalingReporterRoleSamplingSignal TransductionSignal Transduction SystemsSignalingSiteSymptomsTestingTherapeuticTissuesUlcerated ColitisUlcerative ColitisWeight LossWeight ReductionWorkactivity-based protein profilingbacteria in the gutbacteria pathogenbacterial pathogenbiologicbiological signal transductionbody weight losschemical synthesiscommensal bacteriacommensal bacteria in the gastrointestinal tractcommensal bacteria in the gutcommensal bacteria in the intestinecommensal bacterial speciesconformationconformationalconformational stateconformationallyconformationsdesensitizationdigestive tract microbiomeeleocolitisenteric commensalenteric microbial communityenteric microbiomeenteric microbiotaextracellularfluorescein isothiocyanate dextranfluoresceinthiocarbamoyl dextransgastrointestinalgastrointestinal commensalgastrointestinal disordergastrointestinal microbial floragastrointestinal microbiomegut bacteriagut commensalgut communitygut dysbiosisgut floragut homeostasisgut microbe communitygut microbial communitygut microbial compositiongut microbial consortiagut microbiomegut microbiotagut microbioticgut microfloragut-associated microbiomehost microbe associationhost microbe relationshiphost-microbe interactionshost-microbial interactionshost-microorganism interactionsin vitro Assayinflammatory disease of the intestineinflammatory disorder of the intestineinhibitorintestinal autoinflammationintestinal barrierintestinal biomeintestinal commensalintestinal epitheliumintestinal floraintestinal microbiomeintestinal microbiotaintestinal microfloraintestinal mucosal barrierintestinal tract microfloraliquid chromatography mass spectrometrymicrobialmonolayernew drug targetnew druggable targetnew pharmacotherapy targetnew therapeutic targetnew therapy targetnovelnovel drug targetnovel druggable targetnovel pharmacotherapy targetnovel therapeutic targetnovel therapy targetpathobiontpathogenic bacteriapeptide aminoacid sequencepeptide sequencepreventpreventingprotein aminoacid sequenceprotein expressionreceptorregional enteritisscreeningscreeningssmall moleculesocial rolesuccesstargeted drug therapytargeted drug treatmentstargeted therapeutictargeted therapeutic agentstargeted therapytargeted treatmenttherapeutic targetwt-loss
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Full Description

Project Summary
Crohn’s disease and ulcerative colitis are forms of inflammatory bowel disease (IBD) that affect more than 6.8
million patients worldwide. Because no cure is available to date, treatment is limited to reducing IBD symptoms
such as severe diarrhea, weight loss, fatigue and pain. Although the exact mechanisms that mediate the
pathogenesis of the disease are unclear, excessive proteolysis in the gut combined with dysregulated signaling
of protease-activated receptors (PARs) have been identified as important drivers of IBD and additional
gastrointestinal (GI) diseases. PARs are a unique class of four eukaryotic G-protein coupled receptors
(GPCRs) that are directly regulated by proteolytic cleavage of a peptide sequence in the extracellular N-
terminal domain (NTD). Cleavage reveals a tethered activating ligand or alters the receptor conformation to
induce activation. PAR-signaling can promote inflammation by disrupting the integrity of the intestinal epithelial
barrier, which under physiological conditions allows permeability of nutrients but restricts the entry of bacterial
pathogens and toxins. Many GI diseases are accompanied by loss of barrier function and dysbiosis of the gut
microbiome. Proteases derived from commensal bacteria are likely to be important regulators of gut
homeostasis and pathogenesis, thus making them potential therapeutic targets. However, it is unclear which
extracellular proteases are produced by commensal strains in the gut and how these enzymes affect health
and disease by proteolysis of co-localized PARs. We hypothesize that beneficial commensal bacteria secrete
proteases that keep excessive inflammation in check by basal activation or proteolytic desensitization of PARs.
Conversely, pathobiont bacteria species secrete proteases that promote inflammation via increased PAR
activation. Therefore, proteases produced by the gut microbiota as well as pathogenic bacteria have the
potential to be valuable new therapeutic targets for the treatment of various forms of IBD. To test our
hypothesis, we will develop a robust in vitro assay to broadly screen for proteases with PAR-processing activity
in both commensals and pathobiont bacterial species. We will then identify specific PAR processing proteases
and assess their specific roles in regulating epithelial barrier integrity and inflammation using cell culture
systems and gut organoids. Finally, we will establish the therapeutic relevance of the identified proteases by
confirming their presence and elevated activity in clinical samples isolated from patients with active IBD.
Ultimately, this work will identify specific PAR processing proteases produced by bacterial strains and define
the mechanism by which they impact the pathogenesis of IBD.

Grant Number: 5R01DK130293-05
NIH Institute/Center: NIH
Principal Investigator: Matthew Bogyo

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