2003
Compensatory Anion Currents in Kv1.3 Channel-deficient Thymocytes*
Koni PA, Khanna R, Chang MC, Tang MD, Kaczmarek LK, Schlichter LC, Flavell R. Compensatory Anion Currents in Kv1.3 Channel-deficient Thymocytes*. Journal Of Biological Chemistry 2003, 278: 39443-39451. PMID: 12878608, DOI: 10.1074/jbc.m304879200.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsApoptosisBase SequenceCell DivisionChloride ChannelsDNAFemaleGene ExpressionIon TransportKv1.3 Potassium ChannelLymphocyte ActivationMaleMembrane PotentialsMiceMice, Inbred C57BLMice, KnockoutPatch-Clamp TechniquesPotassium ChannelsPotassium Channels, Voltage-GatedRNA, MessengerT-LymphocytesConceptsWild-type cellsKv1.3-/- micePotassium channel subunitsVoltage-gated potassium channelsMouse thymocyte subsetsChloride currentsChannel subunitsAnion currentsT-cell activation/proliferationVoltage-dependent potassium currentsVolume regulationCell proliferationThymocyte apoptosisT cell responsesCell-mediated cytotoxicityObvious defectsCell activation/proliferationImmune system defectsT cell proliferationActivation/proliferationPotassium channelsLymph nodesCompensatory effectLymphocyte typeKv1.3
2001
Diversity in the Structure and Function of Ion Channels
B.Levitan I, Kaczmarek L. Diversity in the Structure and Function of Ion Channels. 2001, 139-162. DOI: 10.1093/oso/9780195145236.003.0007.Peer-Reviewed Original ResearchIon channelsGreat diversityDiversityConsiderable diversityRapid membrane depolarizationMembrane depolarizationElectrical activityVoltage-dependent sodium currentsVoltage-dependent potassium currentsAxonal membraneSquid giant axonNeuronal cell bodiesCell bodiesGiant axonsPotassium currentAction potentialsSodium currentMembraneActivityAxons
1998
When, where, and how much? Expression of the Kv3.1 potassium channel in high‐frequency firing neurons
Gan L, Kaczmarek L. When, where, and how much? Expression of the Kv3.1 potassium channel in high‐frequency firing neurons. Developmental Neurobiology 1998, 37: 69-79. PMID: 9777733, DOI: 10.1002/(sici)1097-4695(199810)37:1<69::aid-neu6>3.0.co;2-6.Peer-Reviewed Reviews, Practice Guidelines, Standards, and Consensus StatementsConceptsAuditory brain stem neuronsVoltage-dependent potassium currentsBrain stem neuronsHigh-frequency firing neuronsKv3.1 potassium channelStem neuronsKv3.1 potassium channel geneLong-term regulationSynaptic inputsPotassium currentPotassium channel genesNeuronsPotassium channelsKv3.1 geneKv3.1 subunitsFiring neuronsHigh frequencyChannel genesCurrent knowledgeChannels altersTranscriptional mechanismsCell-type specificityExpressionGene transcriptionExtrinsic factors
1997
Properties and regulation of the minK potassium channel protein
Kaczmarek L, Blumenthal E. Properties and regulation of the minK potassium channel protein. Physiological Reviews 1997, 77: 627-641. PMID: 9234960, DOI: 10.1152/physrev.1997.77.3.627.Peer-Reviewed Reviews, Practice Guidelines, Standards, and Consensus StatementsConceptsMinK proteinSingle transmembrane segmentPotassium channel proteinChannel-forming subunitTransmembrane segmentsMink genesChannel proteinsSecond messengerAmino acidsKvLQT1 channelsXenopus oocytesProteinNative currentsEpithelial cellsMinK mRNAIon selectivityVoltage-dependent potassium currentsResultant channelPotassium currentStrong candidateCellsGenesSubunitsVestibular organsMessenger
1993
Inward rectification of the minK potassium channel
Blumenthal E, Kaczmarek L. Inward rectification of the minK potassium channel. The Journal Of Membrane Biology 1993, 136: 23-29. PMID: 8271270, DOI: 10.1007/bf00241486.Peer-Reviewed Original ResearchConceptsMinK currentsVoltage-dependent potassium currentsOpen channel current-voltage relationshipPotassium currentChannel current-voltage relationshipPotassium channelsMinK potassium channels
1992
Expression of the H-ras oncogene induces potassium conductance and neuron-specific potassium channel mRNAs in the AtT20 cell line
