grant

Experience-dependent plasticity of circuit dynamics

Organization YALE UNIVERSITYLocation NEW HAVEN, UNITED STATESPosted 1 Jan 2024Deadline 31 Dec 2027
NIHUS FederalResearch GrantFY20252-photon21+ years oldAddressAdolescentAdolescent YouthAdultAdult HumanAmblyopiaAutomobile DrivingBrainBrain Nervous SystemCNS plasticityCell BodyCell Communication and SignalingCell SignalingCellsCerebral cortexCognitionComplexConnector NeuronCyclic SomatostatinDataDendritesDevelopmentElectrophysiologyElectrophysiology (science)ElementsEncephalonEquilibriumExposure toGoalsGrowth Hormone Inhibiting FactorsGrowth Hormone-Inhibiting HormoneImageInjuryIntercalary NeuronIntercalated NeuronsInterneuronsInternuncial CellInternuncial NeuronIntracellular Communication and SignalingLeadLearningMediatorMethodologyMethodsMiceMice MammalsMurineMusNerve CellsNerve UnitNeural CellNeurocyteNeuronal PlasticityNeuronsNeurophysiology / ElectrophysiologyPatternPb elementPeptidesPhysiologyPlayPopulationPrimary visual cortexPyramidal neuronRoleSRIHSRIH-14SensoryShapesSightSignal TransductionSignal Transduction SystemsSignalingSiteSomatostatinSomatostatin-14Somatotropin Release Inhibiting FactorsSomatotropin Release-Inhibiting HormoneStimulusStriate CortexStriate areaSynapsesSynapticTherapeuticTrainingTransmissionVisionVisualVisual CortexWorkadulthoodarea striatabalancebalance functionbiological signal transductioncentral nervous system plasticitydevelopmentaldrivingelectrophysiologicalexcitatory neuronexperiencegrowth hormone release inhibiting factorheavy metal Pbheavy metal leadhippocampal pyramidal neuronimaginginjuriesinsightjuvenilejuvenile humanmicroscope imagingmicroscopic imagingmicroscopy imagingmovieneuralneural circuitneural circuitryneural plasticityneurocircuitryneuronalneuroplasticneuroplasticitynew drug treatmentsnew drugsnew pharmacological therapeuticnew therapeuticsnew therapynext generation therapeuticsnovelnovel drug treatmentsnovel drugsnovel pharmaco-therapeuticnovel pharmacological therapeuticnovel therapeuticsnovel therapyoptogeneticsresponsesensory inputsocial rolesynapsesynaptic circuitsynaptic circuitrytransmission processtwo-photonvisual corticalvisual cortical plasticityvisual functionvisual informationvisual plasticityvisual processvisual processingvisual stimulus
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Full Description

PROJECT SUMMARY:
Plasticity of neural circuits is a key element underlying the brain's ability to adapt to experience, and
harnessing plasticity in the brain may provide new therapeutic avenues to ameliorate the effects of early
perturbation or injury. However, our understanding of plasticity in the adult brain remains incomplete. Although
adult plasticity in the visual cortex can be selectively induced through loss of sensory input or repeated
presentation of single stimuli, the impact of more broadly enriched sensory experience is unclear. In addition,
although the role of GABAergic inhibition in developmental visual plasticity has been deeply explored, the role
of inhibitory interneurons in adult plasticity remains largely unknown. In particular, cells that express the peptide
somatostatin (SST-INs) are thought to play a critical role in shaping the feature selectivity of visual responses in
mouse visual cortex, primarily via their robust inhibition of the dendrites of excitatory pyramidal neurons. SST-
INs are also critical mediators of visually-evoked activity patterns that facilitate long-range transmission of visual
information. However, the functional roles of SST-INs in adult plasticity remain unclear. Our preliminary data
suggest the surprising finding that visual experience consisting of repeated presentations of varied stimuli
induces a novel form of plasticity in adult mouse primary visual cortex, leading to robust enhancement of visually
evoked activity in SST-INs. This experience-dependent plasticity is accompanied by altered visual sensitivity in
nearby excitatory neurons. To further explore this observation, we propose to combine a number of
methodological approaches, including 2-photon imaging of identified neural populations, optogenetic
manipulations, and ex vivo synaptic physiology. We will determine the visual experience required to induce this
adult plasticity, identify the underlying cellular and synaptic mechanisms, and examine the functional
consequences for cortical visual encoding and transmission. Our results will provide an unprecedented level of
insight into a novel form of plasticity in the adult cortex and identify underlying cellular- and circuit-level
mechanisms.

Grant Number: 5R01EY035127-02
NIH Institute/Center: NIH
Principal Investigator: JESSICA CARDIN

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