grant

Human 3D neuro-muscular assembloids to study cell tropism and host factor utilization of divergent neuropathogenic enteroviruses

Organization STANFORD UNIVERSITYLocation STANFORD, UNITED STATESPosted 21 Mar 2022Deadline 28 Feb 2027
NIHUS FederalResearch GrantFY20260-11 years old3-D3-Dimensional3DAcute PoliomyelitisAddressAffectAnti-viral TherapyAssayAstrocytesAstrocytusAstrogliaBioassayBiological AssayBiologyBody TissuesBrain InflammationCNS Nervous SystemCRISPRCRISPR/Cas systemCell BodyCell CommunicationCell InteractionCell LineCell LineageCell ProtectionCell-to-Cell InteractionCellLineCellsCentral Nervous SystemCerebral cortexChildChild YouthChildren (0-21)Clustered Regularly Interspaced Short Palindromic RepeatsCortical CordCytoprotectionCytosolDiseaseDisease OutbreaksDisorderEV-68EV-71EV-A71EV-D68EncephalitisEndocytosisEnterovirusEnterovirus 68Enterovirus 71Enterovirus A71Enterovirus D68Enterovirus InfectionsEnzyme GeneEnzymesFoot DiseasesFoundationsGenesGeneticGenetic ScreeningGenomeGoalsHD GeneHD proteinHand's diseaseHind BrainHost FactorHost Factor ProteinHumanHuman poliovirusHuntingtinHuntingtin ProteinHuntington geneHuntington proteinHuntington's disease gene productIT15 geneImmune responseIn VitroIndividualInfectionInfectious AgentIntegration Host FactorsKnock-outKnockoutKnowledgeLaboratoriesLearningLecithinasesLifeMediatingMedicalMedulla SpinalisMeningitisMiceMice MammalsModelingModern ManMolecularMotorMotor CellMotor NeuronsMouth DiseasesMovementMurineMusMuscleMuscle Cell ContractionMuscle ContractionMuscle FibersMuscle TissueMuscular ContractionMyocarditisMyoneural JunctionMyotubesNamesNerve CellsNerve UnitNervous SystemNeural CellNeuraxisNeurocyteNeurologicNeurologic Body SystemNeurologic Organ SystemNeurologicalNeuromuscular JunctionNeuronsNeuropathogenesisNeurosciencesNeurotropismOligodendrocytesOligodendrocytusOligodendrogliaOligodendroglia CellOral Cavity DiseaseOral Cavity DisorderOral DiseaseOral DisorderOrganoidsOutbreaksPalsyParalysedPathogenesisPhospholipasePhysiologicPhysiologicalPlegiaPluripotent Stem CellsPolioPolio VirusPoliomyelitisPoliovirusPreparationProcessProteinsPublishingReceptor ProteinRegulationRespiratory DiseaseRespiratory System DiseaseRespiratory System DisorderRhabdomyocyteRhombencephalonRodentRodentiaRodents MammalsRoleSeriesSiteSkeletal FiberSkeletal MuscleSkeletal Muscle CellSkeletal Muscle FiberSkeletal MyocytesSpinal CordStrains Cell LinesSynapsesSynapticSystemTherapeutic InterventionTissuesTropismViralViral DiseasesViral ReceptorViral meningitisVirusVirus DiseasesVirus ReceptorsVoluntary MuscleWorkacute flaccid myelitisassembloidsastrocytic gliabody movementcardiac inflammationcell typecultured cell linecytoprotectivedisease modeldisorder modelemergent outbreakemerging outbreakengineered progenitor cellsengineered stem cellsgenome scalegenome-widegenomewidehindbrainhost responsehuman diseasehuman progenitorhuman stem cellsimmune system responseimmunoresponsein vivoinfected neonateinfected newborninfectious organisminsightinteresting transcript 15intervention therapykidsmotoneuronmouse modelmouth disordermurine modelmuscularnamenamednamingneonatal infectionneuralneuromuscularneuronalneuropathologicneuropathologicalneuropathologyneurotropicnew approachesnew drug targetnew druggable targetnew outbreaknew pharmacotherapy targetnew therapeutic targetnew therapy targetnewborn infectionnovelnovel approachesnovel drug targetnovel druggable targetnovel outbreaknovel pharmacotherapy targetnovel strategiesnovel strategynovel therapeutic targetnovel therapy targetoverexpressoverexpressionparalysisparalyticpathogenpluripotent progenitorpoliomyelitis viruspreparationsprogenitor biologyprogenitor cell biologyreceptorsocial rolestem and progenitor biologystem cell biologysynapsethree dimensionaltranscriptomicstranslational opportunitiestranslational potentialviral infectionviral infectious disease treatmentvirus host interactionvirus infectionvirus-induced diseaseyoungster
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Full Description

PROJECT SUMMARY
Enteroviruses are the leading cause of viral meningitis in children and recent outbreaks of emerging non-polio
enteroviruses (NPEVs) have been associated with a polio-like paralysis named acute flaccid myelitis (AFM).
Discovery and characterization of cellular components that are critical for neuropathogenesis hold promise for
revealing new approaches to treat enterovirus disease. In recent years, multiple receptors have been identified
for EV-A71 and EV-D68, NPEVs, which are most commonly associated with AFM. Using unbiased genome-
scale screens, we have identified the phospholipase PLA2G16 as an entry factor acting immediately
downstream of receptor engagement following NPEV infection. How the multiple receptors and PLA2G16 work
together to enable infection in cell types relevant for neuropathogenesis is, however, largely unknown. Infection
of cell types present in the central nervous system is critical for developing severe neurological forms of
disease following infection with NPEVs. Although mouse models have been widely used to gain insights into
enterovirus infection processes, genetic and physiological differences between human and rodents limit their
translational potential. Moreover, species incompatibilities in host factor interactions of these human
enteroviruses necessitate overexpression of human receptors, mouse-adapted strains or neonatal infections.
In work that forms a foundation for this proposal, we have developed from pluripotent stem cells human spinal
cord organoids that recapitulate some of the cell diversity of the human spinal cord. Importantly, we have
pioneered an approach to functionally connect motor neurons in spinal cord organoids with human skeletal
muscle and cortical neurons in a preparation we named assembloids. These motor assembloids form
functional neuro-muscular junctions and can control muscle contraction. Here, we propose to systematically
study the role of known host factors in cell lines derived from neural tissue on EV-A71 and EV-D68, discover
novel host factors by performing unbiased genome-scale genetic screens in neural cell lines, and compare cell
lineage tropism and effect on neuronal function during enterovirus infections of cortico-motor assembloids.
Our results will reveal the role and relative contribution of a distinct set of critical receptors and broad-acting
host factors to infection by multiple enteroviruses, discover and provide details on the molecular mechanism of
novel host factors in neural cell types, and leverage a unique neural organoid system to uncover the specific
tropism and functional effect on human neural-muscular circuits during infections with the paralytic
enteroviruses EV-D68 and EV-A71.

Grant Number: 5R01AI169467-05
NIH Institute/Center: NIH
Principal Investigator: Jan Carette

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