Figure 1
Figure 1. Bone marrow erythroblast preparations, EPO-dependent survival responses, and transcriptome-based identification of EPO-regulated survival genes. (A) Bone marrow preparations were expanded for 3 days in SP34-EX medium to yield KitposCD71highTer119neg, KitnegCD71highTer119neg, and KitnegCD71highTer119pos erythroblast populations. Each was then purified by MACS and/or FACS, and increases in survival as afforded by EPO were determined. Specifically, cells were cultured in SP34-EX medium in the absence of SCF and presence of EPO at 0.1 U/mL. At 18 hours, frequencies of apoptotic cells were assayed using FITC–annexin-V and flow cytometry. Values are normalized means plus or minus SE. KitposCD71highTer119neg erythroblasts as purified by multiparameter MACS also were visualized in cytospin preparations and were assayed for protection against programmed cell death at a range of EPO doses. In the lower left panel, flow cytometry analyses also depict the homogeneity of isolated KitposCD71highTer119neg cells. (B) KitposCD71highTer119neg erythroblasts were cultured for 6 hours in the absence of hematopoietic cytokines, and were then exposed to EPO (± 5 U/mL) for 90 minutes. This included parallel processing of bone marrow–derived erythroblasts from n = 4 independent mice. After EPO exposure, RNA was isolated directly; 4 μg was used in biotin-cRNA syntheses and Affymetrix 430-2.0 array hybridizations. Among candidate (anti)apoptosis-related genes, 8 proved to be modulated by EPO at a confidence interval more than 99%. This included Irs2, Trb3, Trb2, Foxo3a, Bim, Pim1, Pim3, and Serpina3G (S3G). Values are mean-fold modulation plus or minus SD.

Bone marrow erythroblast preparations, EPO-dependent survival responses, and transcriptome-based identification of EPO-regulated survival genes. (A) Bone marrow preparations were expanded for 3 days in SP34-EX medium to yield KitposCD71highTer119neg, KitnegCD71highTer119neg, and KitnegCD71highTer119pos erythroblast populations. Each was then purified by MACS and/or FACS, and increases in survival as afforded by EPO were determined. Specifically, cells were cultured in SP34-EX medium in the absence of SCF and presence of EPO at 0.1 U/mL. At 18 hours, frequencies of apoptotic cells were assayed using FITC–annexin-V and flow cytometry. Values are normalized means plus or minus SE. KitposCD71highTer119neg erythroblasts as purified by multiparameter MACS also were visualized in cytospin preparations and were assayed for protection against programmed cell death at a range of EPO doses. In the lower left panel, flow cytometry analyses also depict the homogeneity of isolated KitposCD71highTer119neg cells. (B) KitposCD71highTer119neg erythroblasts were cultured for 6 hours in the absence of hematopoietic cytokines, and were then exposed to EPO (± 5 U/mL) for 90 minutes. This included parallel processing of bone marrow–derived erythroblasts from n = 4 independent mice. After EPO exposure, RNA was isolated directly; 4 μg was used in biotin-cRNA syntheses and Affymetrix 430-2.0 array hybridizations. Among candidate (anti)apoptosis-related genes, 8 proved to be modulated by EPO at a confidence interval more than 99%. This included Irs2, Trb3, Trb2, Foxo3a, Bim, Pim1, Pim3, and Serpina3G (S3G). Values are mean-fold modulation plus or minus SD.

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