Project description:Homeostatic hematopoietice stem cells (HSCs) with greater divisional history lose repopulating potential after very few cell divisions. Divisional history overrides both phenotype and immediate quiescence in determining functional activity. In GFP label retaining system GFP is progressively diluted when cells proceed through a cascade of divisions. We used a GFP label retaining system and performed microarray expression analyses to track the changes in the gene expression profile of bone marrow (BM) LSK cells that relates to divisional history during homeostasis.
Project description:We identified slow-cycling cells (SCCs) in Ewing sarcoma using a label retention assay with CFSE. We labeled cells of SK-ES-1, an Ewing sarcoma cell line, with CFSE. After 5 days culture, we isolated cells retaining strong fluorescence (upper, ~10%) as SCCs and other cells (lower, ~90%) as non-slow-cycling cells (non-SCCs) using FACS AriaTM Ⅲ cell sorter.
Project description:Label retaining and non-retaining muscle stem cells from young and aged H2B-GFP+/-;rtTA+/- were profiled by single cell RNA-seq at two timepoints
Project description:Transcriptional profiling of mouse kidney papilla cells comparing control GFP- cells with GFP+ labeled cells. Mouse kidney papillae were dissected. GFP- and GFP+ cell populations were isolated by FACS. The latter represent slow cycling label retaining cells (LRCs).
Project description:This study was performed to compare transcriptomic changes in the heterogeneous mouse skin epidermal stem cells and hair follicle stem cells (HFSC) populations during chronological aging. Slow-cycling stem cells (label retaining cells, LRCs), fast-cycling stem cells (non-label retaining cells, nLRCs) and hair follicle stem cells express unique gene signatures in young age (2 months old) and have independent stem cell identities. The changes in aging stem cells lineage identities have been a topic of discussion and here we examined if distinct stem cells cycling speed affects their aging process by comparing the transcriptomes of slow-and fast-cycling epidermal stem cells. Our data indicates the loss of unique stem cell identities in aging slow or fast-cycling epidermal stem cells or HFSC at 2 years of age with intermediary effects seen at 1.5 year old.