grant

Deciphering the complex pharmacology of CB1: towards the understanding of a third signaling pathway

Organization TEMPLE UNIV OF THE COMMONWEALTHLocation PHILADELPHIA, UNITED STATESPosted 15 Aug 2023Deadline 31 Jul 2026
NIHUS FederalResearch GrantFY20243'5'-cyclic ester of AMPAdenosine Cyclic 3',5'-MonophosphateAdenosine Cyclic MonophosphateAdenosine, cyclic 3',5'-(hydrogen phosphate)AgonistAmino Acid MotifsAmino AcidsAnalgesic AgentsAnalgesic DrugsAnalgesic PreparationAnalgesicsAnochlesiaAnodynesAntinociceptive AgentsAntinociceptive DrugsArrestinsAssayB. pertussis toxinBasal Transcription FactorBasal transcription factor genesBehavioralBindingBioassayBiological AssayBody TemperatureBordetella pertussis toxinC-terminalC57BL/6 MouseCB1CB1 ReceptorCB1RCNR1 geneCannabinoid Receptor CB1CannabinoidsCatalepsyCell BodyCell Communication and SignalingCell SignalingCellsCholineComplexConsensusCouplesCuesCyclic AMPCyclic GMPDataDevelopmentDysfunctionExperimental DesignsFK506 Binding Protein 12-Rapamycin Associated Protein 1FKBP12 Rapamycin Complex Associated Protein 1FRAP1FRAP1 geneFRAP2FemaleFunctional disorderG Protein-Complex ReceptorG Protein-Coupled Receptor GenesG Protein-Coupled Receptor SignalingG-Protein-Coupled ReceptorsGDP Dissociation FactorGDP Dissociation StimulatorsGDP Exchange FactorsGDP-GTP Exchange ProteinGDP-GTP Reversing FactorsGPCRGPCR SignalingGTP BindingGTP GDP exchange factorGTP boundGeneral Transcription Factor GeneGeneral Transcription FactorsGenerationsGenetic AlterationGenetic ChangeGenetic defectGenomicsGoalsGuanine Nucleotide Exchange FactorsGuanine Nucleotide Exchange ProteinGuanine Nucleotide Releasing FactorsGuanosine Cyclic MonophosphateGuanyl-Nucleotide Exchange FactorGuanyl-Nucleotide Releasing FactorHistamine-Sensitizing FactorHydrophobicityIAP Pertussis ToxinImageIntracellular Communication and SignalingIntracellular Second MessengerInvestigationIslet-Activating ProteinKnowledgeLecithinase DLigandsLocomotor ActivityLymphocytosis-Promoting FactorMeasurementMeasuresMechanistic Target of RapamycinMediatingMolecularMolecular InteractionMonomeric G-ProteinsMonomeric GTP-Binding ProteinsMotor ActivityMutateMutationNerve CellsNerve UnitNeural CellNeurocyteNeuronsPathway interactionsPeptide DomainPertussigenPertussis ToxinPharmacologyPhosphatidic AcidPhosphatidylcholine PhosphohydrolasePhospholipase DPhysiologyPhysiopathologyProtein CProtein DomainsProtein MotifsProteinsRAFT1Receptor ActivationReceptor Mediated Signal TransductionReceptor ProteinReceptor SignalingRetinal S-AntigenRoleSecond Messenger SystemsSecond MessengersSequence AlignmentSignal InductionSignal PathwaySignal TransductionSignal Transduction SystemsSignalingSmall G-ProteinsSmall GTPasesSolidSpecificityStimulusStructural ProteinTailTertiary Protein StructureTestingTranscription Factor Proto-OncogeneTranscription factor genesTransfectionWorkadenosine 3'5' monophosphateaminoacidantinociceptionantinociceptivearrestin Bbeta-arrestinbiological signal transductioncAMPcGMPcannabinoid receptor 1cannabinoid receptor type 1cannabinoid type 1developmentaldrug developmentexchange factorexperimentexperimental researchexperimental studyexperimentsextracellulargenome mutationimagingin vivoinhibitorinterdisciplinary approachlipophosphodiesterase IImTORmalemammalian target of rapamycinmultidisciplinary approachmutantneuronalpain killerpain medicationpain relieverpainkillerpathophysiologypathwaypharmacologicphosphatidylcholine phosphatidohydrolasereceptorresponserhorho G-Proteinsrho GTP-Binding Proteinsrho GTPasesrho Protein P21rho Small GTP-Binding Proteinssequencing alignmentsexsignal transduction second messengerssocial roletherapeutic agent developmenttherapeutic developmenttranscription factorβ-arrestin
Sign up free to applyApply link · pipeline · email alerts
— or —

