Developmentally regulated and erythroid-specific expression of the human embryonic beta-globin gene in transgenic mice.

Transgenic mice have proven to be an effective expression system for studying developmental control of the human fetal and adult beta-globin genes. In the current work we are interested in developing the transgenic mouse system for the study of the human embryonic beta-globin gene, epsilon. An epsilon-globin gene construction (HSII,I epsilon) containing the human epsilon-globin gene with 0.2 kb of 3' flanking sequence and 13.7 kb of extended 5' flanking region including the erythroid-specific DNase I super-hypersensitive sites HSI and HSII was made. This construction was injected into fertilized mouse ova, and its expression was analyzed in peripheral blood, brain, and liver samples of 13.5 day transgenic fetuses. Fetuses carrying intact copies of the transgene expressed human epsilon-globin mRNA in their peripheral blood. Levels of expression of human epsilon-globin mRNA in these transgenic mice ranged from 2% to 26% per gene copy of the endogenous mouse embryonic epsilon y-globin mRNA level. Furthermore, the human epsilon-globin transgene was expressed specifically in peripheral blood but not in brain or in liver which is an adult erythroid tissue at this stage. Thus, the HSII,I, epsilon transgene was expressed in an erythroid-specific and embryonic stage-specific manner in the transgenic mice. A human epsilon-globin gene construction that did not contain the distal upstream flanking region which includes the HSI and HSII sites, was not expressed in the embryos of transgenic mice. These data indicate that the human epsilon-globin gene with 5' flanking region extending to include DNase I super-hypersensitive sites HSI and HSII is sufficient for the developmentally specific activation of the human epsilon-globin gene in erythroid tissue of transgenic mice.     

Repetitive DNA sequences near three human beta-type globin genes.

Five repetitive DNA sequences, of average length 259 bp, have been identified in the intergenic regions which flank three human beta-tupe globin genes. A pair of inverted repeat sequences, separated by 919 bp, was found 1.0 kb to the 5' side of the epsiln-globin gene. Each contains a homologous Alu I site. Another repetitive sequence, with the same orientation as the inverted repeat sequence closest to the epsilon-globin gene, lies about 2.2 kb to the 5' side of the delta-globin gene. A pair of inverted repeat sequences, with the same relative orientations as the other pair and separated by about 800 bp, was found about 1.5 kb to the 3' side of the beta-globin gene.     

Functional Analysis of Multiple Transcription Factor Sites in a Regulatory Element of Human ε-Globin Gene

The human β-like globin genes are arranged as a clusterof five genes (ε, Gγ, Aγ, δ and β) in the order of theirtemporal expression. The human embryonic ε-globin geneis expressed in the blood island of the embryonic yolk sacand is silenced completel     

Embryonic and fetal beta-globin gene repression by the orphan nuclear receptors, TR2 and TR4

The TR2 and TR4 orphan nuclear receptors comprise the DNA-binding core of direct repeat erythroid definitive, a protein complex that binds to direct repeat elements in the embryonic and fetal beta-type globin gene promoters. Silencing of both the embryonic and fetal beta-type globin genes is delayed in definitive erythroid cells of Tr2 and Tr4 null mutant mice, whereas in transgenic mice that express dominant-negative TR4 (dnTR4), human embryonic epsilon-globin is activated in primitive and definitive erythroid cells. In contrast, human fetal gamma-globin is activated by dnTR4 only in definitive, but not in primitive, erythroid cells, implicating TR2/TR4 as a stage-selective repressor. Forced expression of wild-type TR2 and TR4 leads to precocious repression of epsilon-globin, but in contrast to induction of gamma-globin in definitive erythroid cells. These temporally specific, gene-selective alterations in epsilon- and gamma-globin gene expression by gain and loss of TR2/TR4 function provide the first genetic evidence for a role for these nuclear receptors in sequential, gene-autonomous silencing of the epsilon- and gamma-globin genes during development, and suggest that their differential utilization controls stage-specific repression of the human epsilon- and gamma-globin genes.     

The 5'' flanking region of human epsilon-globin gene.

The structural analysis of the 2.0 kb region upstream from the epsilon-globin gene has been carried out. A genomic DNA map around the gene was worked out in some detail to ensure that the cloned DNA was representative of the actual chromosomal arrangement. Furthermore, a new technique was developed to precisely map a reiterated DNA sequence present 1.5 kb to the 5' side of the gene. The complete nucleotide sequence of the 2.0 kb 5' flanking region was then determined and overlapped with the gene. The sequence included the reiterated DNA sequence which is homologous to the so-called AluI family of repeats. Unusual stretches of sequence 50 nucleotides long, where A + T represent about 90% of the bases, are present at both the 5' and 3' sides of the repeat.     

Characterization ofAlu family repetitive sequences which flank human β-type globin genes

Heteroduplex mapping has determined the size, location, and orientation of three Alu family sequences from the human beta-type globin gene cluster. Two of these sequences have the same orientation. One (231 bp long) is 2 kb to the 5' side of the B gamma-globin gene and the other (222 bp) is l kb 5' to the pseudo-beta-l-globin gene. The third (300 bp), 3-4 kb 3' to the pseudo-beta-l-globin gene, has the opposite orientation. Their orientations relative to five previously characterized Alu sequences from this cluster have been established. One of these, 2.5 kb 5' to the epsilon-globin gene, was shown by Southern blot hybridization to be similar but not identical to other family members, whereas the region separating it from a neighbouring inverted repeat is not widely distributed in the human genome.     

Human leukemic K562 cells: differential effects of 5-azacytidine on DNA methylation of epsilon-, gamma-globin and 7SL RNA genes

5 Azacytidine ribonucleoside (5 Aza CR), greatly enhances erythroid differentiation of the K562(h) cell line, with a sharp increase of embryonic and fetal globin gene expression. This phenomenon is correlated with the undermethylation of gamma-globin but not of epsilon-globin, as the epsilon-globin gene is already extensively undermethylated before 5AzaCR induction. By contrast no variations in both DNA methylation and expression are observed in 7SL RNA genes.