Conserved elements containing NF-E2 and tandem GATA binding sites are required for erythroid-specific chromatin structure reorganization within the human beta-globin locus control region.

Proper expression of the genes of the human beta-globin gene locus requires the associated locus control region (LCR). Structurally, the LCR is defined by the presence of four domains of erythroid-specific chromatin structure. These domains, which have been characterized as DNase I hypersensitive sites (HSs), comprise the active elements of the LCR. The major focus of this research is to define the cis -acting elements which are required for the formation of these domains of unique chromatin structure. Our previous investigations on the formation of LCR HS4 demonstrated that NF-E2 and tandem, inverted GATA binding sites are required for the formation of the native HS. Similarly arranged NF-E2 and tandem GATA sites are present within the core regions of the other human LCR HSs and are evolutionarily conserved. Using site-directed mutagenesis of human HSs 2 and 3 we have tested the hypothesis that these NF-E2 and GATA sites are common requirements for the formation of all LCR HSs. We find that mutation of these elements, and particularly the GATA elements, results in a decrease or complete loss of DNase I hypersensitivity. These data imply the presence of common structural elements within the core of each LCR HS which are required for erythroid-specific chromatin structure reorganization.     

In vivo formation of a human beta-globin locus control region core element requires binding sites for multiple factors including GATA-1, NF-E2, erythroid Kruppel-like factor, and Sp1

The active elements of the beta-globin locus control region (LCR) are located within domains of unique chromatin structure. These nuclease hypersensitive sites (HSs) are characterized by high DNase I sensitivity, erythroid specificity, similar nucleosomal structure, and evolutionarily conserved clusters of cis-acting elements that are required for the formation and function of the core elements. To determine the requirements for HS core formation in the setting of nuclear chromatin, we constructed a series of artificial HS cores containing binding sites for GATA-1, NF-E2, and Sp1. In contrast to the results of previous in vitro experiments, we found that when constructs were stably integrated in mouse erythroleukemia cells the binding sites for NF-E2, GATA-1, or Sp1 alone or in any combination were unable to form core HS structures. We subsequently identified two new cis-acting elements from the LCR HS4 core that, when combined with the NF-E2, Sp1, and tandem inverted GATA elements, result in core structure formation. Both new cis-acting elements bind Sp1, and one binds erythroid Kruppel-like factor (EKLF). We conclude that in vivo beta-globin LCR HS core formation is more complex than previously thought and that several factors are required for this process to occur.     

Structural analysis and mapping of DNase I hypersensitivity of HS5 of the beta-globin locus control region.

The beta-globin locus control region (LCR) is a cis regulatory element that is located in the 5' part of the locus and confers high-level erythroid lineage-specific and position-independent expression of the globin genes. The LCR is composed of five DNase I hypersensitive sites (HSs), four of which are formed in erythroid cells. The function of the 5'-most site, HS5, remains unknown. To gain insights into its function, mouse HS5 was cloned and sequenced. Comparison of the HS5 sequences of mouse, human, and galago revealed two extensively conserved regions, designated HS5A and HS5B. DNase I hypersensitivity mapping revealed that two hypersensitive sites are located within the HS5A region (designated HS5A(major) and HS5A(minor)), and two are located within the HS5B region (HS5B(major), HS5B(minor)). The positions of each of these HSs colocalize with either GATA-1 or Ap1/NF-E2 motifs, suggesting that these protein binding sites are implicated in the formation of HS5. Gel retardation assays indicated that the Ap1/NF-E2 motifs identified in murine HS5A and HS5B interact with NF-E2 or similar proteins. Studies of primary murine cells showed that HS5 is formed in all hemopoietic tissues tested (fetal liver, adult thymus, and spleen), indicating that this HS is not erythroid lineage specific. HS5 was detected in murine brain but not in murine kidney or adult liver, suggesting that this site is not ubiquitous. The presence of GATA-1 and NF-E2 motifs (which are common features of the DNase I hypersensitive sites of the LCR) suggests that the HS5 is organized in a manner similar to that of the other HSs. Taken together, our results suggest that HS5 is an inherent component of the beta-globin locus control region.     

Dependence of globin gene expression in mouse erythroleukemia cells on the NF-E2 heterodimer.

High-level, tissue-specific expression of the beta-globin genes requires the presence of an upstream locus control region (LCR). The overall enhancer activity of the beta-globin complex LCR (beta-LCR) is dependent on the integrity of the tandem NF-E2 sites of HS-2. The NF-E2 protein which binds these sites is a heterodimeric basic leucine zipper protein composed of a tissue-specific subunit, p45 NF-E2, and a smaller subunit, p18 NF-E2, that is widely expressed. In these studies, we sought to investigate the role of NF-E2 in globin expression. We show that expression of a dominant-negative mutant p18 greatly reduces the amount of functional NF-E2 complex in the cell. Reduced levels of both alpha- and beta-globin were associated with the lower levels of NF-E2 activity in this cell line. Globin expression was fully restored upon the introduction of a tethered p45-p18 heterodimer. We also examined CB3 cells, a mouse erythroleukemia (MEL) cell line that does not express endogenous p45 NF-E2, and demonstrated that the restoration of globin gene expression was dependent upon the levels of expressed tethered NF-E2 heterodimer. Results of DNase I hypersensitivity mapping and in vivo footprinting assays showed no detectable chromatin alterations in beta-LCR HS-2 due to loss of NF-E2. Finally, we examined the specificity of NF-E2 for globin gene expression in MEL cells. These experiments indicate a critical role for the amino-terminal domain of p45 NF-E2 and show that a related protein, LCRF1, is unable to restore globin gene expression in p45 NF-E2-deficient cells. From these results, we conclude that NF-E2 is specifically required for high level goblin gene expression in MEL cells.     

Synthetic human beta-globin 5'HS2 constructs function as locus control regions only in multicopy transgene concatamers.

Transgenes linked to the beta-globin locus control region (LCR) are transcribed in a copy-dependent manner that is independent of the integration site. It has previously been shown that the LCR 5'HS2 region does not require its NF-E2 dimer binding site for LCR activity. In this paper we analyse synthetic 5'HS2 core constructs containing point mutations in the other factor binding sites 3' of the NF-E2 dimer site. The results show that 5'HS2 core is a partially active LCR that functions in a concatamer of at least two copies but not when present as a single copy in transgenic mice and that no single binding site within 5'HS2 is required for position-independent expression. In addition, the H-BP factor is identical to upstream stimulatory factor (USF) and full enhancement levels by 5'HS2 core in MEL cells require a combination of all the factor binding sites. We suggest that 5'HS2 cores in a concatamer interact with each other to establish an area of open chromatin and that this process may be the basis of LCR function.