Shelley E. Brown

Quantum dot-induced epigenetic and genotoxic changes in human breast cancer cells

The staggering array of nanotechnological products, found in our environment and those applicable in medicine, has stimulated a growing interest in examining their long-term impact on genetic and epigenetic processes. We examined here the epigenomic and genotoxic response to cadmium telluride quantum dots (QDs) in human breast carcinoma cells. QD treatment induced global hypoacetylation implying a global epigenomic response. The ubiquitous responder to genotoxic stress, p53, was activated by QD challenge resulting in translocation of p53, with subsequent upregulation of downstream targets Puma and Noxa. Consequential decrease in cell viability was in part prevented by the p53 inhibitor pifithrin-α, suggesting that p53 translocation contributes to QD-induced cytotoxicity. These findings suggest three levels of nanoparticle-induced cellular changes: non-genomic, genomic and epigenetic. Epigenetic changes may have long-term effects on gene expression programming long after the initial signal has been removed, and if these changes remain undetected, it could lead to long-term untoward effects in biological systems. These studies suggest that aside from genotoxic effects, nanoparticles could cause more subtle epigenetic changes which merit thorough examination of environmental nanoparticles and novel candidate nanomaterials for medical applications.

Reversal of maternal programming of stress responses in adult offspring through methyl supplementation: altering epigenetic marking later in life.

Stress responses in the adult rat are programmed early in life by maternal care and associated with epigenomic marking of the hippocampal exon 17 glucocorticoid receptor (GR) promoter. To examine whether such epigenetic programming is reversible in adult life, we centrally infused the adult offspring with the essential amino acid l-methionine, a precursor to S-adenosyl-methionine that serves as the donor of methyl groups for DNA methylation. Here we report that methionine infusion reverses the effect of maternal behavior on DNA methylation, nerve growth factor-inducible protein-A binding to the exon 17 promoter, GR expression, and hypothalamic-pituitary-adrenal and behavioral responses to stress, suggesting a causal relationship among epigenomic state, GR expression, and stress responses in the adult offspring. These results demonstrate that, despite the inherent stability of the epigenomic marks established early in life through behavioral programming, they are potentially reversible in the adult brain.

The Transcription Factor Nerve Growth Factor-Inducible Protein A Mediates Epigenetic Programming: Altering Epigenetic Marks by Immediate-Early Genes

Maternal care alters epigenetic programming of glucocorticoid receptor (GR) gene expression in the hippocampus, and increased postnatal maternal licking/grooming (LG) behavior enhances nerve growth factor-inducible protein A (NGFI-A) transcription factor binding to the exon 17 GR promoter within the hippocampus of the offspring. We tested the hypothesis that NGFI-A binding to the exon 17 GR promoter sequence marks this sequence for histone acetylation and DNA demethylation and that such epigenetic alterations subsequently influence NGFI-A binding and GR transcription. We report that (1) NGFI-A binding to its consensus sequence is inhibited by DNA methylation, (2) NGFI-A induces the activity of exon 17 GR promoter in a transient reporter assay, (3) DNA methylation inhibits exon 17 GR promoter activity, and (4) whereas NGFI-A interaction with the methylated exon 17 GR promoter is reduced, NGFI-A overexpression induces histone acetylation, DNA demethylation, and activation of the exon 17 GR promoter in transient transfection assays. Site-directed mutagenesis assays demonstrate that NGFI-A binding to the exon 17 GR promoter is required for such epigenetic reprogramming. In vivo, enhanced maternal LG is associated with increased NGFI-A binding to the exon 17 GR promoter in the hippocampus of pups, and NGFI-A-bound exon 17 GR promoter is unmethylated compared with unbound exon 17 GR promoter. Knockdown experiments of NGFI-A in hippocampal primary cell culture show that NGFI-A is required for serotonin-induced DNA demethylation and increased exon 17 GR promoter expression. The data are consistent with the hypothesis that NGFI-A participates in epigenetic programming of GR expression.

DNA methyltransferase 1 knock down induces gene expression by a mechanism independent of DNA methylation and histone deacetylation.

