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Project Details

G Protein signaling at the endosome

Project Number3R01GM080739-01S1

Contact PI/Project LeaderDOHLMAN, HENRIK G.

Awardee OrganizationUNIV OF NORTH CAROLINA CHAPEL HILL

Description

Abstract Text

Most hormones and neurotransmitters bind to cell surface receptors, activate G proteins, and produce a second messenger that propagates the signal within the cell. In yeast the G-beta/gamma subunits are necessary and sufficient for most aspects of the response to mating pheromones. Recently however,we determined that the G-alpha protein (Gpa1) can also transmit a signal mediated by the only known phosphatidylinositol 3-kinase in yeast (Vps34) and the phospholipid second messenger, Ptdlns 3-P. Notably, Gpa1 and Vps34 are both located at the endosome, far removed from receptors and the G-beta/gamma subunits. Our objective in this proposal is to identify other components of the pathway (receptor, G- beta/gamma, effector target) and the mechanism by which these proteins transmit their signal at the endosome. There are three specific aims: Aim 1. How is the G protein at the endosome activated? We have shown that Gpa1 stimulates Vps34 and Ptdlns 3-P production at the endosome but we do not know how Gpa1 is activated in this case. Our hypothesis is that Gpa1 and Vps34 are activated by internalized pheromone receptors and subsequently by a second exchange factor at the endosome. Aim 2. What are the G-beta/gamma-like proteins at the endosome? We found that the Ptdlns 3-kinase regulatory subunit Vps15 has a 7-WD repeat domain structure typical of that found in G-beta proteins. Our hypothesis is that Vps15 functions as the G-beta subunit at the endosome. Aim 3. How is G protein signaling at the endosome transmitted? We have shown that the Ptdlns 3-P- binding protein Bem1 translocates to the endosome in response to Gpa1 activation. Our hypothesis is that Ptdlns 3-P activates Bem1 and recruits a subset of signaling proteins to the endosome. These findings reveal a surprising new role and a new site of action for this well-characterized signaling molecule. Mechanisms discovered in yeast are usually recapitulated in higher eukaryotes, so the principles elucidated here will likely apply as well to hormone and neurotransmitter function in humans. Just as G protein coupled receptors at the cell surface are proven targets for the treatment of hypertension and diverse neurological disorders, intracellular receptors are likely as well to be useful in treating human disease.

Public Health Relevance Statement

Data not available.

NIH Spending Category

No NIH Spending Category available.

Project Terms

1-Phosphatidylinositol 3-KinaseAffinityBindingBinding ProteinsCell Surface ReceptorsCell membraneCell surfaceCellsCharacteristicsComplexCopperCytoplasmDissociationEmployee StrikesEndosomesEukaryotaEukaryotic CellEventFigs - dietaryFungal GenomeG Beta GammaG-Protein-Coupled ReceptorsGTP BindingGTP-Binding Protein alpha Subunits, GsGTP-Binding ProteinsGreen Fluorescent ProteinsGuanine Nucleotide Exchange FactorsGuanine NucleotidesGuanosine Triphosphate PhosphohydrolasesHormonesHumanIntracellular Second MessengerLinkMapsMediatingMitogen-Activated Protein KinasesModelingMolecular ConformationMonitorNeurotransmittersPartner in relationshipPathway interactionsPheromonePheromone ReceptorsPhosphatidylinositolsPhospholipidsPhosphotransferasesPhysiologicalPoint MutationProductionProtein OverexpressionProteinsRecruitment ActivityRelative (related person)Research PersonnelRoleSecond Messenger SystemsSeriesSignal PathwaySignal TransductionSignaling MoleculeSignaling ProteinSiteStructureSystemTestingTransducersUrsidae FamilyWD RepeatYeastshuman diseasehypertension treatmentmutantnervous system disordernovelphosphatidylinositol 3-phosphateprogramsprotein functionreceptorreceptor bindingresearch studyresponserhosecond messengeryeast protein

Details

Contact PI/ Project Leader

Name

DOHLMAN, HENRIK G.

Title

PROFESSOR AND CHAIR

Contact

Other PIs

Not Applicable

Program Official

Name

DUNSMORE, SARAH

Contact

Organization

Name

UNIV OF NORTH CAROLINA CHAPEL HILL

City

CHAPEL HILL

Country

UNITED STATES (US)

Department Type

BIOCHEMISTRY

Organization Type

SCHOOLS OF MEDICINE

State Code

Congressional District

Other Information

Opportunity Number

Study Section

Molecular Neuropharmacology and Signaling Study Section[MNPS]

Fiscal Year

2007

Award Notice Date

26-June-2007

Administering Institutes or Centers

National Institute of General Medical Sciences

CFDA Code

859

DUNS Number

608195277

UEI

D3LHU66KBLD5

Project Start Date

01-May-2007

Project End Date

28-February-2011

Budget Start Date

01-May-2007

Budget End Date

29-February-2008

Project Funding Information for 2007

Total Funding

$53,397

Direct Costs

$36,573

Indirect Costs

$16,824

Year	Funding IC	FY Total Cost by IC
2007	National Institute of General Medical Sciences	$53,397

Sub Projects

No Sub Projects information available for 3R01GM080739-01S1

Publications

Publications are associated with projects, but cannot be identified with any particular year of the project or fiscal year of funding. This is due to the continuous and cumulative nature of knowledge generation across the life of a project and the sometimes long and variable publishing timeline. Similarly, for multi-component projects, publications are associated with the parent core project and not with individual sub-projects.

No Publications available for 3R01GM080739-01S1

Patents

No Patents information available for 3R01GM080739-01S1

Outcomes

The Project Outcomes shown here are displayed verbatim as submitted by the Principal Investigator (PI) for this award. Any opinions, findings, and conclusions or recommendations expressed are those of the PI and do not necessarily reflect the views of the National Institutes of Health. NIH has not endorsed the content below.

No Outcomes available for 3R01GM080739-01S1

Clinical Studies

No Clinical Studies information available for 3R01GM080739-01S1

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