Hypersensitive site 4 of the human β-globin locus control region.

The Locus Control Region (LCR) of the human beta globin gene domain is defined by four erythroid-specific DNasel hypersensitive sites (HSS) located upstream of this multigene cluster. The LCR confers copy number dependent high levels of erythroid specific expression to a linked transgene, independent of the site of integration. To assess the role of the individual hypersensitive sites of the LCR, we have localized HSS4 to a 280bp fragment that is functional both in murine erythroleukaemia (MEL) cells and in transgenic mice. This fragment coincides with the major area of hypersensitivity 'in vivo' and contains a number of DNasel footprints. Bandshift analysis shows that these footprints correspond to binding sites for the erythroid specific proteins GATA1 and NF-E2 and a number of ubiquitous proteins, including jun/fos, Sp1 and TEF2

The β-globin dominant control region activates homologous and heterologous promoters in a tissue-specific manner

We have introduced a human beta-globin minilocus, containing the recently described dominant control region (DCR), the beta-globin or Thy-1 gene, and a thymidine kinase (tk)-neoR gene into erythroid and non-erythroid cells. Analysis of the transcription levels of the genes shows that the DCR directs high levels of human beta-globin, Thy-1 and tk-neo expression independent of integration sites in an erythroid-specific manner. The presence of the DNAasel hypersensitive sites at the 5' end of the locus is required for this effect on the homologous and heterologous gene. An analysis of the DCR chromatin in transfected mouse erythroleukemic cells suggests that the formation of the hypersensitive sites in this region precedes beta-globin gene expression

High-level, erythroid specific, expression of the human α-globin gene in transgenic mice and the production of human haemoglobin in murine erythrocytes.

Using the dominant control region (DCR) sequences that flank the beta-globin gene locus, we have been able to achieve high-level expression of the human alpha-globin gene in transgenic mice. Expression in fetal liver and blood is copy number dependent and at levels comparable to that of the endogenous mouse alpha-globin genes. Transgenic fetuses with high-copy numbers of the transgene suffer severe anemia and die before birth. Using a construct with both the human alpha- and beta-globin genes and the beta-globin DCR, live mice with low-copy numbers were obtained. Both human globin genes are expressed at high levels in adult red cells to give human hemoglobin HbA in amounts equal to or greater than endogenous mouse hemoglobin. Expression of HbA in murine red cells is not accompanied by any increase in mean corpuscular volume (MCV) or mean corpuscular hemoglobin concentration (MCHC). However, these transgenic mice tend to have an increased number of reticulocytes in peripheral blood; consistent with some degree of hemolysis. Metabolic labeling experiments showed balanced mouse globin synthesis, but imbalanced human globin synthesis, with an alpha/beta biosynthetic ratio of approximately 0.6. Thus, these mice have mild anemia. These results are discussed with relation to the coordinate regulation of alpha- and beta-globin synthesis in erythroid tissues

Importance of globin gene order for correct developmental expression.

We have used transgenic mice to study the influence of position of the human globin genes relative to the locus control region (LCR) on their expression pattern during development. The LCR, which is located 5' of the globin gene cluster, is normally required for the activation of all the genes. When the human beta-globin gene is linked as a single gene to the LCR it is activated prematurely in the embryonic yolk sac. We show that the correct timing of beta gene activation is restored when it is placed farther from the LCR than a competing human gamma- or alpha-globin gene. Correct timing is not restored when beta is the globin gene closest to the LCR. Similarly, the human gamma-globin gene is silenced earlier when present farthest from the LCR. On the basis of this result, we propose a model of developmental gene control based on stage-specific elements immediately flanking the genes and on polarity in the locus. We suggest that the difference in relative distance to the LCR, which is a consequence of the ordered arrangement of the genes, results in nonreciprocal competition between the genes for activation by the LCR