Can DNA-binding proteins of replisome tautomerize nucleotide bases? Ab initio model study

Atomistic understanding of the C·T mismatched DNA base pair tautomerization via the DPT: QM and QTAIM computational approaches

It was established that the cytosine·thymine (C·T) mismatched DNA base pair with cis-oriented N1H glycosidic bonds has propeller-like structure (|N3C4C4N3| = 38.4°), which is stabilized by three specific intermolecular interactions-two antiparallel N4H…O4 (5.19 kcal mol(-1)) and N3H…N3 (6.33 kcal mol(-1)) H-bonds and a van der Waals (vdW) contact O2…O2 (0.32 kcal mol(-1)). The C·T base mispair is thermodynamically stable structure (ΔG(int) = -1.54 kcal mol(-1) ) and even slightly more stable than the A·T Watson-Crick DNA base pair (ΔG(int) = -1.43 kcal mol(-1)) at the room temperature. It was shown that the C·T ↔ C*·T* tautomerization via the double proton transfer (DPT) is assisted by the O2…O2 vdW contact along the entire range of the intrinsic reaction coordinate (IRC). The positive value of the Grunenberg's compliance constants (31.186, 30.265, and 22.166 Å/mdyn for the C·T, C*·T*, and TS(C·T ↔ C*·T*), respectively) proves that the O2…O2 vdW contact is a stabilizing interaction. Based on the sweeps of the H-bond energies, it was found that the N4H…O4/O4H…N4, and N3H…N3 H-bonds in the C·T and C*·T* base pairs are anticooperative and weaken each other, whereas the middle N3H…N3 H-bond and the O2…O2 vdW contact are cooperative and mutually reinforce each other. It was found that the tautomerization of the C·T base mispair through the DPT is concerted and asynchronous reaction that proceeds via the TS(C·T ↔ C*·T*) stabilized by the loosened N4-H-O4 covalent bridge, N3H…N3 H-bond (9.67 kcal mol(-1) ) and O2…O2 vdW contact (0.41 kcal mol(-1) ). The nine key points, describing the evolution of the C·T ↔ C*·T* tautomerization via the DPT, were detected and completely investigated along the IRC. The C*·T* mispair was revealed to be the dynamically unstable structure with a lifetime 2.13·× 10(-13) s. In this case, as for the A·T Watson-Crick DNA base pair, activates the mechanism of the quantum protection of the C·T DNA base mispair from its spontaneous mutagenic tautomerization through the DPT.

The physico-chemical "anatomy" of the tautomerization through the DPT of the biologically important pairs of hypoxanthine with DNA bases: QM and QTAIM perspectives

The biologically important tautomerization of the Hyp·Cyt, Hyp·Thy and Hyp·Hyp base pairs to the Hyp·Cyt, Hyp·Thy and Hyp·Hyp base pairs, respectively, by the double proton transfer (DPT) was comprehensively studied in vacuo and in the continuum with a low dielectric constant (ε = 4) corresponding to hydrophobic interfaces of protein-nucleic acid interactions by combining theoretical investigations at the B3LYP/6-311++G(d,p) level of QM theory with QTAIM topological analysis. Based on the sweeps of the energetic, electron-topological, geometric and polar parameters, which describe the course of the tautomerization along the intrinsic reaction coordinate (IRC), it was proved that the tautomerization through the DPT is concerted and asynchronous process for the Hyp·Cyt and Hyp·Thy base pairs, while concerted and synchronous for the Hyp·Hyp homodimer. The continuum with ε = 4 does not affect qualitatively the course of the tautomerization reaction for all studied complexes. The nine key points along the IRC of the Hyp·Cyt↔Hyp·Cyt and Hyp·Thy↔Hyp·Thy tautomerizations and the six key points of the Hyp·Hyp↔Hyp·Hyp tautomerization have been identified and fully characterized. These key points could be considered as electron-topological "fingerprints" of concerted asynchronous (for Hyp·Cyt and Hyp·Thy) or synchronous (for Hyp·Hyp) tautomerization process via the DPT. It was found, that in the Hyp·Cyt, Hyp·Thy, Hyp·Hyp and Hyp·Hyp base pairs all H-bonds are significantly cooperative and mutually reinforce each other, while the C2H…O2 H-bond in the Hyp·Cyt base pair and the O6H…O4 H-bond in the Hyp·Thy base pair behave anti-cooperatively, i.e., they become weakened, while two others become strengthened.