posted on 2016-08-10, 00:00authored byLize Deferme, Jarno E. J. Wolters, Sandra M. H. Claessen, Daniel H. J. Theunissen, Twan van den Beucken, J. Richard Wagner, Simone G. van Breda, Jos C. S. Kleinjans, Jacco J. Briedé
In recent years, it has been shown
that free radicals not only
react directly with DNA but also regulate epigenetic processes such
as DNA methylation, which may be relevant within the context of, for
example, tumorigenesis. However, how these free radicals impact the
epigenome remains unclear. We therefore investigated whether methyl
and hydroxyl radicals, formed by tert-butyl hydroperoxide
(TBH), change temporal DNA methylation patterns and how this interferes
with genome-wide gene expression. At three time points, TBH-induced
radicals in HepG2 cells were identified by electron spin resonance
spectroscopy. Total 5-methylcytosine (5mC) levels were determined
by liquid chromatography and tandem mass spectrometry and genome-wide
changes in 5mC and gene expression by microarrays. Induced methylome
changes rather represent an adaptive response to the oxidative stress-related
reactions observed in the transcriptome. More specifically, we found
that methyl radicals did not induce DNA methylation directly. An initial
oxidative and alkylating stress-related response of the transcriptome
during the early phase of TBH treatment was followed by an epigenetic
response associated with cell survival signaling. Also, we identified
genes of which the expression seems directly regulated by DNA methylation.
This work suggests an important role of the methylome in counter-regulating
primary oxidative and alkylating stress responses in the transcriptome
to restore normal cell function. Altogether, the methylome may play
an important role in counter-regulating primary oxidative and alkylating
stress responses in the transcriptome presumably to restore normal
cell function.