2024
Neurons for infant social behaviors in the mouse zona incerta
Li Y, Liu Z, Santana G, Capaz A, Doumazane E, Gao X, Renier N, Dietrich M. Neurons for infant social behaviors in the mouse zona incerta. Science 2024, 385: 409-416. PMID: 39052814, DOI: 10.1126/science.adk7411.Peer-Reviewed Original ResearchConceptsInfant social behaviorSocial behaviorZona incertaSomatostatin-expressing neuronsNeural basisInfant behaviorBehavioral distressEmotional developmentMaternal presenceNeural activity manipulationFacilitation of learningBrain centersSocial interactionPopulations of neuronsInfant mouse brainPreweaning miceMouse brainNeuronsInfantsMiceActive manipulationBehaviorMothersDistressIncerta
2023
Characterization of behavioral avoidance to a food allergen in different strains of mice
Lima B, Cullen J, de Paula Carvalho L, Bober J, Florsheim E, Medzhitov R, Dietrich M. Characterization of behavioral avoidance to a food allergen in different strains of mice. Brain Behavior And Immunity 2023, 114: 71. DOI: 10.1016/j.bbi.2024.01.204.Peer-Reviewed Original Research
2015
Hypothalamic Agrp Neurons Drive Stereotypic Behaviors beyond Feeding
Dietrich MO, Zimmer MR, Bober J, Horvath TL. Hypothalamic Agrp Neurons Drive Stereotypic Behaviors beyond Feeding. Cell 2015, 160: 1222-1232. PMID: 25748653, PMCID: PMC4484787, DOI: 10.1016/j.cell.2015.02.024.Peer-Reviewed Original ResearchConceptsHypothalamic AgRP neuronsAgRP neuronsNeuropeptidergic signalingReceptor signalingFunctional rolePotential therapeutic avenuesAgRP neuron activationStereotypic behaviorFeeding behaviorRepetitive behaviorsSignalingTherapeutic avenuesFood triggersAdult miceNervous systemDecreased anxietyNeuronsMinor effectActivationFood consumptionNeuron activationGoal-directed behaviorSensory informationFlexible goal-directed behaviorDisease
2014
O-GlcNAc Transferase Enables AgRP Neurons to Suppress Browning of White Fat
Ruan HB, Dietrich MO, Liu ZW, Zimmer MR, Li MD, Singh JP, Zhang K, Yin R, Wu J, Horvath TL, Yang X. O-GlcNAc Transferase Enables AgRP Neurons to Suppress Browning of White Fat. Cell 2014, 159: 306-317. PMID: 25303527, PMCID: PMC4509746, DOI: 10.1016/j.cell.2014.09.010.Peer-Reviewed Original ResearchConceptsAgRP neuronsFundamental cellular processesWhite fatN-acetylglucosamine (O-GlcNAc) modificationOrexigenic AgRP neuronsVoltage-dependent potassium channelsCellular processesGlcNAc transferaseDynamic physiological processesNuclear proteinsWhite adipose tissue browningPhysiological processesAdipose tissue browningDiet-induced obesityPhysiological relevanceTissue browningGenetic ablationBeige cellsEnergy metabolismInsulin resistanceNeuronal excitabilityPotassium channelsAdipose tissueCentral mechanismsNeurons
2013
Mitofusin 2 in POMC Neurons Connects ER Stress with Leptin Resistance and Energy Imbalance
Schneeberger M, Dietrich MO, Sebastián D, Imbernón M, Castaño C, Garcia A, Esteban Y, Gonzalez-Franquesa A, Rodríguez IC, Bortolozzi A, Garcia-Roves PM, Gomis R, Nogueiras R, Horvath TL, Zorzano A, Claret M. Mitofusin 2 in POMC Neurons Connects ER Stress with Leptin Resistance and Energy Imbalance. Cell 2013, 155: 172-187. PMID: 24074867, PMCID: PMC3839088, DOI: 10.1016/j.cell.2013.09.003.Peer-Reviewed Original ResearchConceptsHypothalamic ER stressER stress-induced leptin resistanceLeptin resistanceMitofusin 2ER stressMitochondria-endoplasmic reticulum interactionAnorexigenic pro-opiomelanocortin (POMC) neuronsPro-opiomelanocortin (POMC) neuronsDiet-induced obesityMitochondria-ER contactsSystemic energy balancePOMC neuronsMetabolic alterationsCausative factorsEnergy expenditurePOMC processingObesityUnderlying mechanismCrucial involvementNeuronsEnergy imbalanceEssential regulatorCritical roleHyperphagiaHypothalamusMitochondrial Dynamics Controlled by Mitofusins Regulate Agrp Neuronal Activity and Diet-Induced Obesity
Dietrich MO, Liu ZW, Horvath TL. Mitochondrial Dynamics Controlled by Mitofusins Regulate Agrp Neuronal Activity and Diet-Induced Obesity. Cell 2013, 155: 188-199. PMID: 24074868, PMCID: PMC4142434, DOI: 10.1016/j.cell.2013.09.004.Peer-Reviewed Original ResearchConceptsMitochondrial dynamicsEnergy metabolismCell-type specificCellular energy metabolismWhole-body energy metabolismKey organellesMitofusin 1Mitofusin 2High-fat dietMitochondria sizeAgRP neuronsMfn1Anorexigenic pro-opiomelanocortin (POMC) neuronsAgRP neuronal activityKnockout miceMetabolismPro-opiomelanocortin (POMC) neuronsFusion mechanismDiet-Induced ObesityMitofusinsOverfed stateImportant roleCellsDynamic changesOrganellesHigh saturated fat and low carbohydrate diet decreases lifespan independent of body weight in mice.
