DNA methylation and chromatin structure regulate T cell perforin gene expression

Perforin is a cytotoxic effector molecule expressed in NK cells and a subset of T cells. The mechanisms regulating its expression are incompletely understood. We observed that DNA methylation inhibition could increase perforin expression in T cells, so we examined the methylation pattern and chromatin structure of the human perforin promoter and upstream enhancer in primary CD4(+) and CD8(+) T cells as well as in an NK cell line that expresses perforin, compared with fibroblasts, which do not express perforin. The entire region was nearly completely unmethylated in the NK cell line and largely methylated in fibroblasts. In contrast, only the core promoter was constitutively unmethylated in primary CD4(+) and CD8(+) cells, and expression was associated with hypomethylation of an area residing between the upstream enhancer at -1 kb and the distal promoter at -0.3 kb. Treating T cells with the DNA methyltransferase inhibitor 5-azacytidine selectively demethylated this area and increased perforin expression. Selective methylation of this region suppressed promoter function in transfection assays. Finally, perforin expression and hypomethylation were associated with localized sensitivity of the 5' flank to DNase I digestion, indicating an accessible configuration. These results indicate that DNA methylation and chromatin structure participate in the regulation of perforin expression in T cells.     

DNA methylation alters chromatin structure and regulates Thy-1 expression in EL-4 T cells

Thy-1 exhibits marked differences in expression in various tissues in many species; therefore, it is of interest to define possible mechanisms that may regulate Thy-1 expression. We produced Thy-1 negative variants of the murine T cell lymphoma EL-4 by mutagenesis with ethylmethanesulfonate (EMS), negative selection with anti-Thy-1 monoclonal antibodies (mAb) plus complement, and fluorescence-activated cell sorting (FACS). Thy-1 surface negative (Thy-1-) mutants produced in this manner were shown to produce no detectable Thy-1 mRNA, but contained an intact Thy-1 gene as determined by Southern blotting. 5' CG sequences, which had been demethylated in the parent EL-4 clone, were completely methylated in the EMS-induced Thy-1-variant. In addition, a DNase I hypersensitive site that mapped to the 5' end of the Thy-1 gene in EL-4 was absent in the Thy-1- variant. Treatment of this Thy-1- clone with 5-azadeoxycytidine (5-dAZA) resulted in re-expression of surface Thy-1, demethylation of the 5' CG sequences, and regeneration of the DNase I hypersensitive site. These studies indicate that methylation of certain critical DNA sequences in the 5' region of the Thy-1 gene can alter local chromatin structure and regulate expression of this gene.     

DNA methylation and chromatin structure: a view from below

An understanding of the function and control of DNA methylation in eukaryotes has been elusive. Studies of Neurospora crassa have led to a model that accounts for the chromosomal distribution of methylation and suggests a basic function for DNA methylation in eukaryotes.     

Overall DNA methylation and chromatin structure of normal and abnormal X chromosomes

DNA methylation patterns were studied at the chromosome level in normal and abnormal X chromosomes using an anti-5-methylcytosine antibody. In man, except for the late-replicating X of female cells, the labeled chromosome structures correspond to R- and T-bands and heterochromatin. Depending on the cell type, the species, and cell culture conditions, the late-replicating X in female cells appears to be more or less undermethylated. Under normal conditions, the only structures that remain methylated on the X chromosomes correspond to pseudoautosomal regions, which harbor active genes. Thus, active genes are usually hypomethylated but are located in methylated chromatin. Structural rearrangements of the X chromosome, such as t(X;X)(pter;pter), induce a Turner syndrome-like phenotype that is inconsistent with the resulting triple-X constitution. This suggests a position effect controlling gene inactivation. The derivative chromosomes are always late replicating, and their duplicated short arms, which harbor pseudoautosomal regions, replicate later than the normal late-replicating X chromosomes. The compaction or condensation of this segment is unusual, with a halo of chromatin surrounding a hypocondensed chromosome core. The chromosome core is hypomethylated, but the surrounding chromatin is slightly labeled. Thus, unusual DNA methylation and chromatin condensation are associated with the observed position effect. This strengthens the hypothesis that DNA methylation at the chromosome level is associated with both chromatin structure and gene expression.     

Developmental patterns of chromatin structure and DNA methylation responsible for epigenetic expression of a maize regulatory gene

Epigenetic regulatory mechanisms heritably alter patterns of gene expression without changes in DNA sequence. Epigenetic states are often correlated with developmentally imposed alterations in genomic DNA methylation and local chromatin structure. Pl-Blotched is a stable epigenetic allele of the maize anthocyanin regulatory gene, purple plant1(pl). Pl-Blotched plants display a variegated pattern of pigmentation that contrasts sharply with the uniformly dark purple pigmentation of plants carrying the dominant Pl-Rhoades allele. Previously, we showed that the lower level of pigmentation in Pl-Blotched is correlated with lower pl mRNA levels and increased DNA methylation at some sites. To explore how DNA methylation, chromatin structure, and developmental stage might contribute to the expression of Pl-Blotched, we used methylation-sensitive restriction enzymes and DNaseI sensitivity assays to compare the methylation status and chromatin structure of Pl-Blotched and Pl-Rhoades at different stages in development. Both alleles exhibit developmentally sensitive changes in methylation. In Pl-Blotched, methylation of two diagnostic HpaII/MspI sites increases progressively, coincident with the juvenile-to-adult transition in growth. In seedlings, the chromatin encompassing the coding region of the gene is less sensitive to DNaseI digestion in Pl-Blotched than in Pl-Rhoades. Developmental maturation from seedling to adult is accompanied by expansion of this closed chromatin domain to include the promoter and downstream flanking sequences. We provide evidence to show that chromatin structure, rather than DNA methylation, is the primary epigenetic determinant for the phenotypic differences between Pl-Blotched and Pl-Rhoades.     

Methods for analyzing the role of DNA methylation and chromatin structure in regulating T lymphocyte gene expression

Chromatin structure, determined in part by DNA methylation, is established during differentiation and prevents expression of genes unnecessary for the function of a given cell type. We reported that DNA methylation and chromatin structure contributes to lymphoidspecific ITGAL (CD11a) and PRF1 (perforin) expression. We used bisulfite sequencing to compare methylation patterns in the ITGAL promoter and 5′ flanking region of T cells and fibroblasts, and in the PRF1 promoter and upstream enhancer of CD4+ and CD8+ T cells with fibroblasts. The effects of methylation on promoter function were tested using regional methylation of reporter constructs, and confirmed by DNA methyltransferase inhibition. The relationship between DNA methylation and chromatin structure was analyzed by DNaseI hypersensitivity. Herein we described the methods and results in greater detail. Published: September 16, 2004.