Putative DNA modification methylase DR_C0020 of Deinococcus radiodurans is an atypical SAM dependent C-5 cytosine DNA methylase.

BACKGROUND: Control of cellular processes by epigenetic modification of cytosine in DNA is widespread among living organisms, but, is hitherto unknown in the extremely radioresistant microbe D. radiodurans. METHODS: C-5 methyl cytosines (m5C) were detected by immuno-blotting with m5C-specific antibody. Site of cytosine methylation by DR_C0020 encoded protein was investigated by bisulfite sequencing. The DR_C0020 knockout mutant (Δdcm), constructed by site directed mutagenesis, was assessed for effect on growth, radiation resistance and proteome. Proteins were identified by mass spectrometry. RESULTS: Methylated cytosines were detected in the D. radiodurans genome. The DR_C0020 encoded protein (Dcm, NCBI accession: WP_034351354.1), whose amino acid sequence resembles m4C methylases, was shown to be the lone SAM-dependent C-5 cytosine methyltransferase. Purified Dcm protein was found to methylate CpN sequence with a preference for methylation of two consecutive cytosines. The Δdcm strain completely lost m5C modification from its genome, had no effect on growth but became radiation sensitive. The Δdcm cells exhibited minor alterations in the abundance of several proteins involved primarily in protein homeostasis, oxidative stress defense, metabolism, etc. CONCLUSION: DR_C0020 encoded SAM-dependent methyltransferase Dcm is solely responsible for C-5cytosine methylation at CpN sites in the genome of D. radiodurans and regulates protein homeostasis under normal growth conditions. The protein is an unusual case of an amino methyltransferase that has evolved to producing m5C. GENERAL SIGNIFICANCE: Although, dispensable under optimal growth conditions, the presence of m5C may be important for recognition of parent strand and, thus, could contribute to the extraordinary DNA repair in D. radiodurans.

Epigenetic modulation upon exposure of lung fibroblasts to TiO2 and ZnO nanoparticles: alterations in DNA methylation.

Titanium dioxide (TiO2) and zinc oxide (ZnO) nanoparticles (NPs) are promising candidates for numerous applications in consumer products. This will lead to increased human exposure, thus posing a threat to human health. Both these types of NPs have been studied for their cell toxicity, immunotoxicity, and genotoxicity. However, effects of these NPs on epigenetic modulations have not been studied. Epigenetics is an important link in the genotype and phenotype modulation and misregulation can often lead to lifestyle diseases. In this study, we have evaluated the DNA methylation-based epigenetic changes upon exposure to various concentrations of NPs. The investigation was designed to evaluate global DNA methylation, estimating the corresponding methyltransferase activity and expression of Dnmt gene using lung fibroblast (MRC5) cell line as lungs are the primary route of entry and target of occupational exposure to TiO2 and ZnO NPs. Enzyme-linked immunosorbent assay-based immunochemical assay revealed dose-related decrease in global DNA methylation and DNA methyltransferase activity. We also found direct correlation between the concentration of NPs, global methylation levels, and expression levels of Dnmt1, 3A, and 3B genes upon exposure. This is the first study to investigate effect of exposure to TiO2 and ZnO on DNA methylation levels in MRC5 cells. Epigenetic processes are known to play an important role in reprogramming and adaptation ability of an organism and can have long-term consequences. We suggest that changes in DNA methylation can serve as good biomarkers for early exposure to NPs since they occur at concentrations well below the sublethal levels. Our results demonstrate a clear epigenetic alteration in response to metal oxide NPs and that this effect was dose-dependent.