2021
Distinct roles of KLF4 in mesenchymal cell subtypes during lung fibrogenesis
Chandran RR, Xie Y, Gallardo-Vara E, Adams T, Garcia-Milian R, Kabir I, Sheikh AQ, Kaminski N, Martin KA, Herzog EL, Greif DM. Distinct roles of KLF4 in mesenchymal cell subtypes during lung fibrogenesis. Nature Communications 2021, 12: 7179. PMID: 34893592, PMCID: PMC8664937, DOI: 10.1038/s41467-021-27499-8.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCell ProliferationDisease Models, AnimalDown-RegulationExtracellular MatrixFemaleFibroblastsFibrosisHumansKruppel-Like Factor 4LungLung InjuryMaleMesenchymal Stem CellsMiceMice, Inbred C57BLMyofibroblastsReceptor, Platelet-Derived Growth Factor betaRespiratory Tract DiseasesSignal TransductionTransforming Growth Factor betaConceptsMesenchymal cell typesPlatelet-derived growth factor receptorSmooth muscle actinLung fibrosisKruppel-like factor 4Forkhead box M1Growth factor receptorCell transitionCell typesExtracellular matrixDistinct rolesKLF4Box M1C chemokine ligandMesenchymal cell subtypesFactor receptorPro-fibrotic effectsFactor 4PDGFRMesenchymeCellsMacrophage accumulationKLF4 levelsChemokine ligandLung fibrogenesis
2012
Radial Construction of an Arterial Wall
Greif DM, Kumar M, Lighthouse JK, Hum J, An A, Ding L, Red-Horse K, Espinoza FH, Olson L, Offermanns S, Krasnow MA. Radial Construction of an Arterial Wall. Developmental Cell 2012, 23: 482-493. PMID: 22975322, PMCID: PMC3500096, DOI: 10.1016/j.devcel.2012.07.009.Peer-Reviewed Original ResearchConceptsInner layer cellsCoordinated processGenetic analysisSuccessive cell layersVessel-specific differencesSignaling pathwaysCell reorientationSequential inductionEndothelial tubesSignal gradientMuscle cellsSignal contributesSerious diseaseCellsCell layerLayer cellsRadial migrationMesenchymeConcentric layersPathwayArterial wallPDGFInvasionInductionArtery wallLive imaging of stem cell and progeny behaviour in physiological hair-follicle regeneration
Rompolas P, Deschene ER, Zito G, Gonzalez DG, Saotome I, Haberman AM, Greco V. Live imaging of stem cell and progeny behaviour in physiological hair-follicle regeneration. Nature 2012, 487: 496-499. PMID: 22763436, PMCID: PMC3772651, DOI: 10.1038/nature11218.Peer-Reviewed Original Research
2009
Analysis of gene expression in PTHrP−/− mammary buds supports a role for BMP signaling and MMP2 in the initiation of ductal morphogenesis
Hens J, Dann P, Hiremath M, Pan T, Chodosh L, Wysolmerski J. Analysis of gene expression in PTHrP−/− mammary buds supports a role for BMP signaling and MMP2 in the initiation of ductal morphogenesis. Developmental Dynamics 2009, 238: 2713-2724. PMID: 19795511, PMCID: PMC2862621, DOI: 10.1002/dvdy.22097.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBone Morphogenetic Protein 4Cells, CulturedDipeptidesDown-RegulationGene Expression Regulation, DevelopmentalHydroxamic AcidsIntercellular Signaling Peptides and ProteinsKeratinsMammary Glands, AnimalMatrix Metalloproteinase 2Matrix Metalloproteinase InhibitorsMesodermMiceMice, KnockoutMorphogenesisOligonucleotide Array Sequence AnalysisParathyroid Hormone-Related ProteinProtease InhibitorsSignal TransductionTranscription FactorsUp-RegulationConceptsGene expressionMammary budMammary mesenchymeDuctal outgrowthMesenchymal cellsEmbryonic mammary developmentMMP2 gene expressionEmbryonic mammary budFunctional roleGenesDuctal morphogenesisBud culturesMammary developmentBudsPTHrP effectsBMPMesenchymeExpressionMMP2 activityMMP2OutgrowthVentral skinCellsMorphogenesisBMP4Chapter 23 An Overview of Renal Development
Marlier A, Cantley L. Chapter 23 An Overview of Renal Development. 2009, 365-392. DOI: 10.1016/b978-0-12-449851-8.00023-1.Peer-Reviewed Original ResearchMetanephric mesenchymeNephric ductUreteric budCell deathBcl-2Anti-apoptotic proteinsRegulated processDifferentiation signalsUB tipsSix2 expressionUninduced mesenchymeMetanephric kidneyRenal vesiclesMesenchymeRenal developmentBudsNearby cellsUbProteinExpressionApoptosisLow expressionCellsOutgrowthInitial outgrowth
