Bernard W Futscher

PMID: 21873453;PMCID: PMC3227093;Abstract:

Epigenetic mechanisms are important regulators of cell type-specific genes, including miRNAs. In order to identify cell type-specific miRNAs regulated by epigenetic mechanisms, we undertook a global analysis of miRNA expression and epigenetic states in three isogenic pairs of human mammary epithelial cells (HMEC) and human mammary fibroblasts (HMF), which represent two differentiated cell types typically present within a given organ, each with a distinct phenotype and a distinct epigenotype. While miRNA expression and epigenetic states showed strong interindividual concordance within a given cell type, almost 10% of the expressed miRNA showed a cell type-specific pattern of expression that was linked to the epigenetic state of their promoter. The tissue-specific miRNA genes were epigenetically repressed in nonexpressing cells by DNA methylation (38%) and H3K27me3 (58%), with only a small set of miRNAs (21%) showing a dual epigenetic repression where both DNA methylation and H3K27me3 were present at their promoters, such as MIR10A and MIR10B. Individual miRNA clusters of closely related miRNA gene families can each display cell type-specific repression by the same or complementary epigenetic mechanisms, such as the MIR200 family, and MIR205, where fibroblasts repress MIR200C/141 by DNA methylation, MIR200A/200B/429 by H3K27me3, and MIR205 by both DNA methylation and H3K27me3. Since deregulation of many of the epigenetically regulated miRNAs that we identified have been linked to disease processes such as cancer, it is predicted that compromise of the epigenetic control mechanisms is important for this process. Overall, these results highlight the importance of epigenetic regulation in the control of normal cell type-specific miRNA expression. © 2011 by Cold Spring Harbor Laboratory Press.

PMID: 1548483;Abstract:

Although immediate cholinergic deficits produced by AF64A can be explained adequately by inhibition of enzymes involved in acetylcholine metabolism, the structural similarity of AF64A to a number of DNA-damaging antitumor agents suggested that the observed long-term cholinergic deficits may involve damage to the cell's informational molecules. This study was initiated to determine if AF64A can damage DNA and prematurely terminate RNA transcription in vitro, and to produce cytotoxic and DNA damaging effects in cells exposed to the drug in vivo. The ability of AF64A to produce N-7 guanine alkylations in DNA in vitro was assessed using a modified Maxam and Gilbert DNA sequencing technique, and the ability of AF64A to terminate RNA transcription was assessed by an in vitro RNA transcription system. AF64A was capable of producing extensive dose-dependent N-7 guanine alkylations in DNA fragments exposed to AF64A in vitro, although no sequence specificity of AF64A attack could be discerned. Furthermore, AF64A was able to produce RNA transcription-terminating lesions in vitro, also in a dose-dependent fashion. Transcription of AF64A-damaged DNA resulted in RNA molecules terminated not at every alkylated guanine, but at various discrete sites along the DNA template. AF64A was also found to be cytotoxic in a dose-dependent manner in cultured mouse leukemia L1210 cells. The induced cytotoxicity was accompanied by DNA lesions which were detected as DNA single strand breaks using the DNA alkaline elution technique. The results of these experiments support the hypothesis that AF64A may alter the structure and function of cellular DNA and may help explain the observed long-term cholinergic deficits.

PMID: 24024150;PMCID: PMC3757676;Abstract:

Manganese superoxide dismutase, encoded by the Sod2 gene, is a ubiquitously expressed mitochondrial antioxidant enzyme that is essential for mammalian life. Mice born with constitutive genetic knockout of Sod2 do not survive the neonatal stage, which renders the longitudinal study of the biochemical and metabolic effects of Sod2 loss difficult. However, multiple studies have demonstrated that tissue-specific knockout of Sod2 in murine liver yields no observable gross pathology or injury to the mouse. We hypothesized that Sod2 loss may have sub-pathologic effects on liver biology, including the acquisition of reactive oxygen species-mediated mitochondrial DNA mutations. To evaluate this, we established and verified a hepatocyte-specific knockout of Sod2 in C57/B6 mice using Cre-LoxP recombination technology. We utilized deep sequencing to identify possible mutations in Sod2 mitochondrial DNA as compared to wt, and both RT-PCR and traditional biochemical assays to evaluate baseline differences in redox-sensitive pathways in Sod2^-/- hepatocytes. Surprisingly, no mutations in Sod2^-/- mitochondrial DNA were detected despite measurable increases in dihydroethidium staining in situ and concomitant decreases in complex II activity indicative of elevated superoxide in the Sod2^-/- hepatocytes. In contrast, numerous compensatory alterations in gene expression were identified that suggest hepatocytes havea remarkable capacity to adapt and overcome the loss of Sod2 through transcriptional means. Taken together, these results suggest that murine hepatocytes have a large reserve capacity to cope with the presence of additional mitochondrial reactive oxygen species. © 2013 The Authors.