2022
Voltage imaging in the olfactory bulb using transgenic mouse lines expressing the genetically encoded voltage indicator ArcLight
Platisa J, Zeng H, Madisen L, Cohen LB, Pieribone VA, Storace DA. Voltage imaging in the olfactory bulb using transgenic mouse lines expressing the genetically encoded voltage indicator ArcLight. Scientific Reports 2022, 12: 1875. PMID: 35115567, PMCID: PMC8813909, DOI: 10.1038/s41598-021-04482-3.Peer-Reviewed Original ResearchConceptsTransgenic mouse lineMouse linesOlfactory bulbSubpopulation of interneuronsVivo mammalian brainTransgenic reporter animalsTransgenic reporter miceOlfactory receptor neuronsNeuronal electrical activityVoltage indicator ArcLightGlomerular layerReporter miceMammalian brainReceptor neuronsReporter animalsHigh expression levelsElectrical activityMembrane potential changesOdorant responsesNeural activityCell populationsSingle trialExpression levelsVivo experimentsDifferent cell types
2014
Mechanistic Studies of the Genetically Encoded Fluorescent Protein Voltage Probe ArcLight
Han Z, Jin L, Chen F, Loturco JJ, Cohen LB, Bondar A, Lazar J, Pieribone VA. Mechanistic Studies of the Genetically Encoded Fluorescent Protein Voltage Probe ArcLight. PLOS ONE 2014, 9: e113873. PMID: 25419571, PMCID: PMC4242678, DOI: 10.1371/journal.pone.0113873.Peer-Reviewed Original ResearchMeSH KeywordsAction PotentialsAmino AcidsAnimalsCells, CulturedFluorescenceFluorescent DyesGreen Fluorescent ProteinsHEK293 CellsHumansHydrogen-Ion ConcentrationKineticsLuminescent ProteinsMembrane PotentialsMicroscopy, ConfocalMutation, MissenseNeuronsPatch-Clamp TechniquesPrenylationRatsRecombinant Fusion ProteinsSpectrometry, Fluorescence
2012
Design Constraints for Mobile, High-Speed Fluorescence Brain Imaging in Awake Animals
Osman A, Park JH, Dickensheets D, Platisa J, Culurciello E, Pieribone VA. Design Constraints for Mobile, High-Speed Fluorescence Brain Imaging in Awake Animals. IEEE Transactions On Biomedical Circuits And Systems 2012, 6: 446-453. PMID: 23853231, DOI: 10.1109/tbcas.2012.2226174.Peer-Reviewed Original Research
2011
Random insertion of split-cans of the fluorescent protein venus into Shaker channels yields voltage sensitive probes with improved membrane localization in mammalian cells
Jin L, Baker B, Mealer R, Cohen L, Pieribone V, Pralle A, Hughes T. Random insertion of split-cans of the fluorescent protein venus into Shaker channels yields voltage sensitive probes with improved membrane localization in mammalian cells. Journal Of Neuroscience Methods 2011, 199: 1-9. PMID: 21497167, PMCID: PMC3281265, DOI: 10.1016/j.jneumeth.2011.03.028.Peer-Reviewed Original ResearchMeSH KeywordsBacterial ProteinsCell LineCell Line, TumorCell MembraneCytosolDNA Transposable ElementsFluorescent DyesHumansKidneyLuminescent ProteinsMembrane PotentialsMembrane ProteinsMicroscopy, ConfocalMicroscopy, FluorescenceModels, MolecularMutation, MissenseNeuroblastomaPatch-Clamp TechniquesPeptide FragmentsProtein FoldingProtein MultimerizationProtein Structure, SecondaryProtein Structure, TertiaryRecombinant Fusion ProteinsShaker Superfamily of Potassium ChannelsTransfectionConceptsShaker subunitsYellow fluorescent proteinEndoplasmic reticulumMammalian cellsNon-fluorescent halvesMisfolded monomersPlasma membrane expressionFluorescent protein VenusShaker potassium channelFluorescent protein (FP) voltage sensorsMembrane localizationPlasma membraneFluorescent proteinRandom insertionMembrane expressionSubunitsMembrane potentialIntracellular fluorescencePotassium channelsCellsFluorescent probeΔF/FVoltage sensorTetramerizationProtein
2008
Genetically encoded fluorescent sensors of membrane potential
Baker BJ, Mutoh H, Dimitrov D, Akemann W, Perron A, Iwamoto Y, Jin L, Cohen LB, Isacoff EY, Pieribone VA, Hughes T, Knöpfel T. Genetically encoded fluorescent sensors of membrane potential. Brain Cell Biology 2008, 36: 53. PMID: 18679801, PMCID: PMC2775812, DOI: 10.1007/s11068-008-9026-7.Peer-Reviewed Original Research
2006
