2019
Transgenic mouse model for conditional expression of influenza hemagglutinin-tagged human SLC20A1/PIT1
Chande S, Ho B, Fetene J, Bergwitz C. Transgenic mouse model for conditional expression of influenza hemagglutinin-tagged human SLC20A1/PIT1. PLOS ONE 2019, 14: e0223052. PMID: 31613887, PMCID: PMC6793878, DOI: 10.1371/journal.pone.0223052.Peer-Reviewed Original ResearchMeSH KeywordsActinsAnimalsBeta-GlobinsBiological TransportBone DensityCalcitriolChickensCytomegalovirusFemaleFibroblast Growth Factor-23Fibroblast Growth FactorsFounder EffectHemagglutinin Glycoproteins, Influenza VirusHumansMaleMiceMice, TransgenicOsteoblastsParathyroid HormonePhosphatesPrimary Cell CulturePromoter Regions, GeneticRabbitsRecombinant Fusion ProteinsSkullTranscription Factor Pit-1TransgenesConceptsPrimary calvaria osteoblastsLoxP-stop-loxPLoxP-STOP-loxP cassetteMouse modelDihydroxy vitamin D levelsHemagglutinin (HABone mineral densityVitamin D levelsInfluenza hemagglutinin (HAConditional mouse modelActivation of transgene expressionElevated plasma PiTransgenic mouse modelPlasma iPTHUrine PiBeta-globin geneSerum calciumWT littermatesMineral densityDays of ageProtein excretionD levelsSemi-quantitative RT-PCRStandard chowTransgenic mice
2012
Fanconi-Bickel Syndrome and Autosomal Recessive Proximal Tubulopathy with Hypercalciuria (ARPTH) Are Allelic Variants Caused by GLUT2 Mutations
Mannstadt M, Magen D, Segawa H, Stanley T, Sharma A, Sasaki S, Bergwitz C, Mounien L, Boepple P, Thorens B, Zelikovic I, Jüppner H. Fanconi-Bickel Syndrome and Autosomal Recessive Proximal Tubulopathy with Hypercalciuria (ARPTH) Are Allelic Variants Caused by GLUT2 Mutations. The Journal Of Clinical Endocrinology & Metabolism 2012, 97: e1978-e1986. PMID: 22865906, PMCID: PMC3462928, DOI: 10.1210/jc.2012-1279.Peer-Reviewed Original ResearchMeSH KeywordsAdolescentAmino Acid SequenceAnimalsFamilial Hypophosphatemic RicketsFamily HealthFanconi SyndromeFemaleGenes, RecessiveGenetic VariationGenome-Wide Association StudyGlucose Transporter Type 1Glucose Transporter Type 2HumansHypercalciuriaHypophosphatemia, FamilialKidney Tubules, ProximalMaleMiceMice, TransgenicMolecular Sequence DataOocytesPedigreeRicketsSodium-Phosphate Cotransporter Proteins, Type IIaSodium-Phosphate Cotransporter Proteins, Type IIcXenopus laevisConceptsGlucose transporter 2Sequence analysis of candidate genesCandidate genesSequence analysisGenome-wide linkage scanAnalysis of candidate genesFanconi-Bickel syndromeProximal renal tubulopathyRenal tubulopathyNucleotide sequence analysisGenetic mappingHomozygous mutationPhosphate importLinkage scanMolecular basisXenopus oocytesTransport of glucoseGLUT2 mutationsMolecular levelGenesGlucose transportUrinary phosphate excretionAllelic variantsPhosphate homeostasisDirect nucleotide sequence analysis
2008
Cellular Mechanism of Decreased Bone in Brtl Mouse Model of OI: Imbalance of Decreased Osteoblast Function and Increased Osteoclasts and Their Precursors*
Uveges TE, Collin‐Osdoby P, Cabral WA, Ledgard F, Goldberg L, Bergwitz C, Forlino A, Osdoby P, Gronowicz GA, Marini JC. Cellular Mechanism of Decreased Bone in Brtl Mouse Model of OI: Imbalance of Decreased Osteoblast Function and Increased Osteoclasts and Their Precursors*. Journal Of Bone And Mineral Research 2008, 23: 1983-1994. PMID: 18684089, PMCID: PMC2686922, DOI: 10.1359/jbmr.080804.Peer-Reviewed Original ResearchConceptsColony-forming unitsRANKL/OPG ratioOsteogenesis imperfectaWildtype valuesCompared to wildtype miceSevere osteogenesis imperfectaReal-time RT-PCRMouse model of OIIncreases osteoclast precursorsBone-resorbing osteoclastsOI therapyKnock-in modelIncreased osteoclastsOsteoclast increaseMarrow culturesWildtype miceModel of OITRACP stainingOsteoblast functionOsteoclast precursorsCellular mechanismsBrtl miceOsteoclastsRT-PCRTRACP(+
2004
Brittle IV Mouse Model for Osteogenesis Imperfecta IV Demonstrates Postpubertal Adaptations to Improve Whole Bone Strength*
Kozloff KM, Carden A, Bergwitz C, Forlino A, Uveges TE, Morris MD, Marini JC, Goldstein SA. Brittle IV Mouse Model for Osteogenesis Imperfecta IV Demonstrates Postpubertal Adaptations to Improve Whole Bone Strength*. Journal Of Bone And Mineral Research 2004, 19: 614-622. PMID: 15005849, DOI: 10.1359/jbmr.040111.Peer-Reviewed Original ResearchMeSH KeywordsAdaptation, PhysiologicalAgingAmino Acid SubstitutionAnatomy, Cross-SectionalAnimalsBone DensityBone DevelopmentBone MatrixCollagen Type IDisease Models, AnimalFemurMaleMiceMice, TransgenicMineralsOsteogenesis ImperfectaRadiographySpectrum Analysis, RamanStress, MechanicalTensile StrengthConceptsMatrix material propertiesWhole bone geometryMaterial propertiesWhole bone strengthOsteogenesis imperfectaMouse modelBone geometryBone strengthMatrix compositesMechanical testsStiffness increaseType IV osteogenesis imperfectaMicroCT dataInvestigate therapeutic interventionsGeometric parametersMechanism independent of changesMouse model of OIRaman spectroscopic resultsMonths of ageMechanically tested to failureKnock-in modelOI patientsRaman spectroscopyGeometric resistanceIndependent of changes