2021
Discovery and functional interrogation of SARS-CoV-2 RNA-host protein interactions
Flynn RA, Belk JA, Qi Y, Yasumoto Y, Wei J, Alfajaro MM, Shi Q, Mumbach MR, Limaye A, DeWeirdt PC, Schmitz CO, Parker KR, Woo E, Chang HY, Horvath TL, Carette JE, Bertozzi CR, Wilen CB, Satpathy AT. Discovery and functional interrogation of SARS-CoV-2 RNA-host protein interactions. Cell 2021, 184: 2394-2411.e16. PMID: 33743211, PMCID: PMC7951565, DOI: 10.1016/j.cell.2021.03.012.Peer-Reviewed Original ResearchConceptsSARS-CoV-2 RNASARS-CoV-2Virus-induced cell deathHost protein interactionsRNA-binding proteinActive infectionRNA virusesHost-virus interfaceGlobal mortalityTherapeutic benefitCRISPR screensAntiviral factorsProtein interactionsAntiviral activityViral specificityHost pathwaysFunctional RNA-binding proteinsFunctional connectionsRNA-centric approachesCell deathHost proteinsVirusFunctional interrogationRNAComprehensive catalog
2004
Low CA1 Spine Synapse Density is Further Reduced by Castration in Male Non-human Primates
Leranth C, Prange-Kiel J, Frick KM, Horvath TL. Low CA1 Spine Synapse Density is Further Reduced by Castration in Male Non-human Primates. Cerebral Cortex 2004, 14: 503-510. PMID: 15054066, DOI: 10.1093/cercor/bhh012.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCell CountChlorocebus aethiopsDendritesHumansMaleOrchiectomyPyramidal CellsReference ValuesSynapsesConceptsSpine synapse densitySynapse densityNon-human primatesSpine synapsesCA1 spine synapse densityPyramidal cell apical dendritesCA1 hippocampal areaCell apical dendritesCA1 stratum radiatumFemale non-human primatesMale non-human primatesMale primatesOrchidectomized animalsApical dendritesCA1 areaDendritic shaftsHippocampal areaStratum radiatumGonadal hormonesControl monkeysMale hippocampusGonadectomized animalsOvariectomized femalesAndrogen hormonesPrimate hippocampus
2003
Fasting Activates the Nonhuman Primate Hypocretin (Orexin) System and Its Postsynaptic Targets
Diano S, Horvath B, Urbanski HF, Sotonyi P, Horvath TL. Fasting Activates the Nonhuman Primate Hypocretin (Orexin) System and Its Postsynaptic Targets. Endocrinology 2003, 144: 3774-3778. PMID: 12933647, DOI: 10.1210/en.2003-0274.Peer-Reviewed Original ResearchConceptsPerifornical regionArcuate nucleusHypothalamic regulationC-Fos-expressing cellsLateral hypothalamic cellsC-fosMedial preoptic areaVariety of endocrineC-fos expressionDiverse brain regionsHCRT axonsLeptin levelsNuclear c-FosDorsomedial hypothalamusAsymmetric synapsesBasal forebrainPresent studyPostsynaptic targetsDorsomedial nucleusNeuropeptide Y.Preoptic areaThalamic nucleiHcrt neuronsHcrt systemAxon terminalsCoenzyme Q Induces Nigral Mitochondrial Uncoupling and Prevents Dopamine Cell Loss in a Primate Model of Parkinson’s Disease
Horvath TL, Diano S, Leranth C, Garcia-Segura LM, Cowley MA, Shanabrough M, Elsworth JD, Sotonyi P, Roth RH, Dietrich EH, Matthews RT, Barnstable CJ, Redmond DE. Coenzyme Q Induces Nigral Mitochondrial Uncoupling and Prevents Dopamine Cell Loss in a Primate Model of Parkinson’s Disease. Endocrinology 2003, 144: 2757-2760. PMID: 12810526, DOI: 10.1210/en.2003-0163.Peer-Reviewed Original ResearchConceptsDopamine cell lossParkinson's diseaseCell lossShort-term oral administrationMitochondrial uncouplingSubstantia nigraDopamine neuronsTetrahydropyridine (MPTP) administrationCoenzyme QPrimate modelOral administrationDiseaseOxidative stressState 4 respirationMitochondrial uncoupling proteinAdministrationUncoupling proteinUncouplingNeuronsNigraTetrahydropyridine
2002
Uncoupling protein 2 in primary pain and temperature afferents of the spinal cord
Horvath B, Spies C, Warden CH, Diano S, Horvath TL. Uncoupling protein 2 in primary pain and temperature afferents of the spinal cord. Brain Research 2002, 955: 260-263. PMID: 12419545, DOI: 10.1016/s0006-8993(02)03364-4.Peer-Reviewed Original ResearchConceptsSpinal cordExpression of UCP2Primary sensory afferentsMechanisms of painProtein 2Primary painSensory afferentsSubstantia gelatinosaVentral hornSubstance P.Axon terminalsCordEnergy homeostasisUCP2 expressionDirect appositionTemperature sensationMitochondrial protonophorePainAfferentsUCP2Mitochondrial uncouplerCellular energy homeostasisExpressionPerikaryaAxons
