grant

Engineered BacNav and BacCav for Improved Excitability and Contraction

Organization DUKE UNIVERSITYLocation DURHAM, UNITED STATESPosted 1 May 2022Deadline 31 Jan 2027
NIHUS FederalResearch GrantFY202521+ years old3-D3-Dimensional3DAAV vectorAAV-based vectorAAV9 deliveryAAV9 mediated deliveryAAV9 vector deliveryAAV9 viral deliveryAAV9 virus to deliverAction PotentialsAddressAdultAdult HumanAdverse effectsAllelic LossAnimal ModelAnimal Models and Related StudiesAnti-Arrhythmia AgentsAnti-Arrhythmia DrugsAnti-ArrhythmicsArrhythmiaBirth DefectsBody TissuesBrugada syndromeCalciumCalcium ChannelCalcium Channel Antagonist ReceptorCalcium Channel Blocker ReceptorsCalcium Ion ChannelsCardiacCardiac ArrhythmiaCardiac DiseasesCardiac DisordersCardiac Electrophysiologic TechniquesCardiac Electrophysiological DiagnosticsCardiac Muscle CellsCardiac MyocytesCardiac infarctionCardiocyteCause of DeathCell BodyCell Culture TechniquesCellsChromosome MappingCodonCodon NucleotidesCommon Rat StrainsComputer SimulationComputer based SimulationCongenital AbnormalityCongenital Anatomical AbnormalityCongenital DefectsCongenital DeformityCongenital MalformationDNA TherapyDNA mutationDefectDeveloped CountriesDiseaseDisorderDysfunctionECGEKGEchocardiogramEchocardiographyElectrocardiogramElectrocardiographyElectrophysiologyElectrophysiology (science)EngineeringFibrosisFibrosis in the heartFibrosis in the myocardiumFibrosis within the heartFibrosis within the myocardiumFibrotic myocardiumFoundationsFunctional disorderFutureGene LocalizationGene MappingGene Mapping GeneticsGene Transfer ClinicalGenesGeneticGenetic ChangeGenetic EngineeringGenetic Engineering BiotechnologyGenetic Engineering Molecular BiologyGenetic InterventionGenetic defectGenetic mutationGoalsHeartHeart ArrhythmiasHeart DiseasesHeart Muscle CellsHeart failureHeart myocyteHumanHuman EngineeringHuman FigureHuman bodyImpairmentIn SituIn VitroIn vivo analysisIndustrialized CountriesIndustrialized NationsIonsIschemic HeartIschemic Heart DiseaseIschemic myocardiumK channelKineticsLeftLinkage MappingLoss of HeterozygosityMammalian CellMapsMeasurementMechanicsMediatingMembraneMethodsMiceMice MammalsModelingModern ManMurineMusMuscle Cell ContractionMuscle ContractionMuscular ContractionMutateMutationMyocardial InfarctMyocardial InfarctionMyocardial IschemiaMyocardiumNa elementNeonatalNeurophysiology / ElectrophysiologyOpticsOrthologOrthologous GenePathologyPermeabilityPhysiopathologyPlayPotassium ChannelPotassium Ion ChannelsPredispositionPreparationPropertyRatRats MammalsRattusRecombinant DNA TechnologyRegulationRoleSA node dysfunctionShort QT syndromeSick Sinus SyndromeSite-Directed MutagenesisSite-Specific MutagenesisSliceSodiumSodium ChannelSodium Ion ChannelsSpeedSusceptibilitySyndromeSystemTargeted DNA ModificationTargeted ModificationTestingTherapeuticTherapeutic EffectTissue ModelTissuesTotal Human and Non-Human Gene MappingTransthoracic EchocardiographyVDCCVariantVariationVentricularViralViral VectorVirusVoltage-Dependent Calcium ChannelsWorkadeno-associated viral vectoradeno-associated viral vector 9 deliveryadeno-associated virus 9 deliveryadeno-associated virus vectoradulthoodarrhythmic agentbiophysical characteristicsbiophysical characterizationbiophysical measurementbiophysical parametersbiophysical propertiescandidate identificationcardiac electrophysiologycardiac failurecardiac fibrosiscardiac functioncardiac infarctcardiac ischemiacardiac musclecardiac tissue engineeringcardiomyocytecell culturecell culturescomputational simulationcomputerized simulationcoronary attackcoronary fibrosiscoronary infarctcoronary infarctioncoronary ischemiadeveloped countrydeveloped nationdeveloped nationsdisease modeldisorder modelelectrophysiologicalengineered heart tissueextracellularfibrotic heartfunction of the heartgene repair therapygene therapygene-based therapygenetic mappinggenetic therapygenetically engineeredgenome mutationgenomic therapyheart attackheart disorderheart electrophysiologyheart fibrosisheart functionheart infarctheart infarctionheart ischemiaheart muscleheart sonographyhemodynamicsimprovedin silicoin vitro Modelin vivoin vivo evaluationin vivo testingloss of function mutationmechanicmechanicalmembrane structuremodel of animalmouse modelmurine modelmyocardial fibrosismyocardial ischemia/hypoxiamyocardium ischemianovelopticaloverexpressoverexpressionpatch clamppathophysiologypharmacologicpreparationspreventpreventingrecombinant viral vectorsinoatrial node dysfunctionsinus node dysfunctionsocial rolesudden cardiac deaththree dimensionaltraffickingtransgene expressionvoltage
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Full Description