Muller AP, Dietrich Mde O, Martimbianco de Assis A, Souza DO, Portela LV. High saturated fat and low carbohydrate diet decreases lifespan independent of body weight in mice. Longevity & Healthspan 2013, 2: 10. PMID: 24472284, PMCID: PMC3922950, DOI: 10.1186/2046-2395-2-10.Peer-Reviewed Original ResearchHypothalamic control of energy balance: insights into the role of synaptic plasticity
Dietrich MO, Horvath TL. Hypothalamic control of energy balance: insights into the role of synaptic plasticity. Trends In Neurosciences 2013, 36: 65-73. PMID: 23318157, DOI: 10.1016/j.tins.2012.12.005.Peer-Reviewed Original ResearchConceptsWhole-body energy metabolismRegion-specific expressionGenetic toolsPeripheral tissue functionsMetabolism regulationMetabolic hormone receptorsEnergy metabolismTissue functionMetabolic eventsRole of neuronsHormone receptorsRegulationGlial cellsHypothalamic controlSynaptic plasticityCentral regulationNeuronal circuitsBrain circuitsEnormous leapPlasticitySurprising findingRoleExpressionMetabolismDynamic process
2012
Limitations in anti-obesity drug development: the critical role of hunger-promoting neurons
Dietrich MO, Horvath TL. Limitations in anti-obesity drug development: the critical role of hunger-promoting neurons. Nature Reviews Drug Discovery 2012, 11: 675-691. PMID: 22858652, DOI: 10.1038/nrd3739.Peer-Reviewed Original ResearchConceptsNPY/AgRP neuronsNegative energy balanceSevere side effectsAgRP neuronsPOMC neuronsPositive energy balanceChronic disordersPeripheral tissuesReactive oxygen speciesSide effectsLong-term positive energy balanceCalorie restrictionAnti-obesity drug developmentBehavioral interventionsIntense behavioral interventionsPro-opiomelanocortin (POMC) neuronsChronic metabolic disorderLong-term treatmentWhite adipose tissueAlternative therapeutic approachAnti-obesity therapiesPromotion of satietyNew drug therapiesPopulations of neuronsHigher brain functionsAgRP neurons regulate development of dopamine neuronal plasticity and nonfood-associated behaviors
Dietrich MO, Bober J, Ferreira JG, Tellez LA, Mineur YS, Souza DO, Gao XB, Picciotto MR, Araújo I, Liu ZW, Horvath TL. AgRP neurons regulate development of dopamine neuronal plasticity and nonfood-associated behaviors. Nature Neuroscience 2012, 15: 1108-1110. PMID: 22729177, PMCID: PMC3411867, DOI: 10.1038/nn.3147.Peer-Reviewed Original Research
2010
Agrp Neurons Mediate Sirt1's Action on the Melanocortin System and Energy Balance: Roles for Sirt1 in Neuronal Firing and Synaptic Plasticity
Dietrich MO, Antunes C, Geliang G, Liu ZW, Borok E, Nie Y, Xu AW, Souza DO, Gao Q, Diano S, Gao XB, Horvath TL. Agrp Neurons Mediate Sirt1's Action on the Melanocortin System and Energy Balance: Roles for Sirt1 in Neuronal Firing and Synaptic Plasticity. Journal Of Neuroscience 2010, 30: 11815-11825. PMID: 20810901, PMCID: PMC2965459, DOI: 10.1523/jneurosci.2234-10.2010.Peer-Reviewed Original ResearchConceptsFood intakeMelanocortin systemAgRP neuronal activityAnorexigenic POMC neuronsHypothalamic melanocortin systemAction of SIRT1Negative energy balanceAgRP neuronsPOMC neuronsCre-lox technologyInhibitory toneMC4R antagonistFat massLean massSynaptic inputsNeuronal activityNeuronal firingAdult miceBody weightSIRT1 inhibitorSynaptic plasticityCalorie restrictionMelanocortin receptorsSIRT1 activityBody metabolism
2008
Exercise-Induced Synaptogenesis in the Hippocampus Is Dependent on UCP2-Regulated Mitochondrial Adaptation
Dietrich MO, Andrews ZB, Horvath TL. Exercise-Induced Synaptogenesis in the Hippocampus Is Dependent on UCP2-Regulated Mitochondrial Adaptation. Journal Of Neuroscience 2008, 28: 10766-10771. PMID: 18923051, PMCID: PMC3865437, DOI: 10.1523/jneurosci.2744-08.2008.Peer-Reviewed Original ResearchConceptsSynaptic plasticityVoluntary exerciseEssential organellesUCP2 functionProtein-2 mRNA expressionDendritic spine synapsesBioenergetic adaptationMitochondrial metabolismMitochondrial oxygen consumptionMitochondrial numberEnergetic needsMitochondrial adaptationsMitochondrial mechanismsExercise inducesDentate gyrusStratum radiatumSpine synapsesCA1 regionGlial morphologyHippocampal formationNeuronal activityGranule cellsAction potentialsNeuronal morphologyMRNA expression