Macrophage Hypercellularity Accompanies Erythroid Hyperplasia in Sickle Cell Mice and during Recovery from Blood Loss in Wild Type Mice

Red blood cell (RBC) homeostasis tightly balances production of new erythroid cells and clearance of damaged or senescent RBCs. Macrophages play a central role in this process in the specialized niches termed erythroblastic island. Macrophages expressing CD169 (Sialoadhesin or Siglec-1), F4/80, CD11...

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Bibliographic Details
Published in:Blood 2019-11, Vol.134 (Supplement_1), p.3528-3528
Main Authors: Gbotosho, Oluwabukola, Kapetanaki, Maria G, Ghosh, Samit, Weidert, Frances, Bullock, Grant C., Ofori-Acquah, Solomon Fiifi, Kato, Gregory J
Format: Article
Language:English
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Summary:Red blood cell (RBC) homeostasis tightly balances production of new erythroid cells and clearance of damaged or senescent RBCs. Macrophages play a central role in this process in the specialized niches termed erythroblastic island. Macrophages expressing CD169 (Sialoadhesin or Siglec-1), F4/80, CD11b, VCAM-1, ER-HR3 and Ly-6G play important roles in physiological and pathological erythropoiesis. Sickle cell disease (SCD) is characterized by chronic stress erythropoiesis as a compensatory mechanism for anemia. Recent publications have detected macrophage hypercellularity correlated with erythroid hyperplasia in genetic models of erythrocytosis and monocyte-derived macrophage proliferation in the spleen. Because macrophages are integral part of the erythropoietic niche, our objective was to assess the macrophage compartment in transgenic sickle cell mice (SS) at steady state compared to AA controls. Furthermore, we used acute blood loss in C57BL/6J wild type (WT) to confirm if macrophage hypercellularity accompanies erythroid hyperplasia in a mouse model without erythrocytosis or sickling. Using flow cytometry, macrophages were identified with F4/80, CD45, CD11b and CD169, while erythroid progenitor cells were identified with Ter119 and CD71 in the BM and spleen of SS mice and age-matched control (AA) mice. Each subset of macrophages is 3.8 to 6.8-fold higher in SS mice bone marrow compared to AA at steady state (p≤0.05, Fig 1a). Findings were similar for other CD169 subsets in the spleens of SS mice. This macrophage hypercellularity was accompanied by expected erythroid hyperplasia, with 12-fold higher immature erythroid progenitor cells (CD71hiTer119hi) in SS mice than AA controls (p≤0.001). To confirm the increase in macrophage numbers that accompanied erythroid hyperplasia in SS mice as a response to erythroid stress, we induce stress with acute blood loss in WT mice by phlebotomy (once). Interestingly, we found macrophage hypercellularity accompanies erythroid hyperplasia in WT mice during recovery from acute blood loss. WT mice showed about 47-61% increases in CD169 macrophages subsets in the marrow and 47-83% increase in the spleen during recovery from acute blood loss (5-7 days) compared to untreated mice (Fig. 1b). This macrophage hypercellularity was accompanied with 88% increase in immature erythroid progenitor cell. Similarly, we investigated if there was age dependence in macrophage hypercellularity that accompanies erythroid hyperplasia in SS m
ISSN:0006-4971
1528-0020
DOI:10.1182/blood-2019-127224