2001
Estrogen Synthetase (Aromatase) Immunohistochemistry Reveals Concordance Between Avian and Rodent Limbic Systems and Hypothalami
Naftolin F, Horvath T, Balthazart J. Estrogen Synthetase (Aromatase) Immunohistochemistry Reveals Concordance Between Avian and Rodent Limbic Systems and Hypothalami. Experimental Biology And Medicine 2001, 226: 717-725. PMID: 11520936, DOI: 10.1177/153537020222600802.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAromataseBiological EvolutionBirdsChlorocebus aethiopsCoturnixHumansHypothalamusImmunohistochemistryLimbic SystemRatsConceptsHypothalamus of birdsAppearance of birdsAmniote evolutionEarly divergenceVertebrate groupsDivergent evolutionAvian homologHomologous brain structuresMajor anatomical differencesCommon functionMammalsCellular levelBirdsOptic lobeAvian brainMorphological criteriaDifferent functional requirementsPrinciples of neurobiologyAnatomical dissimilaritiesHomologAnatomical differencesMammalian brain regionsAviansRodent limbic systemSynthetaseOestrogen‐Induced Changes in the Synaptology of the Monkey (Cercopithecus aethiops) Arcuate Nucleus During Gonadotropin Feedback
Zsarnovszky A, Horvath TL, Garcia‐Segura L, Horvath B, Naftolin F. Oestrogen‐Induced Changes in the Synaptology of the Monkey (Cercopithecus aethiops) Arcuate Nucleus During Gonadotropin Feedback. Journal Of Neuroendocrinology 2001, 13: 22-28. DOI: 10.1111/j.1365-2826.2001.00602.x.Peer-Reviewed Original ResearchConceptsGnRH neuronesGnRH cellsDay 1Day 2Day 8Pg/Gonadotropin secretionArcuate nucleusOestrogen-induced LH surgeAfrican green monkeysGonadotropin feedbackInhibitory innervationEstrogen modulationOVX monkeysLH surgeSerum concentrationsExcitatory inputsInhibitory synapsesExcitatory synapsesInhibitory inputsSynaptic connectionsGnRHNeuronesGreen monkeysSynapsesOestrogen-induced changes in the synaptology of the monkey (Cercopithecus aethiops) arcuate nucleus during gonadotropin feedback.
Zsarnovszky A, Horvath T, Garcia-Segura L, Horvath B, Naftolin F. Oestrogen-induced changes in the synaptology of the monkey (Cercopithecus aethiops) arcuate nucleus during gonadotropin feedback. Journal Of Neuroendocrinology 2001, 13: 22-8. PMID: 11123512, DOI: 10.1046/j.1365-2826.2001.00602.x.Peer-Reviewed Original ResearchConceptsGnRH neuronesGnRH cellsDay 1Day 2Day 8Pg/Gonadotropin secretionOestrogen-induced LH surgeAfrican green monkeysInhibitory innervationEstrogen modulationOVX monkeysLH surgeArcuate nucleusSerum concentrationsExcitatory inputsInhibitory synapsesExcitatory synapsesInhibitory inputsSynaptic connectionsGnRHNeuronesGreen monkeysSynapsesPronounced alterations
2000
Estrogen Is Essential for Maintaining Nigrostriatal Dopamine Neurons in Primates: Implications for Parkinson's Disease and Memory
Leranth C, Roth R, Elsworth J, Naftolin F, Horvath T, Redmond D. Estrogen Is Essential for Maintaining Nigrostriatal Dopamine Neurons in Primates: Implications for Parkinson's Disease and Memory. Journal Of Neuroscience 2000, 20: 8604-8609. PMID: 11102464, PMCID: PMC6773080, DOI: 10.1523/jneurosci.20-23-08604.2000.Peer-Reviewed Original ResearchConceptsNigrostriatal dopamine neuronsDopamine neuronsParkinson's diseaseSubstantia nigraDopamine cellsTyrosine hydroxylase-expressing neuronsTyrosine hydroxylase-immunoreactive cellsNigral dopamine systemsEstrogen replacement therapyNew treatment strategiesUnbiased stereological analysisTypes of neuronsProgression of diseaseEstrogen replacementPostmenopausal womenEstrogen deprivationReplacement therapyTreatment strategiesCompact zoneGonadal hormonesLong-term effectsDopamine systemEstrogenDiseaseNeuronsMitochondrial Uncoupling Protein 2 (UCP2) in the Nonhuman Primate Brain and Pituitary*This work was supported by NSF Grant IBN-9728581, NIH Grants NS-36111, MH-59847, RR-00163, HD-29186, and HD-37186.
