Developmental changes in DNA methylation and covalent histone modifications of chromatin associated with the epsilon-, gamma-, and beta-globin gene promoters in Papio anubis

The baboon is a suitable and relevant animal model to study the mechanism of human globin gene switching. This investigation addresses the role of DNA methylation and histone coding in globin gene switching in the baboon, Papio anubis. Bisulfite sequencing and chromatin immunoprecipitation studies were performed in erythroid cells purified from fetuses of varying gestational ages and from adult bone marrow to analyze the manner that changes in DNA methylation of the epsilon-, gamma-, and beta-globin promoters and association of ac-H3, ac-H4, H3-dimeK4, H3-dimeK36, and H3-dimeK79 with the epsilon-, gamma-, and beta-globin promoters occur during development. Changes in DNA methylation of the epsilon- and gamma-globin gene promoters during transitional stages of globin gene switching were consistent with the stochastic model of methylation and a role of DNA methylation in gene silencing. Enrichment of ac-H3, ac-H4, and pol II at the promoters of developmentally active genes was observed, while the pattern of distribution of H3-dimeK4 and H3-dimeK79 suggests that these modifications are found near both currently and formerly active promoters. Enrichment of H3-dimeK36 at the silenced epsilon-globin gene promoter was observed. These studies demonstrate that coordinated epigenetic modifications in the chromatin structure of the beta-like globin gene promoters accompany the highly regulated changes in expression patterns of these genes during development.     

Epigenetic analysis of the human alpha- and beta-globin gene clusters

K562 erythroleukemia cells have been widely used as a model for the study of globin gene regulation. A number of agents have been shown to activate or suppress globin gene expression in these cells. However, the molecular effects of these agents on the epigenetic configuration of the alpha- and gamma-globin genes that encode HbF are not known. In this report, we investigated the relationship between globin expression and histone acetylation of the human alpha- and beta-globin clusters in the fetal erythroid environment of K562 cells. Our studies suggest that acetylation of histone H3 may be important in regulating developmental stage-specific expression of the different beta-like globin genes while acetylation of both histones H3 and H4 may be important for the regulation of tissue-specific expression of these genes. In contrast, acetylation of both histones H3 and H4 at the alpha-like globin promoters appears to be important for both developmental stage- and tissue-specific expression. Interestingly, butyrate-induced activation of alpha-globin gene expression in K562 cells is associated with significant increase in histone acetylation levels while TPA-induced inhibition is associated with decreased histone acetylation at its promoters. In contrast, changes in histone acetylation and DNA methylation do not appear to be important in the regulation of gamma-globin gene expression by the same agents. These data suggest that the butyrate-mediated induction of the fetal gamma-globin genes in K562 cells is not a direct result of its histone deacetylase inhibitor activity of butyrate on the chromatin of the gamma-globin promoters, while the induction of the alpha-globin genes could be a result of a direct effect of butyrate on chromatin at its promoters. This is another example of the important differences in the molecular mechanisms of regulation of the genes of the alpha- and beta-like globin clusters.     

Induction of an embryonic globin gene promoter by short-chain fatty acids

Short-chain fatty acids (SCFAs) and dimethyl sulfoxide (DMSO) induce adult erythroid differentiation in murine erythroleukemia (MEL) cells, but only SCFAs concurrently up-regulate expression from the endogenous embryonic globin gene epsilony. The epsilony promoter, linked to a reporter gene and stably transfected into MEL cells, was tested during adult erythroid differentiation. Both the epsilony-CACCC site at -114 bp and enhancer sequences (hypersensitive site 2 [HS2]) from the beta-globin locus control region (LCR) were essential to maximal SCFA-mediated induction of expression from these constructs in MEL cells. Gel-shift analyses of binding activity from SCFA-induced MEL cell nuclear extracts showed in vitro binding by specificity proteins 1 and 3 (SP1, SP3) and basic or erythroid Krüppel-like factors (BKLF, EKLF) at the epsilony-CACCC site. In a functional analysis, transient cotransfections in nonerythroid NIH/3T3 cells of SP1, SP3, BKLF, or EKLF and HS2 epsilony promoter-luciferase constructs, with or without coactivators (p300, CREB-binding protein [CBP], or p300/CBP-associated factor [PCAF]) and SCFAs, were performed. SP1, SP3, and EKLF further increased expression from HS2 epsilony promoter constructs following exposure to SCFAs. This effect was variably augmented by coactivators and was diminished in EKLF mutants that were unable to undergo histone/factor-acetyl transferase (H/FAT)-mediated acetylation. In addition, acetylation of SP1 was detectable in NIH/3T3 cells following exposure to SCFAs. In sum, LCR sequence and an embryonic globin gene promoter CACCC site were essential to that promoter's up-regulation during SCFA-mediated induction of adult erythroid differentiation in vitro. Of factors that interact at the CACCC site, SCFA-mediated acetylation is implicated in SP1 and EKLF, and may be a mechanism through which SCFAs induce embryonic/fetal globin gene promoters during adult erythroid differentiation.     

