Cell kinetic studies fail to identify sequentially proliferating progenitors as the major source of epithelial renewal in the adult murine prostate

There is evidence that stem cells and their progeny play a role in the development of the prostate. Although stem cells are also considered to give rise to differentiated progeny in the adult prostate epithelium ex vivo, the cohort of adult prostate stem cells in vivo as well as the mechanisms by wh...

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Veröffentlicht in:	PloS one 2015-05, Vol.10 (5), p.e0128489-e0128489
Hauptverfasser:	Pignon, Jean-Christophe, Grisanzio, Chiara, Carvo, Ingrid, Werner, Lillian, Regan, Meredith, Wilson, E Lynette, Signoretti, Sabina
Format:	Artikel
Sprache:	eng
Schlagworte:	Androgens Animals Biology Cell division Cell Proliferation - physiology Epithelial cells Epithelium Epithelium - metabolism Homeostasis Laboratory animals Male Medical schools Mice Mutation Pathology Progenitor cells Progeny Prostate Prostate - cytology Prostate - metabolism Prostate cancer Regeneration Replication Rodents Stem cell transplantation Stem cells Stem Cells - cytology Stem Cells - metabolism Stochastic models Stochastic processes Stochasticity Studies Thymidine
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creator	Pignon, Jean-Christophe Grisanzio, Chiara Carvo, Ingrid Werner, Lillian Regan, Meredith Wilson, E Lynette Signoretti, Sabina
description	There is evidence that stem cells and their progeny play a role in the development of the prostate. Although stem cells are also considered to give rise to differentiated progeny in the adult prostate epithelium ex vivo, the cohort of adult prostate stem cells in vivo as well as the mechanisms by which the adult prostate epithelium is maintained and regenerated remain highly controversial. We have attempted to resolve this conundrum by performing in vivo tracing of serially replicating cells after the sequential administration of two thymidine analogues to mice. Our results show that, during normal prostate homeostasis, sequentially proliferating cells are detected at a rate that is consistent with a stochastic process. These findings indicate that in vivo, under steady-state conditions, most adult prostate epithelial cells do not represent the progeny of a small number of specialized progenitors that generate sequentially replicating transit-amplifying (TA) cells but are formed by stochastic cell division. Similarly, no rapidly cycling TA cells were detected during regeneration following one cycle of androgen-mediated involution/regeneration of the prostate epithelium. These findings greatly enhance our understanding of the mechanisms regulating prostate epithelial cell renewal and may have significant implications in defining the cell of origin of proliferative prostatic diseases.
doi_str_mv	10.1371/journal.pone.0128489
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subjects	Androgens Animals Biology Cell division Cell Proliferation - physiology Epithelial cells Epithelium Epithelium - metabolism Homeostasis Laboratory animals Male Medical schools Mice Mutation Pathology Progenitor cells Progeny Prostate Prostate - cytology Prostate - metabolism Prostate cancer Regeneration Replication Rodents Stem cell transplantation Stem cells Stem Cells - cytology Stem Cells - metabolism Stochastic models Stochastic processes Stochasticity Studies Thymidine
title	Cell kinetic studies fail to identify sequentially proliferating progenitors as the major source of epithelial renewal in the adult murine prostate
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