Abstract
We present a comprehensive, experimental and theoretical study of the impact of 5-hydroxymethylation of DNA cytosine. Using molecular dynamics, biophysical experiments and NMR spectroscopy, we found that Ten-Eleven translocation (TET) dioxygenases generate an epigenetic variant with structural and physical properties similar to those of 5-methylcytosine. Experiments and simulations demonstrate that 5-methylcytosine (mC) and 5-hydroxymethylcytosine (hmC) generally lead to stiffer DNA than normal cytosine, with poorer circularization efficiencies and lower ability to form nucleosomes. In particular, we can rule out the hypothesis that hydroxymethylation reverts to unmodified cytosine physical properties, as hmC is even more rigid than mC. Thus, we do not expect dramatic changes in the chromatin structure induced by differences in physical properties between d(mCpG) and d(hmCpG). Conversely, our simulations suggest that methylated-DNA binding domains (MBDs), associated with repression activities, are sensitive to the substitution d(mCpG) ➔ d(hmCpG), while MBD3 which has a dual activation/repression activity is not sensitive to the d(mCpG) d(hmCpG) change. Overall, while gene activity changes due to cytosine methylation are the result of the combination of stiffness-related chromatin reorganization and MBD binding, those associated to 5-hydroxylation of methylcytosine could be explained by a change in the balance of repression/activation pathways related to differential MBD binding.
Highlights
unmodified 8mer and 12mer DNAs were purchased from Sigma Aldrich
hmdC-Modified 8mer and 12mer DNAs were synthesized on the 1 μmol scale using standard phosphoramidite methods
5-Hydroxymethyl-dCBz CE phosphoramidite was obtained from Glen Research
Summary
Melting Temperatures (Tm in oC) for the oligonucleotide CGAC*GTCG, where C* stands for cytosine (C), methylated-cytosine (mC) and hydroxymethylated-cytosine (hmC) respectively, calculated by UV experiments at different oligo concentrations. Enthalpy (∆H in Kcal/mol), entropy (∆S in cal/mol*K) and free energy ∆G (Kcal/mol), at 25 oC calculated using Van’t Hoff equation (see Methods) from UV data for the oligomer in Table S11 with cytosine, methylcytosine and hydroxymethycytosine respectively
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