Sp1 Regulates Chromatin Looping between an Intronic Enhancer and Distal Promoter of the Human Heme Oxygenase-1 Gene in Renal Cells

HO-1 (heme oxygenase-1) is an inducible microsomal enzyme that catalyzes the degradation of pro-oxidant heme. The goal of this study was to characterize a minimal enhancer region within the human HO-1 gene and delineate its role in modulating HO-1 expression by participation with its promoter elements in renal epithelial cells. Deletion analysis and site-directed mutagenesis identified a 220-bp minimal enhancer in intron 1 of the HO-1 gene, which regulates hemin-mediated HO-1 gene expression. Small interfering RNA, decoy oligonucleotides, site-directed mutagenesis, and chromatin immunoprecipitation assays confirmed the functional interaction of Sp1 with a consensus binding sequence within the 220-bp region. Mutations of regulatory elements within the −4.5 kb promoter region (a cyclic AMP response and a downstream NF-E2/AP-1 element, both located at −4.0 kb, and/or an E-box sequence located at −44 bp) resulted in the loss of enhancer activity. A chromosome conformation capture assay performed in human renal epithelial (HK-2) cells demonstrated hemin-inducible chromatin looping between the intronic enhancer and the −4.0 kb promoter region in a time-dependent manner. Restriction digestion with ApaLI (which cleaves the 220-bp enhancer) led to a loss of stimulus-dependent chromatin looping. Sp1 small interfering RNA and mithramycin A, a Sp1 binding site inhibitor, resulted in loss of the loop formation between the intronic enhancer and the distal HO-1 promoter by the chromosome conformation capture assay. These results provide novel insight into the complex molecular interactions that underlie human HO-1 regulation in renal epithelial cells.     

MLH1 Region Polymorphisms Show a Significant Association with CpG Island Shore Methylation in a Large Cohort of Healthy Individuals

Single nucleotide polymorphisms (SNPs) are the most common form of genetic variation. We previously demonstrated that SNPs (rs1800734, rs749072, and rs13098279) in the MLH1 gene region are associated with MLH1 promoter island methylation, loss of MLH1 protein expression, and microsatellite instability (MSI) in colorectal cancer (CRC) patients. Recent studies have identified less CpG-dense “shore” regions flanking many CpG islands. These shores often exhibit distinct methylation profiles between different tissues and matched normal versus tumor cells of patients. To date, most epigenetic studies have focused on somatic methylation events occurring within solid tumors; less is known of the contributions of peripheral blood cell (PBC) methylation to processes such as aging and tumorigenesis. To address whether MLH1 methylation in PBCs is correlated with tumorigenesis we utilized the Illumina 450 K microarrays to measure methylation in PBC DNA of 846 healthy controls and 252 CRC patients from Ontario, Canada. Analysis of a region of chromosome 3p21 spanning the MLH1 locus in healthy controls revealed that a CpG island shore 1 kb upstream of the MLH1 gene exhibits different methylation profiles when stratified by SNP genotypes (rs1800734, rs749072, and rs13098279). Individuals with wild-type genotypes incur significantly higher PBC shore methylation than heterozygous or homozygous variant carriers (p<1.1×10⁻⁶; ANOVA). This trend is also seen in CRC cases (p<0.096; ANOVA). Shore methylation also decreases significantly with increasing age in cases and controls. This is the first study of its kind to integrate PBC methylation at a CpG island shore with SNP genotype status in CRC cases and controls. These results indicate that CpG island shore methylation in PBCs may be influenced by genotype as well as the normal aging process.     

Increased P16 DNA Methylation in Mouse Thymic Lymphoma Induced by Irradiation

DNA methylation is an important part of epigenetics. In this study, we examined the methylation state of two CpG islands in the promoter of the p16 gene in radiation-induced thymic lymphoma samples. The mRNA and protein levels of P16 were significantly reduced in radiation-induced thymic lymphoma tissue samples. Twenty-three CpG sites of the CpG islands in the p16 promoter region were detected, and the methylation percentages of −71, −63, −239, −29, −38, −40, −23, 46 CpG sites were significantly higher in radiation-induced thymic lymphoma tissue samples than those in matched non-irradiated thymus tissue samples. This study provides new evidence for the methylation state of p16 in the radiation-induced thymic lymphoma samples, which suggests that the methylation of these CpG sites in the p16 promoter may reduce its expression in the thymic lymphoma after irradiation.