Abstract
Growing evidence supports the role of erythroblastic islands (EI) as microenvironmental niches within bone marrow (BM), where cell-cell attachments are suggested as crucial for erythroid maturation. The inducible form of the enzyme heme oxygenase, HO-1, which conducts heme degradation, is absent in erythroblasts where hemoglobin (Hb) is synthesized. Yet, the central macrophage, which retains high HO-1 activity, might be suitable to take over degradation of extra, harmful, Hb heme. Of these enzymatic products, only the hydrophobic gas molecule - CO can transfer from the macrophage to surrounding erythroblasts directly via their tightly attached membranes in the terminal differentiation stage.Based on the above, the study hypothesized CO to have a role in erythroid maturation. Thus, the effect of CO gas as a potential erythroid differentiation inducer on the common model for erythroid progenitors, K562 cells, was explored. Cells were kept under oxygen lacking environment to mimic BM conditions. Nitrogen anaerobic atmosphere (N2A) served as control for CO atmosphere (COA). Under both atmospheres cells proliferation ceased: in N2A due to cell death, while in COA as a result of erythroid differentiation. Maturation was evaluated by increased glycophorin A expression and Hb concentration. Addition of 1%CO only to N2A, was adequate for maintaining cell viability. Yet, the average Hb concentration was low as compared to COA. This was validated to be the outcome of diversified maturation stages of the progenitor's population.In fact, the above scenario mimics the in vivo EI conditions, where at any given moment only a minute portion of the progenitors proceeds into terminal differentiation. Hence, this model might provide a basis for further molecular investigations of the EI structure/function relationship.
Highlights
Reticulocytes are formed in specific bone marrow (BM) niches, known as erythroblastic islands (EI)
EI are composed of a central macrophage surrounded by erythroblasts in different stages of maturation [1,2,3] and the early presence of these unique structures in fetal liver supports their essential role in erythropoiesis [4,5]
This study explored whether carbon monoxide (CO) gas can affect maturation of erythroid progenitors under physiologically relevant conditions prevailing in the BM using K562 cells as a model [17]
Summary
Reticulocytes are formed in specific bone marrow (BM) niches, known as erythroblastic islands (EI). At the terminal differentiation stage, the expelled erythroblast nucleus sweeps hemoglobin (Hb) residues into the macrophage upon engulfment [6] and iron was thought to be the nursing material being transferred from the macrophage to erythroblasts [7]. Intensive research has demonstrated that the source of iron required for Hb Heme synthesis in the BM is from senescent erythrocytes Hb, disintegrated and recycled in the liver and spleen macrophages to be delivered back to the BM by transferrin [8]. In this context, macrophages activity is mediated by heme oxygenase-
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