2015
DARPP-32 interaction with adducin may mediate rapid environmental effects on striatal neurons
Engmann O, Giralt A, Gervasi N, Marion-Poll L, Gasmi L, Filhol O, Picciotto MR, Gilligan D, Greengard P, Nairn AC, Hervé D, Girault JA. DARPP-32 interaction with adducin may mediate rapid environmental effects on striatal neurons. Nature Communications 2015, 6: 10099. PMID: 26639316, PMCID: PMC4675091, DOI: 10.1038/ncomms10099.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBehavior, AnimalBrainCaffeineCalmodulin-Binding ProteinsCentral Nervous System StimulantsChlorocebus aethiopsCocaineCOS CellsDendritic SpinesDopamine and cAMP-Regulated Phosphoprotein 32EnvironmentFluorescence Recovery After PhotobleachingImmunoblottingImmunohistochemistryIn Vitro TechniquesMass SpectrometryMiceMice, Inbred C57BLMutationNeostriatumNeuronsNucleus AccumbensPhosphorylationRatsRats, Sprague-DawleyRewardConceptsAdducin phosphorylationCytoskeletal proteinsActin filamentsMolecular pathwaysCellular mechanismsEnvironmental changesPhosphorylationDARPP-32Striatal neuronsAdducinMutant miceSynaptic stabilityProteinCascadeMultiple effectsEnvironmental effectsBindsDendritic spinesNeuronsModification of responsesBrief exposurePathwayInteractionFilamentsEnrichment
2006
The Prototoxin lynx1 Acts on Nicotinic Acetylcholine Receptors to Balance Neuronal Activity and Survival In Vivo
Miwa JM, Stevens TR, King SL, Caldarone BJ, Ibanez-Tallon I, Xiao C, Fitzsimonds RM, Pavlides C, Lester HA, Picciotto MR, Heintz N. The Prototoxin lynx1 Acts on Nicotinic Acetylcholine Receptors to Balance Neuronal Activity and Survival In Vivo. Neuron 2006, 51: 587-600. PMID: 16950157, DOI: 10.1016/j.neuron.2006.07.025.Peer-Reviewed Original ResearchMeSH KeywordsAdaptor Proteins, Signal TransducingAge FactorsAnimalsAssociation LearningBrainCell SurvivalExcitatory Amino Acid AgonistsMembrane GlycoproteinsMembrane PotentialsMiceMice, Mutant StrainsMutationNerve DegenerationNeuronsNeuropeptidesNicotineNicotinic AgonistsPatch-Clamp TechniquesReceptors, NicotinicConceptsNicotinic acetylcholine receptorsNull mutant miceMutant miceAcetylcholine receptorsNeuronal activityNull mutationBiological processesLynx1Calcium levelsAgonist sensitivityReceptor desensitizationSynaptic efficacyMutationsAllosteric modulatorsDesensitization kineticsWide arrayNicotineVivoSpecific testsNAChRsMiceReceptorsSurvivalHyperactivationFunction
2004
Role of neuronal nicotinic receptors in the effects of nicotine and ethanol on contextual fear conditioning
Wehner JM, Keller JJ, Keller AB, Picciotto MR, Paylor R, Booker TK, Beaudet A, Heinemann SF, Balogh SA. Role of neuronal nicotinic receptors in the effects of nicotine and ethanol on contextual fear conditioning. Neuroscience 2004, 129: 11-24. PMID: 15489024, DOI: 10.1016/j.neuroscience.2004.07.016.Peer-Reviewed Original ResearchConceptsContextual learningForms of learningEffects of nicotineFear conditioningCued fear conditioningContextual fear conditioningCognitive enhancing effectsBeta2 null mutant miceNicotine effectsBeta4-containing receptorsShock stimuliEffects of ethanolBeta2-containing nAChRsLearningNull mutant miceTrainingConditioningBrain nicotinic acetylcholine receptorsMutant miceNicotineNeuronal nicotinic receptorsHomozygous null mutant miceWild-type littermatesMemoryNicotinic acetylcholine receptors
2000
Pharmacological and null mutation approaches reveal nicotinic receptor diversity
Whiteaker P, Marks M, Grady S, Lu Y, Picciotto M, Changeux J, Collins A. Pharmacological and null mutation approaches reveal nicotinic receptor diversity. European Journal Of Pharmacology 2000, 393: 123-135. PMID: 10771005, DOI: 10.1016/s0014-2999(00)00052-2.Peer-Reviewed Reviews, Practice Guidelines, Standards, and Consensus StatementsConceptsNicotinic acetylcholine receptor functionNicotinic acetylcholine receptorsAcetylcholine receptor functionAcetylcholine receptorsNicotinic acetylcholine receptor bindingReceptor functionNative nicotinic acetylcholine receptorsNicotinic acetylcholine receptor subtypesWhole brain preparationAcetylcholine receptor bindingAcetylcholine receptor subtypesMouse brain membranesArray of assaysReceptor subtypesPharmacological comparisonComparative pharmacologyBrain nucleiBrain membranesEfflux techniqueReceptor bindingSubunit deletionReceptor diversityReceptorsAminobutyric acidSubtypes
1999
Two pharmacologically distinct components of nicotinic receptor-mediated rubidium efflux in mouse brain require the beta2 subunit.