KLF2 is essential for primitive erythropoiesis and regulates the human and murine embryonic beta-like globin genes in vivo

The Krüppel-like factors (KLFs) are a family of C2/H2 zinc finger DNA-binding proteins that are important in controlling developmental programs. Erythroid Krüppel-like factor (EKLF or KLF1) positively regulates the beta-globin gene in definitive erythroid cells. KLF2 (LKLF) is closely related to EKLF and is expressed in erythroid cells. KLF2-/- mice die between embryonic day 12.5 (E12.5) and E14.5, because of severe intraembryonic hemorrhaging. They also display growth retardation and anemia. We investigated the expression of the beta-like globin genes in KLF2 knockout mice. Our results show that KLF2-/- mice have a significant reduction of murine embryonic Ey- and beta h1-globin but not zeta-globin gene expression in the E10.5 yolk sac, compared with wild-type mice. The expression of the adult beta(maj)- and beta(min)-globin genes is unaffected in the fetal livers of E12.5 embryos. In mice carrying the entire human globin locus, KLF2 also regulates the expression of the human embryonic epsilon-globin gene but not the adult beta-globin gene, suggesting that this developmental-stage-specific role is evolutionarily conserved. KLF2 also plays a role in the maturation and/or stability of erythroid cells in the yolk sac. KLF2-/- embryos have a significantly increased number of primitive erythroid cells undergoing apoptotic cell death.     

Effect of deletion of 5''HS3 or 5''HS2 of the human beta-globin locus control region on the developmental regulation of globin gene expression in beta-globin locus yeast artificial chromosome transgenic mice.

To analyze the function of the 5' DNase I hypersensitive sites (HSs) of the locus control region (LCR) on beta-like globin gene expression, a 2.3-kb deletion of 5'HS3 or a 1.9-kb deletion of 5'HS2 was recombined into a beta-globin locus yeast artificial chromosome, and transgenic mice were produced. Deletion of 5'HS3 resulted in a significant decrease of epsilon-globin gene expression and an increase of gamma-globin gene expression in embryonic cells. Deletion of 5'HS2 resulted in only a small decrease in expression of epsilon-, gamma-, and beta-globin mRNA at all stages of development. Neither deletion affected the temporal pattern of globin gene switching. These results suggest that the LCR contains functionally redundant elements and that LCR complex formation does not require the presence of all DNase I hypersensitive sites. The phenotype of the 5'HS3 deletion suggests that individual HSs may influence the interaction of the LCR with specific globin gene promoters during the course of ontogeny.     

Conservation of the primary structure, organization, and function of the human and mouse beta-globin locus-activating regions.

DNA sequences located in a region 6-18 kilobases (kb) upstream from the human epsilon-globin gene are known as the locus-activating region (LAR) or dominant control region. This region is thought to play a key role in chromatin organization of the beta-like globin gene cluster during erythroid development. The beta-globin LAR activates linked globin genes in transiently or stably transfected erythroleukemia cells and in erythroid cells of transgenic mice. Since the human beta-globin LAR is functional in mice, we reasoned that critical LAR sequence elements might be conserved between mice and humans. We therefore cloned murine genomic sequences homologous to one portion of the human LAR (site II, positions -11,054 to -10,322 with respect to the human epsilon gene). We found that this murine DNA fragment (mouse LAR site II) and sequences homologous to human LAR sites I and III are located upstream from the mouse beta-like globin gene cluster and determined that their locations relative to the cluster are similar to that of their human counterparts. The homologous site II sequences are 70% identical between mice and humans over a stretch of approximately 800 base pairs. Multiple core sequences with greater than 80% identity were present within this region. Transient and stable transfection assays of K562 erythroleukemia cells demonstrated that both human and mouse LAR elements contain enhancer activity and confer hemin inducibility on a linked human gamma-globin promoter. These results suggest that primary structural elements--and the spatial organization of these elements--are important for function of the beta-globin LAR.