Get email alerts for similar roles

Weekly digest · no password needed · unsubscribe any time

Full Description

ABSTRACT
Understanding the mechanisms underlying GPCR signaling is crucial in order to fully comprehend their role in
physiology and pathophysiology. In addition to canonical second messengers (cAMP, cGMP and IP3) and β-
arrestin signaling, small GTPase proteins, such as Rho GTPases are largely involved in GPCR-mediated signal
transduction. Guanine nucleotide exchange factors (GEFs) convert Rho GTPases from an inactive (GDP-bound)
state to an active state (GTP-bound). Rho-GEFs can be activated by Gq, G12/13 and Gs proteins. However,
currently there is no evidence that Gi/0-WT can directly activate RhoGEFs. PDZ domains are structural protein
domains that recognize simple linear amino acid motifs often at the protein C-terminal (C-motif). RhoA, activated
by PDZ-RhoGEFs, has important signaling roles, by activating phospholipase D (PLD) and transcription factors.
Cannabinoid receptor CB1, an abundantly expressed GPCR that mainly couples to Gi/o, has a EAL C-motif (last
three amino acids) that binds PDZ class III proteins, including PDZ-RhoGEF. Our central hypothesis is that CB1
receptor activation, in addition to engaging cAMP inhibition and β-arrestin pathways, initiates an additional
signaling mechanism downstream to PDZ-RhoGEF leading to activation of RhoA and subsequent activation of
PLD. Activation of PLD generates two distinct second messengers, phosphatidic acid, which activates the mTOR
pathway, and choline, which activates Sigma1 receptors. We will use a multidisciplinary approach, combining
state-of-the-art molecular and pharmacological approaches for a comprehensive investigation of the signaling
pathways elicited by activation of C-motifs of CB1 receptor and identification of pathways-selective ligands. We
will use receptor and PDZ-RhoGEF mutations, measurements of second messengers levels (cAMP, choline and
phosphatidic acid) as well as live imaging of PLD activation. We provide solid preliminary results supporting the
feasibility of the project and the ability of our team to complete the work proposed. The project has two aims:
Aim 1. Investigate the role of PDZ-binding domain in CB1-induced signaling; experiments are designed to
characterize intracellular cascades activated by CB1-motifs (CB1-PDZ binding domain. Aim 2. Investigate the
role of PDZ-RhoGEF/RhoA pathway in CB1 receptor signaling in cultured primary neurons and in vivo. The
successful completion of this project will increase the current knowledge of GPCR signaling and will serve as a
basis for further development of ligands selectively targeting this pathway.

Grant Number: 5R21DA056729-02
NIH Institute/Center: NIH
Principal Investigator: EUGEN BRAILOIU

Sign up free to get the apply link, save to pipeline, and set email alerts.

Sign up free →

Agency Plan

7-day free trial

Unlock procurement & grants

Upgrade to access active tenders from World Bank, UNDP, ADB and more — with email alerts and pipeline tracking.

$29.99 / month

  • 🔔Email alerts for new matching tenders
  • 🗂️Track tenders in your pipeline
  • 💰Filter by contract value
  • 📥Export results to CSV
  • 📌Save searches with one click
Start 7-day free trial →

Explore more

📍 More grants in UNITED STATES🏷 More NIH opportunities🏷 More US Federal opportunities🏷 More Research Grant opportunities🏢 All nih_reporter opportunities