2007
Lateral motor column axons execute a ternary trajectory choice between limb and body tissues
Luria V, Laufer E. Lateral motor column axons execute a ternary trajectory choice between limb and body tissues. Neural Development 2007, 2: 13. PMID: 17605791, PMCID: PMC1949814, DOI: 10.1186/1749-8104-2-13.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAxonsBody PatterningBone Morphogenetic Protein Receptors, Type ICell DifferentiationEphrinsExtremitiesGene Expression Regulation, DevelopmentalGrowth ConesHomeodomain ProteinsKruppel-Like Transcription FactorsLIM-Homeodomain ProteinsMesodermMiceMice, KnockoutMotor NeuronsMuscle, SkeletalNeuronal PlasticityPromyelocytic Leukemia Zinc Finger ProteinReceptors, Eph FamilySpinal CordTranscription FactorsConceptsLateral motor columnLMC axonsHindlimb levelsSpinal cord lateral motor columnMotor columnAxons of neuronsIntermediate choice pointsVentral flankBody tissuesMotor nervesLMC neuronsAxonal trajectoriesLimb trajectoriesAxonsTopographic map formationTarget tissuesLimbTissueTranscription factor codeVentral limbNeuronsMap formationMesenchymeInnervationNerve
2005
Key stages of mammary gland development: Molecular mechanisms involved in the formation of the embryonic mammary gland
Hens JR, Wysolmerski JJ. Key stages of mammary gland development: Molecular mechanisms involved in the formation of the embryonic mammary gland. Breast Cancer Research 2005, 7: 220. PMID: 16168142, PMCID: PMC1242158, DOI: 10.1186/bcr1306.Peer-Reviewed Reviews, Practice Guidelines, Standards, and Consensus StatementsConceptsMammary gland developmentEmbryonic mammary glandGland developmentMolecular mechanismsEmbryonic mammary gland developmentMammary glandProtein signalingMore genesFibroblast growth factorSignaling pathwaysFunctional roleGrowth factorWntGenesKey stagesSignalingMesenchymePathwayMechanismGlandEpidermisDevelopment
1997
Neuronal and Non-Neuronal Collapsin-1 Binding Sites in Developing Chick Are Distinct from Other Semaphorin Binding Sites
Takahashi T, Nakamura F, Strittmatter S. Neuronal and Non-Neuronal Collapsin-1 Binding Sites in Developing Chick Are Distinct from Other Semaphorin Binding Sites. Journal Of Neuroscience 1997, 17: 9183-9193. PMID: 9364065, PMCID: PMC6573609, DOI: 10.1523/jneurosci.17-23-09183.1997.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAvian ProteinsAxonsBinding SitesCells, CulturedCentral Nervous SystemChick EmbryoDNA, ComplementaryFetal ProteinsGanglia, SpinalGlycoproteinsLungMembrane ProteinsMesodermMiceMotor NeuronsMultigene FamilyNerve Growth FactorsNerve Tissue ProteinsNeuronsNeurotrophin 3Organ SpecificityRatsRats, Sprague-DawleyReceptors, Cell SurfaceRecombinant Fusion ProteinsSemaphorin-3AConceptsFusion proteinBinding sitesGrowth conesDRG neuronsNon-neuronal tissuesExtracellular proteinsF fusion proteinSemaphorin familyDRG growth conesProteinLow nanomolar affinityMajor blood vesselsLigand familyBrainstem neuronsSympathetic neuronsNanomolar affinityNervous systemAxonal pathsBiological activityBlood vesselsNeuronsFamilySitesMesenchymeSemaphorins
1967
Rhabdite formation in planaria: The role of microtubules
Lentz T. Rhabdite formation in planaria: The role of microtubules. Journal Of Ultrastructure Research 1967, 17: 114-126. PMID: 6017351, DOI: 10.1016/s0022-5320(67)80024-8.Peer-Reviewed Original ResearchConceptsGolgi apparatusRole of microtubulesCytoplasmic ribosomesCellular organellesGolgi vesiclesEndoplasmic reticulumGland cellsMicrotubulesMigration of vesiclesCells migrateEpidermal surfaceNeoblastsRough-surfaced endoplasmic reticulumGolgi sacculesVacuolesVesiclesPlanariaSecretory materialOpaque granulesRhabditesRibosomesOrganellesMesenchyme
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