Marks MJ, Whiteaker P, Calcaterra J, Stitzel JA, Bullock AE, Grady SR, Picciotto MR, Changeux JP, Collins AC. Two pharmacologically distinct components of nicotinic receptor-mediated rubidium efflux in mouse brain require the beta2 subunit. Journal Of Pharmacology And Experimental Therapeutics 1999, 289: 1090-103. PMID: 10215692.Peer-Reviewed Original ResearchConceptsBeta2 subunitBeta2 null mutant miceConcentration-effect curvesMouse brain synaptosomesAlpha4beta2 receptorsBrain synaptosomesNicotinic agonistsMouse brainRubidium effluxMutant miceLine radioactivity detectionDHbetaEAgonistsEffluxBrainStimulationRadioactivity detectionPotencyHexamethoniumErythroidineResponseAcetylcholineMethyllycaconitineAntagonistBungarotoxinModulation of morphine analgesia in αCGRP mutant mice
Salmon A, Damaj I, Sekine S, Picciotto M, Marubio L, Changeux J. Modulation of morphine analgesia in αCGRP mutant mice. Neuroreport 1999, 10: 849-854. PMID: 10208559, DOI: 10.1097/00001756-199903170-00033.Peer-Reviewed Original ResearchConceptsHot plate testMorphine analgesiaMutant miceTail-flick testPlate testWild-type miceMotor end platesPain pathwaysCGRP immunoreactivityMice lackFlick testMuscle synapsesAntinociceptive behaviorSpinal cordTail flickSpinal gangliaMiceAnalgesiaTargeted disruptionExon 5End platesMorphineGangliaCordImmunoreactivity
1998
Identification of Four Classes of Brain Nicotinic Receptors Using β2 Mutant Mice
Zoli M, Léna C, Picciotto M, Changeux J. Identification of Four Classes of Brain Nicotinic Receptors Using β2 Mutant Mice. Journal Of Neuroscience 1998, 18: 4461-4472. PMID: 9614223, PMCID: PMC6792706, DOI: 10.1523/jneurosci.18-12-04461.1998.Peer-Reviewed Original ResearchConceptsBeta2-/- miceElectrophysiological experimentsBrain regionsNeuronal nicotinic acetylcholine receptor subunitBrain nicotinic receptorsNicotinic acetylcholine receptor subunitsMost brain regionsPatch-clamp recordingsReceptor autoradiography studiesOrder of potencyDifferent brain areasAcetylcholine receptor subunitsThin brain slicesDifferent brain regionsIndividual alpha subunitsAutoradiography studiesBrain slicesNicotinic receptorsNicotinic agonistsHigh affinitySubunit compositionBrain areasAlpha subunitAlpha7 subunitType 2
1997
Mutant Mice and Neuroscience: Recommendations Concerning Genetic Background
Silva A, Simpson E, Takahashi J, Lipp H, Nakanishi S, Wehner J, Giese K, Tully T, Abel T, Chapman P, Fox K, Grant S, Itohara S, Lathe R, Mayford M, McNamara J, Morris R, Picciotto M, Roder J, Shin H, Slesinger P, Storm D, Stryker M, Tonegawa S, Wang Y, Wolfer D. Mutant Mice and Neuroscience: Recommendations Concerning Genetic Background. Neuron 1997, 19: 755-759. PMID: 9354323, DOI: 10.1016/s0896-6273(00)80958-7.Commentaries, Editorials and Letters
1995
Abnormal avoidance learning in mice lacking functional high-affinity nicotine receptor in the brain
Picciotto M, Zoli M, Léna C, Bessis A, Lallemand Y, LeNovère N, Vincent P, Pich E, Brûlet P, Changeux J. Abnormal avoidance learning in mice lacking functional high-affinity nicotine receptor in the brain. Nature 1995, 374: 65-67. PMID: 7870173, DOI: 10.1038/374065a0.Peer-Reviewed Original ResearchConceptsHigh-affinity nicotine receptorsNeuronal nicotinic acetylcholine receptorsBrains of miceΒ2-/- miceNicotinic acetylcholine receptorsThalamic neuronsNicotine applicationFunctional nAChRsNicotine receptorsBrain slicesNicotinic subunitsAbnormal avoidanceAcetylcholine receptorsAspects of behaviorHigh-affinity binding sitesMutant miceElectrophysiological recordingsPassive avoidanceAssociative memoryMiceNicotineNeuronal nicotinic subunitsNon-mutant siblingsBrainReceptors