DNA methyltransferase 1 (DNMT1) catalyzes the post-replication methylation of DNA and is responsible for maintaining the DNA methylation pattern during cell division. A long list of data supports a role for DNMT1 in cellular transformation and inhibitors of DNMT1 were shown to have antitumorigenic effects. It was long believed that DNMT1 promoted tumorigenesis by maintaining the hypermethylated and silenced state of tumor suppressor genes. We have previously shown that DNMT1 knock down by either antisense oligonucleotides directed at DNMT1 or expressed antisense activates a number of genes involved in stress response and cell cycle arrest by a DNA methylation-independent mechanism. In this report we demonstrate that antisense knock down of DNMT1 in human lung carcinoma A549 and embryonal kidney HEK293 cells induces gene expression by a mechanism that does not involve either of the known epigenomic mechanisms, DNA methylation, histone acetylation, or histone methylation. The mechanism of activation of the cell cycle inhibitor p21 and apoptosis inducer BIK by DNMT1 inhibition is independent of the mechanism of activation of the same genes by histone deacetylase inhibition. We determine whether DNMT1 knock down activates one of the nodal transcription activation pathways in the cell and demonstrate that DNMT1 activates Sp1 response elements. This activation of Sp1 response does not involve an increase in either Sp1 or Sp3 protein levels in the cell or the occupancy of the Sp1 elements with these proteins. The methylation-independent regulation of Sp1 elements by DNMT1 unravels a novel function for DNMT1 in gene regulation. DNA methylation was believed to be a mechanism for suppression of CG-rich Sp1-bearing promoters. Our data suggest a fundamentally different and surprising role for DNMT1 regulation of CG-rich genes by a mechanism independent of DNA methylation and histone acetylation. The implications of our data on the biological roles of DNMT1 and the therapeutic potential of DNMT1 inhibitors as anticancer agents are discussed.

Regional-specific global cytosine methylation and DNA methyltransferase expression in the adult rat hippocampus.

Recent observations suggest that DNA methylation plays an important role in memory and long-term potentiation (LTP) in the hippocampus and is involved in programming the offspring epigenome in response to maternal care. Global DNA methylation is believed to be stable postnatally and to be similar across tissues in the adult mammal. It has also been a long held belief that DNA methyltransferases (DNMTs) play a very limited role in postmitotic tissues. Recent data suggests a more dynamic role for DNA methylation in the brain postnatally, therefore we examined the global state of methylation and the expression of the known DNMTs in the different regions of the hippocampus. We observed strikingly different levels of global methylation in the adult rat dentate gyrus (DG) and CA1 region in comparison with the CA2 and CA3 regions. mRNA levels of DNA methyltransferases exhibited similar regional specificity and were correlated with global DNA methylation levels. These regional differences in global methylation and expression of the DNA methylation machinery in the adult brain are consistent with the emerging hypothesis that DNA methylation may play a dynamic physiological role in the adult brain.

Epigenetic Programming of the rRNA Promoter by MBD3

Within the human genome there are hundreds of copies of the rRNA gene, but only a fraction of these genes are active. Silencing through epigenetics has been extensively studied; however, it is essential to understand how active rRNA genes are maintained. Here, we propose a role for the methyl-CpG binding domain protein MBD3 in epigenetically maintaining active rRNA promoters. We show that MBD3 is localized to the nucleolus, colocalizes with upstream binding factor, and binds to unmethylated rRNA promoters. Knockdown of MBD3 by small interfering RNA results in increased methylation of the rRNA promoter coupled with a decrease in RNA polymerase I binding and pre-rRNA transcription. Conversely, overexpression of MBD3 results in decreased methylation of the rRNA promoter. Additionally, overexpression of MBD3 induces demethylation of nonreplicating plasmids containing the rRNA promoter. We demonstrate that this demethylation occurs following the overexpression of MBD3 and its increased interaction with the methylated rRNA promoter. This is the first demonstration that MBD3 is involved in inducing and maintaining the demethylated state of a specific promoter.