Diano S, Urbanski H, Horvath B, Bechmann I, Kagiya A, Nemeth G, Naftolin F, Warden C, Horvath T. Mitochondrial Uncoupling Protein 2 (UCP2) in the Nonhuman Primate Brain and Pituitary*This work was supported by NSF Grant IBN-9728581, NIH Grants NS-36111, MH-59847, RR-00163, HD-29186, and HD-37186. Endocrinology 2000, 141: 4226-4238. PMID: 11089557, DOI: 10.1210/endo.141.11.7740.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBrain ChemistryChlorocebus aethiopsCorticotropin-Releasing HormoneGene ExpressionHypothalamusImmunohistochemistryIn Situ HybridizationIon ChannelsLimbic SystemMacaca fascicularisMacaca mulattaMembrane Transport ProteinsMicroscopy, FluorescenceMitochondrial ProteinsNeuropeptide YOxytocinPituitary GlandPituitary Gland, AnteriorPituitary Gland, PosteriorProteinsRNA, MessengerUncoupling Protein 2VasopressinsConceptsUncoupling protein 2Pituitary glandAnterior lobePrimate brainAxonal processesBrain stem regionsNonhuman primate brainSitu hybridization histochemistryMessenger RNACentral autonomicRR-00163Mitochondrial uncoupling protein 2Neuropeptide YPrimate hypothalamusAnterior pituitaryMetabolic disordersRodent brainPosterior lobeHybridization histochemistryPOMC cellsCell bodiesUCP2 expressionRodent dataNovel targetBrain
1999
Hypocretin (orexin) activation and synaptic innervation of the locus coeruleus noradrenergic system
Horvath T, Peyron C, Diano S, Ivanov A, Aston‐Jones G, Kilduff T, van den Pol A. Hypocretin (orexin) activation and synaptic innervation of the locus coeruleus noradrenergic system. The Journal Of Comparative Neurology 1999, 415: 145-159. PMID: 10545156, DOI: 10.1002/(sici)1096-9861(19991213)415:2<145::aid-cne1>3.0.co;2-2.Peer-Reviewed Original ResearchMeSH KeywordsAction PotentialsAnimalsChlorocebus aethiopsFemaleHypothalamusImmunohistochemistryIntracellular Signaling Peptides and ProteinsLocus CoeruleusMacaca fascicularisMaleMicroscopy, ElectronMSH Release-Inhibiting HormoneNeuropeptidesNeurotransmitter AgentsNorepinephrineOrexinsPresynaptic TerminalsRatsRats, Sprague-DawleyTetrodotoxinTyrosine 3-MonooxygenaseConceptsLocus coeruleusSynaptic innervationNoradrenergic systemAxon terminalsTyrosine hydroxylase-immunopositive cellsAsymmetrical synaptic contactsLC-noradrenergic systemParallel electrophysiological studiesLocus coeruleus noradrenergic systemPresence of tetrodotoxinMelanin-concentrating hormoneLC neuronsAutonomic centersNoradrenergic innervationDense arborizationsExcitatory responsesHypocretin cellsSubstantia nigraSynaptic contactsHypocretin-2Lateral hypothalamusZona incertaModest depolarizationCatecholamine systemsCentral regulationSynaptic Interaction between Hypocretin (Orexin) and Neuropeptide Y Cells in the Rodent and Primate Hypothalamus: A Novel Circuit Implicated in Metabolic and Endocrine Regulations
Horvath T, Diano S, van den Pol A. Synaptic Interaction between Hypocretin (Orexin) and Neuropeptide Y Cells in the Rodent and Primate Hypothalamus: A Novel Circuit Implicated in Metabolic and Endocrine Regulations. Journal Of Neuroscience 1999, 19: 1072-1087. PMID: 9920670, PMCID: PMC6782143, DOI: 10.1523/jneurosci.19-03-01072.1999.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCarrier ProteinsChlorocebus aethiopsEndocrine GlandsFemaleHypothalamusIntracellular Signaling Peptides and ProteinsMaleMetabolismNeural PathwaysNeuronsNeuropeptide YNeuropeptidesOrexin ReceptorsOrexinsRatsRats, Sprague-DawleyReceptors, Cell SurfaceReceptors, G-Protein-CoupledReceptors, LeptinReceptors, NeuropeptideSynapsesConceptsHypothalamic functionCentral regulationHypocretin-containing neuronsLateral hypothalamic cellsLeptin receptor immunoreactivityNeuropeptide Y cellsDirect synaptic contactsNeuropeptide Y systemEndocrine regulationEndocrine processesNPY releaseReceptor immunoreactivityExcitatory actionHypocretin cellsSynaptic contactsArcuate nucleusLateral hypothalamusPrimate hypothalamusLeptin receptorSame neuronsHypothalamic cellsSynaptic regulationAdipose tissueHypocretinNPY