Hemmick L, Perney T, Flamm R, Kaczmarek L, Birnberg N. Expression of the H-ras oncogene induces potassium conductance and neuron-specific potassium channel mRNAs in the AtT20 cell line. Journal Of Neuroscience 1992, 12: 2007-2014. PMID: 1607925, PMCID: PMC6575920, DOI: 10.1523/jneurosci.12-06-02007.1992.Peer-Reviewed Original ResearchConceptsRas-transfected cellsAtT20 cell lineAtT20 cellsEJ-ras oncogeneCell linesPotassium channelsVoltage-dependent potassium channelsRas proteinsPituitary-derived cellsMRNA speciesPlasma membraneSpliced productsPotassium channel mRNASame geneChannel mRNADifferential expressionPotassium currentExcitable cellsVoltage-dependent potassium currentsTwo- to threefold increaseMRNAOncogeneSpeciesExpressionPhenotypeModulation by cAMP of a slowly activating potassium channel expressed in Xenopus oocytes
Blumenthal E, Kaczmarek L. Modulation by cAMP of a slowly activating potassium channel expressed in Xenopus oocytes. Journal Of Neuroscience 1992, 12: 290-296. PMID: 1370322, PMCID: PMC6575684, DOI: 10.1523/jneurosci.12-01-00290.1992.Peer-Reviewed Original ResearchMeSH Keywords8-Bromo Cyclic Adenosine MonophosphateAmino Acid SequenceAnimalsCell MembraneCyclic AMPFemaleGene ExpressionHumansMembrane PotentialsMembrane ProteinsMolecular Sequence DataMutagenesis, Site-DirectedOocytesPhosphorylationPotassium ChannelsPotassium Channels, Voltage-GatedProgesteroneProtein Kinase InhibitorsProtein KinasesRatsRNATransfectionXenopus laevisConceptsMinK proteinCAMP-dependent protein kinasePotential phosphorylation sitesXenopus oocytesCAMP levelsPhosphorylation sitesProtein kinasePlasma membraneKinase activityChannel proteinsIntracellular cAMP levelsProtein inhibitorProteinKinasePotassium channelsOocytesVoltage-dependent potassium currentsIsK
1990
Control of potassium currents and cyclic AMP levels by autoactive neuropeptides in Aplysia neurons
Loechner K, Kaczmarek L. Control of potassium currents and cyclic AMP levels by autoactive neuropeptides in Aplysia neurons. Brain Research 1990, 532: 1-6. PMID: 2178030, DOI: 10.1016/0006-8993(90)91733-w.Peer-Reviewed Original ResearchConceptsVoltage-dependent potassium currentsCyclic AMP levelsBag cell neuronsPotassium currentCell neuronsAMP levelsAlpha-BCPWhole-cell patch-clamp techniqueCell patch-clamp techniqueBag cell afterdischargeTransient voltage-dependent potassium currentPatch-clamp techniqueDelayed potassium currentPharmacologic elevationClamp techniqueOutward currentsAfterdischargesNeuronsCell peptidesAplysia neuronsNeuropeptidesBeta-BCPConsistent effectSecond messengerAlpha
1987
Alpha bag cell peptide directly modulates the excitability of the neurons that release it
Kauer J, Fisher T, Kaczmarek L. Alpha bag cell peptide directly modulates the excitability of the neurons that release it. Journal Of Neuroscience 1987, 7: 3623-3632. PMID: 2824716, PMCID: PMC6569037, DOI: 10.1523/jneurosci.07-11-03623.1987.Peer-Reviewed Original ResearchConceptsAlpha-bag cell peptideBag cell neuronsAlpha-BCPCell neuronsBag cell peptidesPotassium currentCell peptidesVoltage-dependent potassium currentsCAMP levelsVoltage-dependent outward currentIntact abdominal gangliaBag cell clustersAdenylate cyclase activator forskolinAbility of forskolinCyclase activator forskolinLevels of cAMPVoltage-clamp experimentsElectrophysiological actionsIntracellular cAMP levelsImmunohistochemical stainingIntact gangliaAbdominal ganglionPhosphodiesterase inhibitorPharmacological elevationOutward currentsXenopus Oocytes Injected with Rat Uterine RNA Express Very Slowly Activating Potassium Currents
Boyle M, Azhderian E, MacLusky N, Naftolin F, Kaczmarek L. Xenopus Oocytes Injected with Rat Uterine RNA Express Very Slowly Activating Potassium Currents. Science 1987, 235: 1221-1224. PMID: 2434999, DOI: 10.1126/science.2434999.Peer-Reviewed Original ResearchConceptsUterine smooth muscleSmooth musclePotassium currentAction potentialsVoltage-dependent potassium currentsInfluence of estrogenUteri of estrogenXenopus Oocytes InjectedOvariectomized ratsRat brainProlonged burstsEstrogenRepetitive burstsNegative membrane potentialsInjected oocytesRatsExcitable tissuesMuscleXenopus oocytesMembrane potentialOocytesDepolarizationMyometriumUterusBrain