Figure 3.
Figure 3. B-cell progenitors in myeloid colony formation assays. (A) Reanalyzing the sorted CD34+/CD19+ cells in each experiment for the presence of any CD34+/CD19- cells that might form myeloid colonies showed that 100% of sorted cells expressed CD19. The percentage of each subpopulation relative to the total number of cells is shown. (B) Myeloid colony formation per 1000 cells. A significant fraction of CD34+/CD19+/CXCR4- BM cells was able to form myeloid colonies containing granulocytes, macrophages, or erythrocytes (top) as compared to CD34+/CD19+/CXCR4+ cells (middle) and total CD34+ cells (bottom). □ indicates granulocyte-macrophage colony-forming units (CFU-GMs); ▦, BFU-E; and ▪, CFU-GEMM. Note the different scales showing the colony numbers between the graphs; n = 3 each performed in triplicate. Error bars indicate standard error (SE).

B-cell progenitors in myeloid colony formation assays. (A) Reanalyzing the sorted CD34+/CD19+ cells in each experiment for the presence of any CD34+/CD19- cells that might form myeloid colonies showed that 100% of sorted cells expressed CD19. The percentage of each subpopulation relative to the total number of cells is shown. (B) Myeloid colony formation per 1000 cells. A significant fraction of CD34+/CD19+/CXCR4- BM cells was able to form myeloid colonies containing granulocytes, macrophages, or erythrocytes (top) as compared to CD34+/CD19+/CXCR4+ cells (middle) and total CD34+ cells (bottom). □ indicates granulocyte-macrophage colony-forming units (CFU-GMs); ▦, BFU-E; and ▪, CFU-GEMM. Note the different scales showing the colony numbers between the graphs; n = 3 each performed in triplicate. Error bars indicate standard error (SE).

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