DNA-Protein Interaction of gamma-Globin Gene Promoter by Differentiation Inducers / 대한혈액학회지

BACKGROUND: The K562 erythroleukemia cell line was used to study the molecular mechanisms regulating lineage commitment of hematopoietic cells. There are numerous similarities between the erythroid or megakaryocytic lineages. In this study, we examined role of the region -269~-240 of gamma-globin gene promoter in fetal hemoglobin expression during either erythroid or megakaryocytic differentiation. METHODS: K562 cells were cultured and treated with differentiation inducers. Hemoglobin content was scored by benzidine staining, and hemoglobin F was stained by acid elution technique. To determine whether transcription factor binding to the gamma-globin gene promoter is critical to lineage determination, DNA-protein interaction of gamma-globin gene promoter was examined under both uninduced and induced conditions of K562 cells using gel mobility shift assay and southwestern blot analysis. RESULTS: Phorbol 12-myristate 13-acetate (PMA) induced a megakaryocytic differentiation, but suppressed erythroid differentiation. On the other hand, hydroxyurea (HU), hemin, n-butanol, and sodium butyrate (NaB) induced the expression of erythroid phenotypes. Parallel to hemoglobinization, increase in gamma-globin mRNA was observed in HU- and hemin-treated K562 cells. Gel mobility shift assay and southwestern blot analysis revealed that binding of a erythroid-specific protein (p120) to the region -269~-240 of gamma-globin gene promoter occurred with treatment of erythroid differentiation inducers and did not occur with treatment of PMA. CONCLUSION: These results suggest that erythroid differentiation inducers may act via DNA- protein interaction at the gamma-globin gene promoter region to induce erythroid differentiation.

Role of Gamma Globin Promoter Region -269~-240 in Hydroxyurea Treated Erythroid Progenitor Cells / 대한임상병리학회지

BACKGROUND: Recently, a great deal of interest has been focused on the use of hydroxyurea and hemin that may augment Hb F levels in patients with hemoglobinopathies and thalassemia, although the molecular mechanism of those chemicals remains unclear. In this study, we examined the effects of hydroxyurea and hemin on human adult peripheral and cord blood erythroid cells grown in a two-phase liquid culture system. METHODS: Four adult peripheral and four cord blood cells were cultured in two-phase liquid culture, and were treated with hydroxyurea or hemin. We counted isolated erythroid cells by acid benzidine and glycophorin A stains. To determine whether transcription factor binding to the promoter is critical, we also examined the promoter region of gamma globin gene both under uninduced and hydroxyurea or hemin induced conditions using gel mobility shift assay and southwestern blot analysis. RESULTS: When added together with erythropoietin, hydroxyurea led to significant increase in the percentage of erythroid cells in cord blood. In contrast, hemin greatly accelerated hemoglobin accumulation in adult erythroid progenitor cells. At -230 and -264 regions of gamma globin gene promoter, different protein binding patterns were observed in uninduced and hydroxyurea or hemin induced conditions between adult and cord blood. CONCLUSIONS: These results suggest that hydroxyurea and hemin may act via alteration in DNA-protein interactions to induce gamma globin gene expression. In addition, we can conclude that different transcription factors may be involved in the gamma globin induction process between the adult and cord blood erythroid cells.