The Rb/E2F axis is a key regulator of the molecular signatures instructing the quiescent and activated adult neural stem cell state

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dc.contributor.authorFong, Bensun C.
dc.contributor.authorChakroun, Imane
dc.contributor.authorIqbal, Mohamed Ariff
dc.contributor.authorPaul, Smitha
dc.contributor.authorBastasic, Joseph
dc.contributor.authorO'Neil, Daniel
dc.contributor.authorYakubovich, Edward
dc.contributor.authorBejjani, Anthony T.
dc.contributor.authorAhmadi, Nastaran
dc.contributor.authorCarter, Anthony
dc.contributor.authorClark, Alysen
dc.contributor.authorLeone, Gustavo W.
dc.contributor.authorPark, David S.
dc.contributor.authorGhanem, Noël
dc.contributor.authorVandenbosch, Renaud
dc.contributor.authorSlack, Ruth S.
dc.contributor.departmentDepartment of Biology
dc.contributor.facultyFaculty of Arts and Sciences (FAS)
dc.contributor.institutionAmerican University of Beirut
dc.date.accessioned2025-01-24T11:21:12Z
dc.date.available2025-01-24T11:21:12Z
dc.date.issued2022
dc.description.abstractLong-term maintenance of the adult neurogenic niche depends on proper regulation of entry and exit from quiescence. Neural stem cell (NSC) transition from quiescence to activation is a complex process requiring precise cell-cycle control coordinated with transcriptional and morphological changes. How NSC fate transitions in coordination with the cell-cycle machinery remains poorly understood. Here we show that the Rb/E2F axis functions by linking the cell-cycle machinery to pivotal regulators of NSC fate. Deletion of Rb family proteins results in activation of NSCs, inducing a transcriptomic transition toward activation. Deletion of their target activator E2Fs1/3 results in intractable quiescence and cessation of neurogenesis. We show that the Rb/E2F axis mediates these fate transitions through regulation of factors essential for NSC function, including REST and ASCL1. Thus, the Rb/E2F axis is an important regulator of NSC fate, coordinating cell-cycle control with NSC activation and quiescence fate transitions. © 2022 The Authors
dc.identifier.doihttps://doi.org/10.1016/j.celrep.2022.111578
dc.identifier.eid2-s2.0-85140871739
dc.identifier.pmid36323247
dc.identifier.urihttp://hdl.handle.net/10938/25229
dc.language.isoen
dc.publisherElsevier B.V.
dc.relation.ispartofCell Reports
dc.sourceScopus
dc.subjectActivation
dc.subjectAdult neurogenesis
dc.subjectCell fate
dc.subjectCp: neuroscience
dc.subjectCp: stem cell research
dc.subjectMolecular signature
dc.subjectNeural precursors
dc.subjectNeural stem cells
dc.subjectQuiescence
dc.subjectRb/e2f pathway
dc.subjectStem cell maintenance
dc.subjectTranscriptional regulation
dc.subjectAdult stem cells
dc.subjectCell cycle
dc.subjectCell division
dc.subjectNeurogenesis
dc.subjectRetinoblastoma protein
dc.subjectDoublecortin like kinase
dc.subjectKi 67 antigen
dc.subjectTranscription factor e2f1
dc.subjectTranscription factor mash1
dc.subjectTranscription factor sox2
dc.subjectA-549 cell line
dc.subjectAdult
dc.subjectAnimal cell
dc.subjectAnimal experiment
dc.subjectAnimal model
dc.subjectAnimal tissue
dc.subjectArticle
dc.subjectBioinformatics
dc.subjectCell cycle regulation
dc.subjectCell differentiation
dc.subjectCell proliferation
dc.subjectChromatin immunoprecipitation
dc.subjectControlled study
dc.subjectDifferential gene expression
dc.subjectDown regulation
dc.subjectExpression vector
dc.subjectFlow cytometry
dc.subjectFluorescence activated cell sorting
dc.subjectGene expression
dc.subjectGene mutation
dc.subjectHct 116 cell line
dc.subjectHek293 cell line
dc.subjectHek293t cell line
dc.subjectHela s3 cell line
dc.subjectHep-g2 cell line
dc.subjectHigh throughput sequencing
dc.subjectHl-60 cell line
dc.subjectHuman
dc.subjectHuman cell
dc.subjectImmunohistochemistry
dc.subjectImmunoprecipitation
dc.subjectK-562 cell line
dc.subjectMcf-7 cell line
dc.subjectMouse
dc.subjectNerve cell differentiation
dc.subjectNervous system development
dc.subjectNeural stem cell
dc.subjectNonhuman
dc.subjectPanc-1 cell line
dc.subjectPolyacrylamide gel electrophoresis
dc.subjectProtein expression
dc.subjectReal time polymerase chain reaction
dc.subjectRna isolation
dc.subjectSk-n-sh cell line
dc.subjectTissue perfusion
dc.subjectTranscriptomics
dc.subjectUpregulation
dc.subjectWestern blotting
dc.subjectAdult stem cell
dc.subjectGenetics
dc.subjectMetabolism
dc.subjectPhysiology
dc.titleThe Rb/E2F axis is a key regulator of the molecular signatures instructing the quiescent and activated adult neural stem cell state
dc.typeArticle

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