Three fluorescent protein voltage sensors exhibit low plasma membrane expression in mammalian cells
Baker BJ, Lee H, Pieribone VA, Cohen LB, Isacoff EY, Knopfel T, Kosmidis EK. Three fluorescent protein voltage sensors exhibit low plasma membrane expression in mammalian cells. Journal Of Neuroscience Methods 2006, 161: 32-38. PMID: 17126911, DOI: 10.1016/j.jneumeth.2006.10.005.Peer-Reviewed Original Research
2002
A Genetically Targetable Fluorescent Probe of Channel Gating with Rapid Kinetics
Ataka K, Pieribone VA. A Genetically Targetable Fluorescent Probe of Channel Gating with Rapid Kinetics. Biophysical Journal 2002, 82: 509-516. PMID: 11751337, PMCID: PMC1302490, DOI: 10.1016/s0006-3495(02)75415-5.Peer-Reviewed Original ResearchConceptsGreen fluorescent proteinFluorescent proteinSkeletal muscle voltage-gated sodium channelVoltage-gated sodium channelsActivity reporterIntracellular loopChannel gatingTargetable fluorescent probeExcitable cellsFluorescent activity reportersMembrane potential changesExtended depolarizationSkeletal muscleReporterProteinSodium channelsChannel movementFluorescence signalRapid kineticsFluorescent probeCharge movementFluorescence
1998
Galanin–5-hydroxytryptamine interactions: electrophysiological, immunohistochemical and in situ hybridization studies on rat dorsal raphe neurons with a note on galanin R1 and R2 receptors
Xu Z, Zhang X, Pieribone VA, Grillner S, Hökfelt T. Galanin–5-hydroxytryptamine interactions: electrophysiological, immunohistochemical and in situ hybridization studies on rat dorsal raphe neurons with a note on galanin R1 and R2 receptors. Neuroscience 1998, 87: 79-94. PMID: 9722143, DOI: 10.1016/s0306-4522(98)00151-1.Peer-Reviewed Original ResearchConceptsDorsal raphe neuronsRaphe neuronsRat dorsal raphe neuronsCell bodiesOutward currentsInhibitory effectGalanin-like immunoreactivityDorsal raphe nucleusDose-dependent hyperpolarizationExtracellular potassium concentrationGalaninergic mechanismsSitu hybridization studiesGalanin receptorsRaphe nucleusSynaptic contactsNerve endingsPostsynaptic receptorsSoma levelGalaninImmunohistochemical analysisR2 receptorsGalanin R1NeuronsMood regulationPhysiological concentrations
1995
Distinct pools of synaptic vesicles in neurotransmitter release
Pieribone V, Shupliakov O, Brodin L, Hilfiker-Rothenfluh S, Czernik A, Greengard P. Distinct pools of synaptic vesicles in neurotransmitter release. Nature 1995, 375: 493-497. PMID: 7777058, DOI: 10.1038/375493a0.Peer-Reviewed Original ResearchConceptsNeurotransmitter releaseCellular secretory systemSynaptic vesiclesLow-frequency stimulationSynaptic release sitesRelease of neurotransmittersHigh-frequency burstsNeuron-specific proteinSynapsin antibodiesPool of vesiclesDistal poolNerve terminalsMarked depressionVesicular releasePresynaptic membraneSynapsinHigh rateClusters of vesiclesApparent effectReleaseSecretory systemSuch protein familiesNeurotransmittersRelease sitesGalanin induces a hyperpolarization of norepinephrine-containing locus coeruleus neurons in the brainstem slice
Pieribone VA, Xu Z, Zhang X, Grillner S, Bartfai T, Hökfelt T. Galanin induces a hyperpolarization of norepinephrine-containing locus coeruleus neurons in the brainstem slice. Neuroscience 1995, 64: 861-874. PMID: 7538638, DOI: 10.1016/0306-4522(94)00450-j.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBrain StemCalciumGalaninImmunohistochemistryLocus CoeruleusMaleMembrane PotentialsPeptidesRatsRats, Sprague-DawleyTetrodotoxinConceptsLocus coeruleus neuronsCoeruleus neuronsLocus coeruleusNet outward currentGalanin responseOutward currentsATP-sensitive potassium channelsNorepinephrine-containing locus coeruleus neuronsCoexistence of galaninEffects of galaninPotassium concentrationExtracellular potassium concentrationEndogenous galaninGalanin applicationNormal potassium concentrationGalanin effectsGalanin immunoreactivityBrainstem slicesNorepinephrine neuronsAxonal originLow calcium mediumNeuronal somataSlice preparationImmunohistochemical stainingGalanin