grant

Role of PTPRS in Rheumatoid Arthritis

Organization CEDARS-SINAI MEDICAL CENTERLocation LOS ANGELES, UNITED STATESPosted 1 Sept 2014Deadline 31 Mar 2027
NIHUS FederalResearch GrantFY2025(TNF)-αAddressAggressionAggressive behaviorAnti-Rheumatic AgentsAnti-Rheumatic DrugsArthritisAssayAtrophic ArthritisBindingBioassayBiochemicalBiological AssayBiologyBlood NeutrophilBlood Polymorphonuclear NeutrophilCachectinCell BodyCell LineCell LocomotionCell MigrationCell MovementCellLineCellsCellular MatrixCellular MigrationCellular MotilityCellular biologyClinicCo-cultureCocultivationCocultureCoculture TechniquesCytoskeletal GeneCytoskeletal ProteinsCytoskeletal SystemCytoskeletonCytosolic Protein Tyrosine PhosphastaseDataDegenerative ArthritisDegenerative polyarthritisDephosphorylationDevelopmentDimerizationDiseaseDisease remissionDisorderDrug TargetingEPH- and ELK-Related Tyrosine KinaseEPH-and ELK-Related KinaseElectronsEndothelial CellsEndotheliumEnzyme GeneEnzymesEphrin Type-A Receptor 8Ephrin Type-A Receptor 8 PrecursorEpigeneticEpigenetic ChangeEpigenetic MechanismEpigenetic ProcessExternal DomainExtracellular DomainFibroblastsFundingGene TranscriptionGenesGenetic TranscriptionGlycosaminoglycansGoalsGrantHSPGHeparan SulfateHeparan Sulfate ProteoglycanHeparitin SulfateHumanImmuneImmunesImmunoglobulin DomainImmunoglobulin-Like DomainImmunomodulationImmunosuppressantsImmunosuppressive AgentsImmunosuppressive drugImmunosuppressive treatmentIn VitroIncubatedInflammationInvadedJointsKnowledgeLeadMacrophage-Derived TNFMarrow NeutrophilMediatingMembrana Synovialis Capsulae ArticularisMembraneMiceMice MammalsMicroscopyModern ManMolecularMolecular InteractionMonocyte-Derived TNFMorbidityMorbidity - disease rateMucopolysaccharidesMurineMusNatureNegative Beta ParticleNegatronsNeutrophilic GranulocyteNeutrophilic LeukocyteOsteoarthritisOsteoarthrosisPSGAGPTP Family GenePTPasePathway interactionsPatientsPatternPb elementPermeabilityPhenotypePhosphatasesPhosphohydrolasesPhosphomonoesterasesPhosphoric Monoester HydrolasesPhosphorylationPhosphotyrosine PhosphatasePhosphotyrosyl Protein PhosphatasePlayPolymorphonuclear CellPolymorphonuclear LeukocytesPolymorphonuclear NeutrophilsProtein DephosphorylationProtein DimerizationProtein FamilyProtein PhosphorylationProtein Tyrosine KinaseProtein Tyrosine Kinase EEKProtein Tyrosine PhosphataseProtein Tyrosine Phosphatase GeneProteinsProteoglycanProteoheparan SulfatePublishingRNA ExpressionReceptor Type PTP GeneRegulationRemissionReportingRheumatoid ArthritisRoleSeriesSideSignal Transduction InhibitionStrains Cell LinesSurfaceSwellingSynovial MembraneSynoviumTNFTNF ATNF AlphaTNF geneTNF-αTNFATNFαTherapeuticTherapeutic AgentsTranscriptionTranslatingTumor Necrosis FactorTumor Necrosis Factor-alphaTyrosine KinaseTyrosine PhosphataseTyrosine-Protein Kinase Receptor EEKTyrosine-Specific Protein KinaseTyrosyl Phosphoprotein PhosphataseTyrosylprotein KinaseValidationWorkarthriticarthritis therapycell behaviorcell biologycell motilitycellular behaviorcultured cell linedegenerative joint diseasedesigndesigningdevelopmentaldisease controldisorder controlepigeneticallyextracellularezringlycosaminoglycan polysulfateglycosaminoglycan polysulfuric acid esterglycosaminoglycan polysulphateheavy metal Pbheavy metal leadhydroxyaryl protein kinasehypertrophic arthritisimmune modulationimmune regulationimmune suppressive agentimmune suppressorimmunologic reactivity controlimmunomodulatoryimmunoregulationimmunoregulatoryimmunosuppressive substanceimmunosuppressorimprintin vivoinflamed jointinnovateinnovationinnovativeinterestintracellular skeletonjoint damagejoint degenerationjoint degradationjoint destructionjoint inflammationjoint injuryjoint swellingjoint tissue degenerationjoint traumamembrane structuremigrationmouse modelmurine modelneutrophilnew drug treatmentsnew drugsnew pharmacological therapeuticnew therapeuticsnew therapynext generation therapeuticsnovelnovel drug treatmentsnovel drugsnovel pharmaco-therapeuticnovel pharmacological therapeuticnovel therapeuticsnovel therapyoverexpressoverexpressionpathwayphosphoprotein p81polysulfated glycosaminoglycanprotein expressionprotein tyrosine phosphate phosphohydrolaserecruitrheumatic arthritissocial rolestructural biologysulfated glycosaminoglycansyndecan-4syndecan4therapeutic targettyrosyl protein kinasevalidations
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Full Description

