A 46 base pair enhancer sequence within the locus activating region is required for induced expression of the gamma-globin gene during erythroid differentiation.

The locus activating region (LAR), contained within 30 kb of chromatin flanking the human beta-globin gene cluster, has recently been shown to be essential for high level beta-globin gene expression. To determine the effect of fragments containing LAR sequences on globin gene expression, mRNA from a marked gamma-globin gene linked to LAR fragments was assayed in stably transfected K562 erythroleukemia cells. DNaseI hypersensitive site II (HS II), located 10.9 kb upstream of the epsilon-globin gene, was required for high level gamma-globin gene expression. We also showed that a 46 bp enhancer element within HS II was necessary and sufficient for the increased gamma-globin gene expression observed with hemin induced erythroid maturation of K562 cells. These results localize a distant regulatory element important for activation of globin genes during human erythroid cell maturation.     

Multiple elements in human beta-globin locus control region 5' HS 2 are involved in enhancer activity and position-independent, transgene expression.

The human beta-globin Locus Control Region (LCR) has two important activities. First, the LCR opens a 200 kb chromosomal domain containing the human epsilon-, gamma- and beta-globin genes and, secondly, these sequences function as a powerful enhancer of epsilon-, gamma- and beta-globin gene expression. Erythroid-specific, DNase I hypersensitive sites (HS) mark sequences that are critical for LCR activity. Previous experiments demonstrated that a 1.9 kb fragment containing the 5' HS 2 site confers position-independent expression in transgenic mice and enhances human beta-globin gene expression 100-fold. Further analysis of this region demonstrates that multiple sequences are required for maximal enhancer activity; deletion of SP1, NF-E2, GATA-1 or USF binding sites significantly decrease beta-globin gene expression. In contrast, no single site is required for position-independent transgene expression; all mice with site-specific mutations in 5' HS 2 express human beta-globin mRNA regardless of the site of transgene integration. Apparently, multiple combinations of protein binding sites in 5' HS 2 are sufficient to prevent chromosomal position effects that inhibit transgene expression.     

Position independence and proper developmental control of gamma-globin gene expression require both a 5'' locus control region and a downstream sequence element.

We have analyzed the expression of human gamma-globin genes during development in F2 progeny of transgenic mice carrying two types of constructs. In the first type, gamma-globin genes were linked individually to large (approximately 4-kb) sequence fragments spanning locus control region (LCR) hypersensitive site 2 (HS2) or HS3. These LCR fragments contained not only the core HS elements but also extensive evolutionarily conserved flanking sequences. The second type of construct contained tandem gamma- and beta-globin genes linked to identical HS2 or HS3 fragments. We show that gamma-globin expression in transgenic mice carrying HS2 gamma or HS3 gamma constructs is highly sensitive to position effects and that such effects override the cis regulatory elements present in these constructs to produce markedly different developmental patterns of gamma-globin expression in lines carrying the same transgene. In contrast, gamma-globin expression in both HS2 gamma beta and HS3 gamma beta mice is sheltered from position effects and the developmental patterns of gamma-globin expression in lines carrying the same transgene are identical and display stage-specific regulation. The results suggest that cis regulatory sequences required for proper developmental control of fetal globin expression in the presence of an LCR element reside downstream from the gamma genes.     

Identification of New Regulatory Sequences Far Upstream of the Mouse Monocyte Chemoattractant Protein-1 Gene

We systematically searched for sequences influencing the expression of the mouse monocyte chemoattractant protein-1 (MCP-1) gene (Scya2) by mapping DNase I hypersensitive sites (HS) in the chromatin of mesangial cells in a 40-kb interval around the gene. We found nine HS located between -24 kb and +12.7 kb. Three HS coincided with previously known regulatory sequences (HS-2.4, HS-1.0, and HS-0.2). We tested two of the previously unknown HS located far upstream of Scya2 (HS-19.4 and HS-16.3) in transfection experiments using luciferase reporter constructs and mouse mesangial cells as recipients. In transient transfections, both HS had a moderate effect on basal promoter activity as well as promoter activity stimulated by tumor necrosis factor-alpha. In stable transfection experiments, we found much higher activity. A DNA fragment containing HS-19.4 and HS-16.3 caused a considerable increase in the number of stably integrated luciferase copies. We determined the nucleotide sequence of the 5' flanking region to -28.6 kb. Computer-assisted sequence analysis did not yield evidence of an additional gene. These HS are located within the 5' flanking region of a gene cluster consisting of Scya2 (MCP-1), Scya7 (MCP-3), Scya11 (eotaxin), Scya12 (MCP-5), and Scya8 (MCP-2). This report represents the first comprehensive chromatin analysis of the mouse MCP-1 locus leading to the identification of a complex regulatory region located far upstream of Scya2.     

