0000000001188883

AUTHOR

Vaibhav P. Pai

showing 2 related works from this author

HCN2 Channel-Induced Rescue of Brain Teratogenesis via Local and Long-Range Bioelectric Repair

2020

Embryonic exposure to the teratogen nicotine results in brain defects, by disrupting endogenous spatial pre patterns necessary for normal brain size and patterning. Extending prior work in Xenopus laevis that showed that misexpression of ion channels can rescue morphogenesis, we demonstrate and characterize a novel aspect of developmental bioelectricity: channel-dependent repair signals propagate long-range across the embryo. We show that distal HCN2 channel misexpression and distal transplants of HCN2-expressing tissue, non-cell-autonomously reverse profound defects, rescuing brain anatomy, gene expression, and learning. Moreover, such rescue can be induced by small-molecule HCN2 channel a…

0301 basic medicineteratogenMorphogenesisXenopusregenerative medicineEndogenyBiologyRegenerative medicinelcsh:RC321-57103 medical and health sciencesCellular and Molecular Neuroscience0302 clinical medicinenon-locallcsh:Neurosciences. Biological psychiatry. NeuropsychiatryIon channelOriginal ResearchMechanism (biology)Embryobiology.organism_classificationEmbryonic stem cellCell biologylong-range030104 developmental biologybioelectricCellular Neuroscienceion channel030217 neurology & neurosurgerynicotineFrontiers in Cellular Neuroscience
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From non-excitable single-cell to multicellular bioelectrical states supported by ion channels and gap junction proteins: Electrical potentials as di…

2019

Endogenous bioelectric patterns within tissues are an important driver of morphogenesis and a tractable component of a number of disease states. Developing system-level understanding of the dynamics by which non-neural bioelectric circuits regulate complex downstream cascades is a key step towards both, an evolutionary understanding of ion channel genes, and novel strategies in regenerative medicine. An important capability gap is deriving rational modulation strategies targeting individual cells' bioelectric states to achieve global (tissue- or organ-level) outcomes. Here, we develop an ion channel-based model that describes multicellular states on the basis of spatio-temporal patterns of …

Gap Junction Proteins030303 biophysicsCellBiophysicsCell CommunicationRegenerative medicineModels BiologicalConnexinsIon ChannelsCell membrane03 medical and health sciencesmedicineMorphogenesisAnimalsHumansMolecular BiologyIon channelPhysics0303 health sciencesCell potentialElectrical potentialsGap JunctionsElectrophysiological PhenomenaMulticellular organismmedicine.anatomical_structureSingle-Cell AnalysisNeuroscienceSignal TransductionProgress in biophysics and molecular biology
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