1996
Aromatase Immunoreactivity in Axon Terminals of the Vertebrate Brain
Naftolin F, Horvath T, Jakab R, Leranth C, Harada N, Balthazart J. Aromatase Immunoreactivity in Axon Terminals of the Vertebrate Brain. Neuroendocrinology 1996, 63: 149-155. PMID: 9053779, DOI: 10.1159/000126951.Peer-Reviewed Original ResearchConceptsAxon terminalsAromatase immunoreactivityAxonal processesDifferent vertebrate speciesAdult central nervous systemRole of aromataseSmall clear synaptic vesiclesCentral nervous systemClear synaptic vesiclesVertebrate speciesSubcellular locationMost vertebratesSpecific limbicNeuronal perikaryaAromatase activityElectron microscopic examinationEstrogen synthesisHypothalamic structuresSubcellular distributionSynaptic levelVertebrate brainNervous systemBrain aromataseMolecular biologyIntraneuronal production
1995
Distribution of Estrogen Receptor-Immunoreactive Cells in Monkey Hypothalamus: Relationship to Neurones Containing Luteinizing Hormone-Releasing Hormone and Tyrosine Hydroxylase
Herbison A, Horvath T, Naftolin F, Leranth C. Distribution of Estrogen Receptor-Immunoreactive Cells in Monkey Hypothalamus: Relationship to Neurones Containing Luteinizing Hormone-Releasing Hormone and Tyrosine Hydroxylase. Neuroendocrinology 1995, 61: 1-10. PMID: 7731492, DOI: 10.1159/000126810.Peer-Reviewed Original ResearchConceptsER-immunoreactive cellsHormone-releasing hormoneER immunoreactivityMonkey hypothalamusTyrosine hydroxylaseDouble-labeling experimentsProgesterone receptorDopaminergic neuronesLHRH neuronesEstrogen receptor-immunoreactive cellsReceptor-immunoreactive cellsPituitary hormone secretionSpecific hypothalamic nucleiTH-immunoreactive cellsPR-containing cellsDopamine-containing neuronesHypothalamic dopaminergic neuronesAfrican green monkeysLHRH neuronsPeriventricular areaSteroid statusArcuate nucleusHormone secretionHypothalamic nucleiPrimate hypothalamus
1993
Neuropeptide-Y innervation of estrogen-induced progesterone receptor-containing dopamine cells in the monkey hypothalamus: a triple labeling light and electron microscopic study
Horvath TL, Shanabrough M, Naftolin F, Leranth C. Neuropeptide-Y innervation of estrogen-induced progesterone receptor-containing dopamine cells in the monkey hypothalamus: a triple labeling light and electron microscopic study. Endocrinology 1993, 133: 405-414. PMID: 8100520, DOI: 10.1210/endo.133.1.8100520.Peer-Reviewed Original ResearchConceptsTyrosine hydroxylase-immunoreactive neuronsHydroxylase-immunoreactive neuronsProgesterone receptorSynaptic contactsAxon terminalsDopamine cellsTyrosine hydroxylase-immunopositive cellsHypophyseal hormone secretionEffects of NPYDorsomedial hypothalamic nucleusCoronal vibratome sectionsNuclear progesterone receptorPR-containing cellsAfrican green monkeysDiaminobenzidine reactionNPY axonsPeriventricular areaOVX animalsHormone secretionMonkey hypothalamusAnterior hypothalamusHypothalamic nucleiDopamine neuronsPRL releaseEstrogen
1992
Presence of calbindin and lack of parvalbumin in progesterone receptor-containing neurons of the monkey mediobasal hypothalamus
Horvath TL, Leranth C, Naftolin* F. Presence of calbindin and lack of parvalbumin in progesterone receptor-containing neurons of the monkey mediobasal hypothalamus. Neuroscience 1992, 50: 309-314. PMID: 1436493, DOI: 10.1016/0306-4522(92)90425-2.Peer-Reviewed Original ResearchConceptsProgesterone receptor-containing neuronsReceptor-containing neuronsReceptor-containing cellsCalbindin-immunoreactive neuronsProgesterone receptorAsymmetric synaptic contactsPresence of calbindinCentral nervous systemAfrican green monkeysLight microscopic resultsGABA neuronsGABAergic neuronsPeriventricular areaSynaptic contactsMonkey hypothalamusPostsynaptic targetsExcitatory fibresInfundibular nucleusMediobasal hypothalamusCalcium-binding proteinsNervous systemCalbindin cellsCalbindinNeuronsParvalbumin content