Regulation of stem cell (SC) proliferation is central to tissue homoeostasis, injury repair, and cancer development. Accumulation of replication errors in SCs is limited by either infrequent division and/or by chromosome sorting to retain preferentially the oldest 'immortal' DNA strand. The frequency of SC divisions and the chromosome-sorting phenomenon are difficult to examine accurately with existing methods. To address this question, we developed a strategy to count divisions of hair follicle (HF) SCs over time, and provide the first quantitative proliferation history of a tissue SC during its normal homoeostasis. We uncovered an unexpectedly high cellular turnover in the SC compartment in one round of activation. Our study provides quantitative data in support of the long-standing infrequent SC division model, and shows that HF SCs do not retain the older DNA strands or sort their chromosome. This new ability to count divisions in vivo has relevance for obtaining basic knowledge of tissue kinetics.
Aml1/Runx1 controls developmental aspects of several tissues, is a master regulator of blood stem cells, and plays a role in leukemia. However, it is unclear whether it functions in tissue stem cells other than blood. Here, we have investigated the role of Runx1 in mouse hair follicle stem cells by conditional ablation in epithelial cells. Runx1 disruption affects hair follicle stem cell activation, but not their maintenance, proliferation or differentiation potential. Adult mutant mice exhibit impaired de novo production of hair shafts and all temporary hair cell lineages, owing to a prolonged quiescent phase of the first hair cycle. The lag of stem cell activity is reversed by skin injury. Our work suggests a degree of functional overlap in Runx1 regulation of blood and hair follicle stem cells at an equivalent time point in the development of these two tissues.
Several experimental in vivo systems exist that generate reciprocal translocations between engineered chromosomal loci of yeast or Drosophila, but not without previous genome modifications. Here we report the successful induction of chromosome translocations in unmodified yeast cells via targeted DNA integration of the KAN(R) selectable marker flanked by sequences homologous to two chromosomal loci randomly chosen on the genome. Using this bridge-induced translocation system, 2% of the integrants showed targeted translocations between chromosomes V-VIII and VIII-XV in two wild-type Saccharomyces cerevisiae strains. All the translocation events studied were found to be non-reciprocal and the fate of their chromosomal fragments that were not included in the translocated chromosome was followed. The recovery of discrete-sized fragments suggested multiple pathway repair of their free DNA ends. We propose that centromere-distal chromosome fragments may be processed by a break-induced replication mechanism ensuing in partial trisomy. The experimental feasibility of inducing chromosomal translocations between any two desired genetic loci in a eukaryotic model system will be instrumental in elucidating the molecular mechanism underlying genome rearrangements generated by DNA integration and the gross chromosomal rearrangements characteristic of many types of cancer.
Introduction 3. Epithelial-Mesenchymal Transition: Molecular and structural changes during the process 3.1. EMT in development 3.2. Transcriptional regulation of EMT: EMT-TFs as master regulators 3.3. EMT and CTCs in cancer: A starting point for invasion and metastasis 4. EMT, cellular plasticity and metastasis: an intermediate state is the key 5. EMT and cancer stemness 5.1. Overview of cancer stem cells 5.2. Plasticity and reversibility of normal and CSC 5.3. EMT and CSCs: Two sides of the same coin 6. Regulation of EMT by cell signaling 6.1. Wnt signaling and EMT 6.2. TGF-β signaling and EMT 6.3. Notch signaling and EMT 7. Current status and therapeutic potential 8. Perspectives 9. Acknowledgments 10. References
Secretory phospholipase A 2 Group-IIA (sPLA 2 -IIA) catalyzes the hydrolysis of the sn-2 position of glycerophospholipids to yield fatty acids and lysophospholipids. sPLA 2 -IIA is deregulated in various cancers; however, its role in hair follicle stem cell (HFSC) regulation is obscure. Here we report a transgenic mice overexpressing sPLA 2 -IIA (K14-sPLA 2 -IIA) showed depletion of HFSC pool. This was accompanied with increased differentiation, loss of ortho-parakeratotic organization and enlargement of sebaceous gland, infundibulum and junctional zone. The colony forming efficiency of keratinocytes was significantly reduced. Microarray profiling of HFSCs revealed enhanced level of epithelial mitogens and transcription factors, c-Jun and FosB that may be involved in proliferation and differentiation. Moreover, K14-sPLA 2 -IIA keratinocytes showed enhanced activation of EGFR and JNK1/2 that led to c-Jun activation, which co-related with enhanced differentiation. Further, depletion of stem cells in bulge is associated with high levels of chromatin silencing mark, H3K27me3 and low levels of an activator mark, H3K9ac suggestive of alteration in gene expression contributing toward stem cells differentiation. Our results, first time uncovered that overexpression of sPLA 2 -IIA lead to depletion of HFSCs and differentiation associated with altered histone modification. Thus involvement of sPLA 2 -IIA in stem cells regulation and disease pathogenesis suggest its prospective clinical implications. STEM CELLS
In Saccharomyces cerevisiae, aneuploidy is well tolerated and stable. We analysed whether the induced loss of a disomic chromosome favours endo-reduplication of the remaining chromosome or the cells prefer to retain the acquired euploidy. Chromosome VIII disomes and trisomes were tagged with GFP (green fluorescent protein), DsRed (red fluorescent protein) and BFP (blue fluorescent protein) integrated at the thr1 locus, using our newly designed STIK (specific targeted integration of kanamycin resistance-associated, non-selectable DNA) plasmid system. A knockout cassette for centromere 8 was constructed with the hygromycin-B marker, which was transformed into the strains. The transformants lost sensitivity to hygromycin, thereby indicating the event of centromere replacement. Quantitative PCR and Southern analysis were performed for chromosome VIII copy number determination by probing the markers located on both the right (ARG4 and THR1 ) and left (GUT1 ) arm whereas, for chromosome V, markers such as HIS1, located on right arm, and URA3, on left arm, were used. The loss of an extranumerary chromosome VIII in a disome and trisome leads to stable euploidy. Furthermore, in a wild-type diploid, deletion of a copy of chromosome VIII, leads to monosomy, and restoration of euploidy after 22 generations, by reduplication of chromosome VIII, and consequent loss of heterozygosis (LOH). However, chromosome V knockouts in chromosome VIII trisome, still showed LOH and duplication of chromosome V, with return to the original aneuploid condition. These results suggest that yeast cells could control the integrity of their genetic complement acting at the individual chromosome level.
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