Impaired cardiomyocyte excitability and contractile function represent important targets for preventing the
occurrence of sudden cardiac death and progression of heart failure. Growing mechanistic understanding of
cardiac pathologies and increasingly safe and effective methods to deliver viruses to human body make gene
therapies an attractive strategy for combatting various heart diseases. Specifically, the ability to genetically, in a
stable fashion, directly augment sodium or L-type calcium current in cardiomyocytes could directly enhance cell
excitability and contractility and counteract occurrence of electrical abnormalities in a variety of heart diseases.
However, cardiac Na+ or L-type Ca2+ channel genes are too large to be effectively delivered by therapeutic
viruses including adeno-associated viral (AAV) vectors. To address this challenge, we propose to develop a
novel AAV-based therapy that leverages engineering of much smaller prokaryotic voltage-gated sodium
(BacNav) and calcium (BacCav) channel genes. Our preliminary results show that genetically engineered BacNav
channels can improve cardiomyocyte excitability and action potential conduction in in vitro and in silico models
of rat and human fibrotic heart tissues. Furthermore, we demonstrate successful cardiomyocyte-specific AAV9
delivery of BacNav channels in healthy murine hearts without any adverse effects on cardiac electrophysiology
or contractile function. Building on these promising results, we propose to: 1) identify engineered BacNav variants
with specific mutations and trafficking motifs that maximize cardiomyocyte excitability and action potential speed
by utilizing in vitro cell culture, ex vivo heart slice preparations, and computer simulations and 2) engineer new
variants of BacCav, which alone or in combination with BacNav can augment not only cardiomyocyte excitability
but also contractile strength, which will be studied using engineered 3D heart tissue models in vitro. Finally, we
will exploit murine models of impaired cardiac tissue excitability (genetic loss of cardiac Na+ current (SCN5A+/-
)) or contractile dysfunction (myocardial infarction) to explore which of the identified BacNav and BacCav genes
delivered by AAV vector will induce optimal long-term therapeutic effects in vivo. If successful, these studies will
create a foundation for the future mechanistic studies of prokaryotic channel regulation in mammalian
cardiomyocytes and will guide testing of the engineered BacNav and BacCav channel therapies in large animal
models of heart disease.

Grant Number: 5R01EB032726-04
NIH Institute/Center: NIH
Principal Investigator: Nenad Bursac

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