Hematopoietic cells of various lineages are organized in distinct cellular architectures in the bone marrow hematopoietic compartment (BMHC). The homogeneous Kroghian model, which deals only with a single cell type, may not be sufficient to accurately describe oxygen transfer in the BMHC. Thus, for cellular architectures of physiological significance, more complex biophysical-transport models were considered and compared against simulations using the homogeneous Kroghian model. The effects of the heterogeneity of model parameters on the oxygen tension (pO(2)) distribution were examined using the multilayer Kroghian model. We have also developed two-dimensional Kroghian models to simulate several cellular architectures in which a cell cluster (erythroid cluster) or an individual cell (megakaryocyte or adipocyte) is located in the BMHC predominantly occupied by mature granulocytes. pO(2) distributions in colony-type cellular arrangements (erythroblastic islets, granulopoietic loci, and lymphocytic nodules) in the BMHC were also evaluated by modifying the multilayer Kroghian model. The simulated results indicate that most hematopoietic progenitors experience low pO(2) values, which agrees with the finding that low pO(2) promotes the expansion of various hematopoietic progenitors. These results suggest that the most primitive stem cells, which are located even further away from BM sinuses, are likely located in a very low pO(2) environment.
Human bone marrow (BM) is a tissue of complex architectural organization, which includes granulopoietic loci, erythroblastic islets, and lymphocytic nodules. Oxygen tension (pO(2)) is an important determinant of hematopoietic stem and progenitor cell proliferation and differentiation. Thus, understanding the impact of the BM architectural organization on pO(2) levels in extravascular hematopoietic tissue is an important biophysical problem. However, currently it is impossible to measure pO(2) levels and their spatial variations in the BM. Homogeneous Kroghian models were used to estimate pO(2) distribution in the BM hematopoietic compartment (BMHC) and to conservatively simulate pO(2)-limited cellular architectures. Based on biophysical data of hematopoietic cells and characteristics of BM physiology, we constructed a tissue cylinder solely occupied by granulocytic progenitors (the most metabolically active stage of the most abundant cell type) to provide a physiologically relevant limiting case. Although the number of possible cellular architectures is large, all simulated pO(2) profiles fall between two extreme cases: those of homogeneous tissues with adipocytes and granulocytic progenitors, respectively. This was illustrated by results obtained from a parametric criterion derived for pO(2) depletion in the extravascular tissue. Modeling results suggest that stem and progenitor cells experience a low pO(2) environment in the BMHC.
• Physiological shear stress promotes megakaryocytic maturation, DNA synthesis, phosphatidylserine exposure and caspase-3 activation.• Shear enhances the production and function of PLPs and Mk-derived microparticles possessing a novel function.In vivo visualization of thrombopoiesis suggests an important role for shear flow in platelet biogenesis. In vitro, shear stress was shown to accelerate proplatelet formation from mature megakaryocytes (Mks). Yet, the role of biomechanical forces on Mk biology and platelet biogenesis remains largely unexplored. In this study, we investigated the impact of shear stress on Mk maturation and formation of platelet-like particles (PLPs), pro/preplatelets (PPTs), and Mk microparticles (MkMPs), and furthermore, we explored a physiological role for MkMPs. We found that shear accelerated DNA synthesis of immature Mks in an exposure time-and shear stress level-dependent manner. Both phosphatidylserine exposure and caspase-3 activation were enhanced by shear stress. Exposure to physiological shear dramatically increased generation of PLPs/PPTs and MkMPs by up to 10.8 and 47-fold, respectively. Caspase-3 inhibition reduced shear-induced PLP/PPT and MkMP formation. PLPs generated under shear flow displayed improved functionality as assessed by CD62P exposure and fibrinogen binding. Significantly, coculture of MkMPs with hematopoietic stem and progenitor cells promoted hematopoietic stem and progenitor cell differentiation to mature Mks synthesizing a-and dense-granules, and forming PPTs without exogenous thrombopoietin, thus identifying a novel and unexplored potential physiological role for MkMPs. (Blood. 2014;124(13):2094-2103
A gene (aad) coding for an aldehyde/alcohol dehydrogenase (AAD) was identified immediately upstream of the previously cloned ctfA (J. W. Cary, D. J. Petersen, E. T. Papoutsakis, and G. N. Bennett, Appl. Environ. Microbiol. 56:1576-1583
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