Abstract
Methylated cytosine within CpG dinucleotides is a key factor for epigenetic gene regulation. It has been revealed that methylated cytosine decreases DNA backbone flexibility and increases the thermal stability of DNA. Although the molecular environment is an important factor for the structure, thermodynamics, and function of biomolecules, there are few reports on the effects of methylated cytosine under a cell-mimicking molecular environment. Here, we systematically investigated the effects of methylated cytosine on the thermodynamics of DNA duplexes under molecular crowding conditions, which is a critical difference between the molecular environment in cells and test tubes. Thermodynamic parameters quantitatively demonstrated that the methylation effect and molecular crowding effect on DNA duplexes are independent and additive, in which the degree of the stabilization is the sum of the methylation effect and molecular crowding effect. Furthermore, the effects of methylation and molecular crowding correlate with the hydration states of DNA duplexes. The stabilization effect of methylation was due to the favorable enthalpic contribution, suggesting that direct interactions of the methyl group with adjacent bases and adjacent methyl groups play a role in determining the flexibility and thermodynamics of DNA duplexes. These results are useful to predict the properties of DNA duplexes with methylation in cell-mimicking conditions.
Highlights
The covalent addition of a methyl group to the 5-position of the cytosine ring within aCpG dinucleotide is an epigenetic modification of DNA that is vital for cellular development [1,2,3]
Thermodynamic parameters as well as circular dichroism (CD) spectra demonstrated that the effects of methylation and molecular crowding are independent and additive
We examined the thermodynamics of DNA oligonucleotides with various numbers of methylation under dilute and cell-mimicking molecular crowding conditions with different cosolutes
Summary
The covalent addition of a methyl group to the 5-position of the cytosine ring within aCpG dinucleotide is an epigenetic modification of DNA that is vital for cellular development [1,2,3]. Next-generation sequencing of the methylome for the whole genome has identified methylation in non-CpG contexts (mCH, where H=A, C, or T) in stem cells, oocytes, and neurons of mammals [7,8,9,10,11,12,13]. It is generally considered that methylated cytosine represses gene expression by binding with methylation binding proteins, resulting in the blocking of transcription factors [21,22,23]. The specific binding of methylation binding proteins to methylated DNA is critical for the epigenetic gene regulation system. The effects of methylated cytosine on the DNA structure and its stability and dynamics in living cells are important for understanding epigenetic mechanisms, and for developing tailored epigenetic therapies that target cancer and neurodegeneration
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