2022
β Cell–specific deletion of Zfp148 improves nutrient-stimulated β cell Ca2+ responses
Emfinger CH, de Klerk E, Schueler KL, Rabaglia ME, Stapleton DS, Simonett SP, Mitok KA, Wang Z, Liu X, Paulo JA, Yu Q, Cardone RL, Foster HR, Lewandowski SL, Perales JC, Kendziorski CM, Gygi SP, Kibbey RG, Keller MP, Hebrok M, Merrins MJ, Attie AD. β Cell–specific deletion of Zfp148 improves nutrient-stimulated β cell Ca2+ responses. JCI Insight 2022, 7: e154198. PMID: 35603790, PMCID: PMC9220824, DOI: 10.1172/jci.insight.154198.Peer-Reviewed Original ResearchConceptsCell-specific deletionΒ-cell Ca2Insulin secretionAmino acid metabolismLow glucose conditionsRNA-seqPancreatic β-cellsLevels of enzymesZfp148Glutamate dehydrogenaseIntermediary metabolismChannel closureEnhanced insulin secretionWestern-style dietControl mice fedElevated glucose levelsAcid metabolismΒ-cellsCell functionGlucose toleranceCell Ca2Elevated sensitivityGlucose conditionsMetabolic challengesMice fed
2020
Effect of Supplementation with Hydroethanolic Extract of Campomanesia xanthocarpa (Berg.) Leaves and Two Isolated Substances from the Extract on Metabolic Parameters of Mice Fed a High-Fat Diet
Cardozo C, Inada A, Cardoso C, de Oliveira Filiú W, de Farias B, Alves F, Tatara M, Croda J, de Cássia Avellaneda Guimarães R, Hiane P, de Cássia Freitas K. Effect of Supplementation with Hydroethanolic Extract of Campomanesia xanthocarpa (Berg.) Leaves and Two Isolated Substances from the Extract on Metabolic Parameters of Mice Fed a High-Fat Diet. Molecules 2020, 25: 2693. PMID: 32531999, PMCID: PMC7321075, DOI: 10.3390/molecules25112693.Peer-Reviewed Original ResearchConceptsHigh-fat dietInterleukin-6Diet-induced obesity modelBeneficial effectsHydroethanolic extractMale Swiss miceHydroethanolic leaf extractEffect of supplementationLipid parametersMice fedAdiposity gainFat dietSwiss miceObesity modelObesity featuresMetabolic parametersFood intakeHistological parametersMetabolic disordersBody weightNutrition dietProtein expressionDietFood behaviorFurther investigation
2019
An omega-3 Fatty Acid Enriched Diet Reduces Anxiety-like Behavior While High Dietary Sucrose During Chemotherapy Increases Anxiety-like Behavior in Mice (P14-023-19)
Ormiston K, Orchard T, DeVries A, Phuwamongkolwiwat P, Li J, Andridge R, Fitzgerald J, Tinkai T, Lustberg M. An omega-3 Fatty Acid Enriched Diet Reduces Anxiety-like Behavior While High Dietary Sucrose During Chemotherapy Increases Anxiety-like Behavior in Mice (P14-023-19). Current Developments In Nutrition 2019, 3: nzz052.p14-023-19. PMCID: PMC6573952, DOI: 10.1093/cdn/nzz052.p14-023-19.Peer-Reviewed Original ResearchAnxiety-like behaviorDocosahexaenoic acidIncreases Anxiety-Like BehaviorWeeks of dietBreast cancer patientsAssociation of cytokinesNumber of marblesOvariectomized C57BL/6 miceLess anxiety-like behaviorSignificant differencesSymptoms of anxietyChemotherapy injectionsChemotherapy groupDHA groupHealthy womenFatty acidsMice fedSaline groupC57BL/6 miceInflammatory cytokinesCancer patientsChemotherapy increasesInterleukin-6Results TwentyMouse modelShort-term Resistance Training Increases APPL1 Content in the Liver and the Insulin Sensitivity of Mice Fed a Long-term High-fat Diet
Minuzzi L, Kuga G, Breda L, Gaspar R, Muñoz V, Pereira R, Botezelli J, da Silva A, Cintra D, de Moura L, Ropelle E, Pauli J. Short-term Resistance Training Increases APPL1 Content in the Liver and the Insulin Sensitivity of Mice Fed a Long-term High-fat Diet. Experimental And Clinical Endocrinology & Diabetes 2019, 128: 30-37. PMID: 30991419, DOI: 10.1055/a-0885-9872.Peer-Reviewed Original ResearchConceptsLong-term high-fat dietShort-term resistance trainingHigh-fat dietResistance trainingInsulin sensitivityHigh calorie intakeLiver of miceAdiponectin pathwayChow dietMice fedInsulin resistanceGlycemic homeostasisSwiss miceAdiponectin receptorsPhysical activityPhysical exerciseInsulin actionHepatic tissueMiceLiverDietAdiponectinInadequate levelsAdverse consequencesCritical regulator
2018
Genetically Obese Human Gut Microbiota Induces Liver Steatosis in Germ-Free Mice Fed on Normal Diet
Wang R, Li H, Yang X, Xue X, Deng L, Shen J, Zhang M, Zhao L, Zhang C. Genetically Obese Human Gut Microbiota Induces Liver Steatosis in Germ-Free Mice Fed on Normal Diet. Frontiers In Microbiology 2018, 9: 1602. PMID: 30079055, PMCID: PMC6062601, DOI: 10.3389/fmicb.2018.01602.Peer-Reviewed Original ResearchHepatic transcriptional profilePreM groupGut microbiotaLiver steatosisNon-alcoholic fatty liver diseaseDietary weight loss programObesity-associated gut microbiotaLipid metabolismPeroxisome proliferator-activated receptor alphaProliferator-activated receptor alphaDysbiotic gut microbiotaLiver macrovesicular steatosisFatty liver diseaseNormal chow dietWeight loss programC57BL/6J male miceNormal hepatic physiologyObese human donorsLiver diseaseChow dietLoss programMice fedHuman gut microbiotaMacrovesicular steatosisMetabolic deterioration
2016
A diet-induced animal model of non-alcoholic fatty liver disease and hepatocellular cancer
Asgharpour A, Cazanave SC, Pacana T, Seneshaw M, Vincent R, Banini BA, Kumar DP, Daita K, Min HK, Mirshahi F, Bedossa P, Sun X, Hoshida Y, Koduru SV, Contaifer D, Warncke UO, Wijesinghe DS, Sanyal AJ. A diet-induced animal model of non-alcoholic fatty liver disease and hepatocellular cancer. Journal Of Hepatology 2016, 65: 579-588. PMID: 27261415, PMCID: PMC5012902, DOI: 10.1016/j.jhep.2016.05.005.Peer-Reviewed Original ResearchConceptsNon-alcoholic steatohepatitisNon-alcoholic fatty liver diseaseDiet-induced animal modelsProgressive non-alcoholic steatohepatitisHuman non-alcoholic steatohepatitisFatty liver diseaseHepatocellular cancerLiver diseaseAnimal modelsDiet-induced mouse modelGene signatureHigh-fat dietSimilar histological phenotypesAd libitum consumptionProgressive fibrosisLDL cholesterolChow dietMice fedInsulin resistanceFat dietClinical endpointsHuman NAFLDObesogenic dietPreclinical modelsMouse model
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