Jean-Pierre Lévesque1, Ingrid G Winkler. 1. Biological Therapies Program, Mater Medical Research Institute, South Brisbane, Australia. jplevesque@mmri.mater.org.au
Abstract
PURPOSE OF REVIEW: Steady-state hematopoiesis in adult bone marrow requires the maintenance of a small pool of hematopoietic stem cells (HSCs) by self-renewing symmetric division. HSCs can be divided into potent rarely dividing HSCs which function as long-term reserve and more proliferative HSCs which contribute to maintaining the blood and immune cell pool. Extrinsic instructions provided by unique microenvironments (niches) regulate the fate of individual HSCs and progenitors. This review discusses the latest findings in respect to the organization and function of these niches. RECENT FINDINGS: It has recently emerged that mesenchymal stem cells, various osteoblastic progenitors and sinusoidal endothelial cells all critically regulate HSCs within niches. Each of these niche cells expresses different arrays of signaling proteins which differentially regulate HSCs and progenitors. HSCs have been reported in two types of niches. However, as osteoblastic/mesenchymal niches and perivascular niches overlap anatomically, this makes the dichotomy between osteoblastic niches for quiescent HSCs and endothelial niches for more proliferative HSCs a too simplistic model. Indeed local blood perfusion in a niche alone can functionally separate HSC populations. SUMMARY: The fate of each individual HSC is likely to be the result of the unique balance between signals elicited by proteins expressed by mesenchymal/osteoblastic progenitors, sinusoidal endothelial cells and physicochemical cues such as local blood perfusion and hypoxia in each individual niche. More sophisticated three-dimensional fluorescence microscopy techniques on whole mount bone fragments should provide new insights in the spatial organization of niches relative to bone and microcirculation in the bone marrow.
PURPOSE OF REVIEW: Steady-state hematopoiesis in adult bone marrow requires the maintenance of a small pool of hematopoietic stem cells (HSCs) by self-renewing symmetric division. HSCs can be divided into potent rarely dividing HSCs which function as long-term reserve and more proliferative HSCs which contribute to maintaining the blood and immune cell pool. Extrinsic instructions provided by unique microenvironments (niches) regulate the fate of individual HSCs and progenitors. This review discusses the latest findings in respect to the organization and function of these niches. RECENT FINDINGS: It has recently emerged that mesenchymal stem cells, various osteoblastic progenitors and sinusoidal endothelial cells all critically regulate HSCs within niches. Each of these niche cells expresses different arrays of signaling proteins which differentially regulate HSCs and progenitors. HSCs have been reported in two types of niches. However, as osteoblastic/mesenchymal niches and perivascular niches overlap anatomically, this makes the dichotomy between osteoblastic niches for quiescent HSCs and endothelial niches for more proliferative HSCs a too simplistic model. Indeed local blood perfusion in a niche alone can functionally separate HSC populations. SUMMARY: The fate of each individual HSC is likely to be the result of the unique balance between signals elicited by proteins expressed by mesenchymal/osteoblastic progenitors, sinusoidal endothelial cells and physicochemical cues such as local blood perfusion and hypoxia in each individual niche. More sophisticated three-dimensional fluorescence microscopy techniques on whole mount bone fragments should provide new insights in the spatial organization of niches relative to bone and microcirculation in the bone marrow.
Authors: Tata Nageswara Rao; Jonathan Marks-Bluth; Jessica Sullivan; Manoj K Gupta; Vashe Chandrakanthan; Simon R Fitch; Katrin Ottersbach; Young C Jang; Xianhua Piao; Rohit N Kulkarni; Thomas Serwold; John E Pimanda; Amy J Wagers Journal: Stem Cell Res Date: 2015-02-18 Impact factor: 2.020
Authors: E Del Poggetto; M Tanturli; N Ben-Califa; A Gozzini; I Tusa; G Cheloni; I Marzi; M G Cipolleschi; Y Kashman; D Neumann; E Rovida; P Dello Sbarba Journal: Cell Cycle Date: 2015 Impact factor: 4.534
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