Trans acting regulation of beta globin gene expression in erythroleukemia (K562) cells.

K562 cells are induced by hemin to produce gamma and epsilon globin but not beta globin, although the beta globin gene is intact, and when isolated is expressed in a transient expression assay (1, 2). We have previously shown that an epsilon globin gene transferred into K562 cells is expressed and inducible (3). In this paper, we report the stable transfer of a sickle or betaS globin gene into K562 cells. Thirty-six different transformed lines were tested; 24 of 36 lines contained an intact betaS globin gene. However, using S1 nuclease, Dot blot, and Northern blotting analyses, none of these lines showed beta globin mRNA expression. These results indicate that trans acting factors are responsible for the lack of expression of the beta globin gene in K562 cells.     

Stat3 beta inhibits gamma-globin gene expression in erythroid cells

We demonstrated previously gamma-globin gene inhibition in K562 cells and primary erythroid progenitors treated with interleukin-6. Although several cis-acting elements have been identified in the globin promoters, the precise mechanism for cytokine-mediated globin gene regulation remains to be elucidated. In this report we demonstrate inhibitors of Stat3 phosphorylation abrogate interleukin-6-mediated gamma gene silencing in erythroid cells. DNA-protein binding studies established Stat3 interaction in the 5'-untranslated gamma-globin promoter region. Furthermore, co-transfection experiments with Stat3 beta demonstrate gamma promoter inhibition in a concentration-dependent manner, which was significantly reversed when the cognate Stat3-binding site in the 5'-untranslated region was mutated. These studies establish a novel mechanism for gamma gene silencing through the STAT signal transduction pathway.     

Human globin gene expression after gene transfer

Human globin genes can be transferred into mouse and human erythroid cells in culture, and can be appropriately expressed at the mRNA level in these cells. A plasmid containing a human beta globin gene is expressed in mouse erythroleukemia cells (MELC), and another containing a human epsilon or gamma gene is expressed in human erythroleukemia (K562) cells. A neomycin resistance (neoR) gene on the plasmids has been used to select for those cells containing the transferred globin genes; this selection may favor the expression of the globin genes by providing chromosomal positions requiring neoR expression. Analyzing clones resistant to G418, a neomycin analogue, demonstrated globin mRNA expression and induction. Retroviral vectors have also been used to transfer and appropriately express human beta genes in MELC. In addition, a plasmid containing a dihydrofolate reductase (DHFR) gene as well as neoR and beta globin genes has been used to amplify and express beta globin mRNA in MELC. These experiments suggest that high level appropriate expression of human beta globin genes is feasible and provides potentially useful approaches to the long-range goal of gene therapy for sickle cell anemia and beta thalassemia.     

A novel nuclear protein which binds to G gamma and A gamma globin promoters and modulates hemoglobin synthesis in K562 cells.

Nuclear extract of human erythroleukemic cell line K562 contains a 70 kDa protein which is gradually reduced when cells are induced to express globin genes by 25 microM hemin. When globin synthesis was inhibited by cycloheximide (100 micrograms/ml) or Actinomycin D (1 microgram/ml), the disappearance of this protein was prevented. The 70 kDa nuclear protein exhibited strong binding to G gamma and A gamma globin promoters but not to beta-globin promoter. This suggests that this 70 kDa nuclear protein may be involved in the regulation of fetal globin gene expression.     

DNase I hypersensitivity in the gamma globin gene locus of K562 cells.

We have probed the chromatin conformation of the G gamma-A gamma-delta-beta globin gene locus of K562 cells, a human hematopoietic cell line, with the enzyme pancreatic DNAse I. This enzyme preferentially digests genes in an active configuration. We have found that in K562 cells, which produce embryonic and fetal but not adult hemoglobins, both the active gamma and inactive beta genes are DNAse I sensitive. However, only the active gamma genes have DNAse I hypersensitive regions. The hypersensitive regions have been mapped to an area approximately 100 base pairs 5' to the G gamma and A gamma genes.     

Role of gene order in developmental control of human gamma- and beta-globin gene expression.

To determine the effect of gene order on globin gene developmental regulation, we produced transgenic mice containing two tandemly arranged gamma- or beta-globin or gamma beta- and beta gamma-globin genes linked to a 2.5-kb cassette containing sequences of the locus control region (LCR). Analysis of constructs containing two identical gamma or beta genes assessed the effect of gene order on globin gene expression, while analysis of constructs containing tandemly arranged gamma and beta genes assessed any additional effects of the trans-acting environment. When two gamma genes were tandemly linked to the LCR, expression from the proximal gamma gene was three- to fourfold higher than expression from the distal gamma gene, and the ratio of proximal to distal gene expression remained unchanged throughout development. Similarly, when two beta genes were tandemly linked to the LCR, the proximal beta gene was predominantly expressed throughout development. These results indicate that proximity to LCR increases gene expression, perhaps by influencing the frequency of interaction between the LCR and globin gene promoters. An arrangement where the gamma gene was proximal and the beta gene distal to the LCR resulted in predominant gamma-gene expression in the embryo. When the order was reversed and the gamma gene was placed distally to the LCR, gamma-gene expression in the embryo was still up to threefold higher than expression of the LCR-proximal beta gene. These findings suggest that the embryonic trans-acting environment interacts preferentially with the gamma genes irrespective of their order or proximity to the LCR. We conclude that promoter competition rather than gene order plays the major role in globin gene switching.