Joining the loops: beta-globin gene regulation

The mammalian beta-globin locus is a multigene locus containing several globin genes and a number of regulatory elements. During development, the expression of the genes changes in a process called "switching." The most important regulatory element in the locus is the locus control region (LCR) upstream of the globin genes that is essential for high-level expression of these genes. The discovery of the LCR initially raised the question how this element could exert its effect on the downstream globin genes. The question was solved by the finding that the LCR and activate globin genes are in physical contact, forming a chromatin structure named the active chromatin hub (ACH). Here we discuss the significance of ACH formation, provide an overview of the proteins implicated in chromatin looping at the beta-globin locus, and evaluate the relationship between nuclear organization and beta-globin gene expression.     

The 5'HS4 core element of the human beta-globin locus control region is required for high-level globin gene expression in definitive but not in primitive erythropoiesis.

To assess the contribution of DNase I-hypersensitive site 4 (HS4) of the beta-globin locus control region (LCR) to overall LCR function we deleted a 280 bp fragment encompassing the core element of 5'HS4 from a 248 kb beta-globin locus yeast artificial chromosome (beta-YAC) and analyzed globin gene expression during development in beta-YAC transgenic mice. Four transgenic lines were established; each contained at least one intact copy of the beta-globin locus. The deletion of the 5'HS4 core element had no effect on globin gene expression during embryonic erythropoiesis. In contrast, deletion of the 5'HS4 core resulted in a significant decrease of gamma and beta-globin gene expression during definitive erythropoiesis in the fetal liver and a decrease of beta-globin gene expression in adult blood. We conclude that the core element of 5'HS4 is required for globin gene expression only in definitive erythropoiesis. Absence of the core element of HS4 may limit the ability of the LCR to provide an open chromatin domain and/or enhance gamma and beta-globin gene expression in the adult erythroid cells.     

Genome domains and domain regulatory elements

Gene activity regulation at the level of genome domains is considered with special emphasis on locus control regions (LCR), which are thought to act as dominant regulatory elements providing for the active state of tissue-specific gene domains. Detailed analysis was made of experimental data on the organization and function of mammalian beta-globin gene LCR. On recent evidence, this LCR is necessary for high-level expression of the globin genes, but not for the active state of the domain. These data are compared with earlier findings suggesting a key role of LCR in the organization of active genome domains. The boundaries of functional genome domains are also considered.     

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.