grant

The Role of c-ABL in Mediating TIE2 Signaling and Formation of Venous Malformation

Organization UNIVERSITY OF CINCINNATILocation CINCINNATI, UNITED STATESPosted 15 Sept 2024Deadline 14 Sept 2027
NIHUS FederalResearch GrantFY20253-D modeling3D modelingAddressAffectAngiopoietin 1 ReceptorAngiopoietin Receptor Tie-2AreaAssayAutomobile DrivingBinding ProteinsBioassayBiological AssayBleedingBlood VesselsCD202B AntigenCardiovascularCardiovascular Body SystemCardiovascular Organ SystemCardiovascular systemCell Communication and SignalingCell Growth in NumberCell LocomotionCell MigrationCell MovementCell MultiplicationCell ProliferationCell SignalingCellular MigrationCellular MotilityCellular ProliferationClosure by LigationCo-ImmunoprecipitationsCre driverDNA mutationDataDefectDevelopmentDiseaseDisorderEPH- and ELK-Related Tyrosine KinaseEPH-and ELK-Related KinaseEndothelial CellsEndothelial TEK Tyrosine KinaseEndotheliumEphrin Type-A Receptor 8Ephrin Type-A Receptor 8 PrecursorEpithelial-Specific Protein Receptor Tyrosine Kinase TIE-2FK506 Binding Protein 12-Rapamycin Associated Protein 1FKBP12 Rapamycin Complex Associated Protein 1FRAP1FRAP1 geneFRAP2GeneticGenetic ChangeGenetic defectGenetic mutationGoalsHeart VascularHemorrhageHeterograftHeterologous TransplantationHyperactivityIn VitroIn complete remissionIntracellular Communication and SignalingInvestigationKinasesLesionLigand Binding ProteinLigand Binding Protein GeneLigandsLigationLocationMeasuresMechanistic Target of RapamycinMediatingMethodsMiceMice MammalsModalityModelingMurineMusMutateMutationPI-3K/AKTPI3K/AKTPTK ReceptorsPainPainfulPathogenesisPathologicPathway interactionsPatientsPhenotypePhosphotransferase GenePhosphotransferasesPhysiologicPhysiologicalPreclinical TestingProtein BindingProtein Tyrosine KinaseProtein Tyrosine Kinase EEKProteinsRAFT1Receptor Protein-Tyrosine KinasesReceptor Tyrosine Kinase GeneResearchRestRoleSignal TransductionSignal Transduction SystemsSignalingTEK Tyrosine KinaseTEK geneTIE-2TIE-2 ReceptorTIE-2 Receptor Tyrosine KinaseTIE-2-RTKTIE2TIE2 Tyrosine KinaseTamoxifenTek ReceptorTestingTherapeuticThrombosisTie2 ReceptorTransgenic MiceTransgenic OrganismsTransmembrane Receptor Protein Tyrosine KinaseTransphosphorylasesTubeTunica Interna Endothelial Cell KinaseTyrosine KinaseTyrosine Kinase Linked ReceptorsTyrosine Kinase ReceptorsTyrosine-Protein Kinase Receptor EEKTyrosine-Protein Kinase Receptor TEKTyrosine-Protein Kinase Receptor TIE-2Tyrosine-Specific Protein KinaseTyrosylprotein KinaseVMCMVMCM1VeinsVenous AngiomaVenous MalformationWorkXenograftXenograft procedureXenotransplantationbiological signal transductionblood lossbound proteincell motilitycirculatory systemcomplete responsedevelopmentaldrivinggain of functiongenome mutationhydroxyaryl protein kinasein vivoin vivo Modelinduced Creinducible Creloss of functionmTORmammalian target of rapamycinmouse modelmurine modelmutantmutant mouse modelneonatal micenew drug targetnew druggable targetnew pharmacotherapy targetnew therapeutic targetnew therapy targetnovelnovel drug targetnovel druggable targetnovel pharmacotherapy targetnovel therapeutic targetnovel therapy targetp140 TEKpathwaypharmacologicpre-clinical studypre-clinical testingpreclinical studysocial roletargeted drug therapytargeted drug treatmentstargeted therapeutictargeted therapeutic agentstargeted therapytargeted treatmentthree-dimensional modelingthrombotic diseasethrombotic disordertransgenictranslational impacttyrosyl protein kinasevascularxeno-transplantxeno-transplantation
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Full Description

PROJECT SUMMARY/ABSTRACT
Venous malformations (VMs) are vascular lesions with abnormally enlarged vessels that are disfiguring, painful,
and have complications such as bleeding and thrombosis. Current therapeutic options are not universally
effective, can require life-long treatment, and fail to produce full lesion regression, indicating that investigation of
novel causative pathways is needed. VM is associated with mutation in the endothelial tyrosine kinase receptor
TIE2, the most common of which is the p.L914F mutation. However, studies into the cellular mechanisms driving
VM pathogenesis are hindered by the lack of an in vivo model of TIE2 mutation. In addition, our lab has recently
shown that c-ABL, an intracellular tyrosine kinase, is activated in endothelial cells (EC) upon ligand stimulation
of TIE2 or with expression of mutant TIE2 p.L914F. Furthermore, we have also observed that ABL inhibition
mutually reduces TIE2 activation by an unknown mechanism. To address these questions, my proposal rests
on a central hypothesis: increased c-ABL signaling downstream of hyperactive mutant TIE2 p.L914F in
endothelial cells promotes formation of venous malformation through feed forward TIE2/c-ABL
signaling. We will address this hypothesis through the following Specific Aims: 1) define the effects of c-ABL on
TIE2 activation and signaling and 2) determine if c-ABL is required for formation of VM lesions in vivo. In this
work, we will define how ABL signaling affects physiological and pathological TIE2 activation in endothelial cells
utilizing in vitro functional assays and both loss of function and gain of function of c-ABL. We will also utilize our
newly developed transgenic mouse model of TIE2 L914F-driven VM to investigate the cellular defects associated
with VM pathogenesis. This model will then be used to investigate the role of c-ABL in VM formation in vivo and
provide preclinical testing of ABL inhibition for the treatment of VM. The information obtained from this project
will elucidate the relationship between TIE2 and c-ABL signaling in physiological and pathological vascular
function and will establish the first genetic mouse model of mutant TIE2-driven VM, which will be essential for
further study of the mechanisms of VM pathogenesis.

Grant Number: 5F31HL176101-02
NIH Institute/Center: NIH
Principal Investigator: Lindsay Bischoff

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