ABSTRACT
Fibroblast-like synoviocytes (FLS) are joint-lining non-hematopoietic cells that in rheumatoid arthritis (RA)
contribute to local joint inflammation and damage. There is interest in discovering FLS-directed therapeutic
agents that could be combined with current immunosuppressant disease-modifying anti-rheumatic agents
(DMARDs). This renewal proposal focuses on understanding the mechanism of action and regulation of the
tyrosine phosphatase PTPRS, which plays a critical role in FLS migration and invasion.
In the first cycle of this grant, we have shown that PTPRS is an important regulator of FLS aggressiveness during
RA and developed an approach to modulate PTPRS function in rheumatoid FLS. Our studies showed that on
the surface of RA FLS, PTPRS is kept in an inactive state through specific binding to the heparan sulfate (HS)-
proteoglycan syndecan-4 through a mechanism called the proteoglycan switch. Treatment of RA FLS with a
decoy fragment of PTPRS encompassing its two most extracellular proteoglycan-binding immunoglobulin
domains (called Ig1&2) causes detachment of PTPRS from syndecan-4. This leads to PTPRS-dependent
inhibition of migration and invasiveness via dephosphorylation of the PTPRS substrate ezrin. In vivo
administration of Ig1&2 reverses arthritis in multiple mouse models via a non-immunological mechanism. We
also find that PTPRS expression is inhibited on RA FLS by tumor necrosis factor alpha, suggesting that PTPRS
expression is regulated by joint inflammation.
In the second cycle of the grant, we would like to deepen our knowledge of the mechanism of action and
regulation of PTPRS in FLS and RA. Here we propose to a series of mechanistic studies in primary human FLS
and mouse models of RA aimed at understanding the regulation of PTPRS expression in RA FLS (Aims 1) and
how Ig1&2 and PTPRS regulate FLS-induced inflammation in arthritis (Aim 2). We will also use biochemical,
structural, and cellular biology approaches to understand the key molecular determinants for PTPRS regulation
by syndecan-4 (Aim 3).
Our long-term goal remains to understand the biology of PTPRS in RA FLS, which will help to complete the
validation of the PTPRS-regulated pathway as a therapeutic target for RA.

Grant Number: 5R01AR066053-10
NIH Institute/Center: NIH
Principal Investigator: Nunzio Bottini

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