Variations in DNA Methylation Patterns During the Cell Cycle of HeLa Cells

DNA methylation has been viewed as a stable component of the epigenome, which is established during development and fixed thereafter. We show here using nearest neighbor analysis, immunocytochemistry, and high performance capillary electrophoresis that the DNA methylation pattern varies in HeLa cells during a single cell cycle. Immunocytochemical analysis in primary human fibroblasts shows similar variations. The global levels of DNA methylation decreased in G1 and increase during the S phase of the cell cycle. Since there was little change in the DNA methylation levels in repetitive sequences throughout the cell cycle, we examined the DNA methylation pattern of unique sequences using a human CpG island microarray. Hybridization with methylated DNA from G1 and S phase of the cell cycle revealed that 174 CG-containing sequences were differentially methylated between G1 and S. 75% of all the variations in DNA methylation detected in unique sequences represented hypomethylation at G0, with changes occurring in both CpG islands and non-CpG islands. Bisulfite mapping confirmed these changes in methylation in the regions identified by the microarray. This is the first demonstration of a dynamic DNA methylation pattern within a single cell cycle of a mature somatic cell. These data are important for our understanding of the stability of DNA methylation patterns in somatic cells.

The methylated-DNA binding protein MBD2 enhances NGFI-A (egr-1)-mediated transcriptional activation of the glucocorticoid receptor

Variations in maternal care in the rat influence the epigenetic state and transcriptional activity of glucocorticoid receptor (GR) gene in the hippocampus. The mechanisms underlying this maternal effect remained to be defined, including the nature of the relevant maternally regulated intracellular signalling pathways. We show here that increased maternal licking/grooming (LG), which stably enhances hippocampal GR expression, paradoxically increases hippocampal expression of the methyl-CpG binding domain protein-2 (MBD2) and MBD2 binding to the exon 17 GR promoter. Knockdown experiments of MBD2 in hippocampal primary cell culture show that MBD2 is required for activation of exon 17 GR promoter. Ectopic co-expression of nerve growth factor-inducible protein A (NGFI-A) with MBD2 in HEK 293 cells with site-directed mutagenesis of the NGFI-A response element within the methylated exon 17 GR promoter supports the hypothesis that MBD2 collaborates with NGFI-A in binding and activation of this promoter. These data suggest a possible mechanism linking signalling pathways, which are activated by behavioural stimuli and activation of target genes.

DNA demethylation induced by the methyl-CpG-binding domain protein MBD3.

The methyl-CpG binding domain protein MBD3 has been shown to be essential for embryonic development and differentiation, and to act by suppressing gene expression through the recruitment of co-repressor complexes. We have recently shown that MBD3 is also involved in maintaining the demethylated and active state of rRNA genes, and that depletion of MBD3 results in hypermethylation of rRNA promoters. The possibility that MBD3 could also trigger DNA demethylation of RNA polymerase II-transcribed genes has not been addressed. In this study we used a gain-of-function approach to examine whether MBD3 expression alters DNA methylation states in a living cell and whether it has specific targets for DNA methylation or demethylation in the genome. We used a combination of methylated DNA immunoprecipitation (mDIP) and hybridization to a human promoter tiling microarray to examine the landscape of DNA methylation patterns in response to MBD3 overexpression. We demonstrate that MBD3 induces genomic DNA demethylation and that it has specific targets in the genome with which it associates. Demethylation is localized to promoter regions with intermediate CpG density, and promoters with predicted transcription factor binding sites for NF-Y were significantly affected. These data demonstrate a causal relationship between MBD3 and DNA demethylation of genomic targets in cells.

Dynamic epigenetic states of ribosomal RNA promoters during the cell cycle.

It has previously been shown that the ribosomal RNA promoter is regulated through epigenetic mechanisms. It is unclear however whether epigenetic marks are stable in somatic cells or whether and how they vary with cell cycle dynamics. Here we present an analysis of epigenetic marks in cells positioned at different phases of the cell cycle following synchronization using a double thymidine block. We show that the levels of acetylated histone 4 are highest in early S phase, coinciding with the peak of binding of the transcriptional activators UBF and MBD3 to the ribosomal RNA promoter. Additionally, binding of the DNA methyltransferase DNMT1 is highest during mid-S phase, while DNMT3B binding peaks later in G2. Bisulfite mapping of the ribosomal RNA promoter reveals that the DNA methylation state varies during the cell cycle being lowest during early and late S phase. Interestingly, although the interaction of RNA polymerase I with the promoter and its progress along the gene coincides with epigenetic activation, the burst in levels of rRNA transcript did not occur until after DNA synthesis was complete. This suggests that although the rRNA promoter is poised for transcription early in the cell cycle, the accumulation of rRNA transcripts requires additional signals later in the cell cycle. This data is consistent with the idea that epigenetic states are dynamic in somatic cells and might participate in physiological cellular responses.