Distal regulatory elements from the mouse metallothionein locus stimulate gene expression in transgenic mice.

DNA regions of 10 and 7 kb that flank the mouse metallothionein II (MT-II) and MT-I genes, respectively, were combined with a minimally marked MT-I (MT-I*) gene and tested in transgenic mice. This construct resulted in (i) position-independent expression of MT-I* mRNA and copy number-dependent expression, (ii) levels of hepatic MT-I mRNA per cell per transgene that were about half that derived from endogenous MT-I genes, (iii) appropriate regulation by metals and hormones, and (iv) tissue distribution of transgene mRNA that resembled that of endogenous MT-I mRNA. These features were not observed when MT-I* was tested without the flanking regions. These MT-I flanking sequences also improved the expression of rat growth hormone reporter genes, with or without introns, that were under the control of the MT-I promoter. Moreover, they enhanced expression from two of four heterologous promoters/enhancers that were tested. Deletion analysis indicated that regions known to have DNase I-hypersensitive sites were necessary but not sufficient for high-level expression. These data suggest that the DNA regions flanking the mouse MT-I and MT-II genes have functions like the locus control regions described for other genes.     

The structure of the human CD2 gene and its expression in transgenic mice.

We report the genomic organization of the human CD2 gene and its expression in transgenic mice. A 28.5 kb segment of DNA consisting of 4.5 kb 5' flanking sequences, 15 kb containing the gene's five exons and 9 kb of 3' flanking sequences can direct the expression of the CD2 gene only on thymocytes, circulating T cells and megakaryocytes of the transgenic mice. The expression of each copy of the human CD2 transgene appears to be as high as the endogenous mouse CD2 gene and as high as the expression on the surface of human T lymphocytes, independent of the site of integration and dependent on the copy number of genes that have integrated.     

Sequences within and flanking hypersensitive sites 3 and 2 of the beta-globin locus control region required for synergistic versus additive interaction with the epsilon-globin gene promoter.

The locus control region is required for high-level, position-independent expression of mammalian beta-globin genes. It is marked by five major DNase hypersensitive sites (HSs) in a 16 kb region of chromatin, and the protein-DNA complexes that form these HSs may interact in a holocomplex that carries out the full function of the locus control region. Previous studies showed that a large rabbit DNA fragment containing both HS2 and HS3 in their native sequence context and spacing produced a much larger increase in expression of a linked reporter gene than the sum of the largest effects observed with DNA fragments containing HS2 or HS3 individually. To test whether this reflected a synergistic interaction between the 200-400 bp cores of the HSs or if this effect required additional sequences outside the cores, combinations of different restriction fragments containing HS2 or HS3 were tested for their ability to increase the expression of a hybrid epsilon-globin-luciferase reporter gene in transfected K562 cells. The results show that the human HS2 and HS3 cores do not interact either additively or synergistically with the reporter gene when juxtaposed, and separation by spacer DNA has little effect on their function. Fragments of human DNA containing cores plus flanking sequences for HS3 or HS2 show an additive effect in combination, whereas homologous fragments of rabbit DNA containing HS3 and HS2 interact synergistically. At least part of this difference localizes to the rabbit DNA fragment containing HS3, which can interact synergistically with the human DNA fragment containing HS2. The region 5' to the HS3 core plays a role both in the cooperative interaction observed with the rabbit DNA fragment and the domain-opening observed with the human DNA. A minor DNase HS maps to this region, and the pattern of sequence conservation is consistent with some difference in function between species.     

A locus control region at -12 kb of the tyrosinase gene.

We have shown previously that the tyrosinase gene encompassed in a 250 kb yeast artificial chromosome (YAC) is expressed faithfully in transgenic mice. To define the sequences important for this qualitatively and quantitatively correct expression pattern, we have generated transgenic mice with YACs carrying several deletions in the mouse tyrosinase locus. In particular, we wanted to address the in vivo relevance of a regulatory element indicated by a cell-specific DNase I hypersensitive site (HS) located -12 kb upstream of the gene. Wild-type level expression was observed only when the YACs transferred contained this HS. Constructs in which the HS was deleted gave rise to much weaker expression and variable patterns of expression. In conclusion, this HS region appears to harbour the essential regulatory element for the correct expression of the tyrosinase gene. Moreover, it behaves as a locus control region in that it commands the functional status of this expression domain, protecting it from position effects.