Open AccessMetal-assisted proton transfer reaction in base pairs
Author(s) -
Toru Matsui,
Yasuteru Shigeta,
Kimihiko Hirao
Publication year - 2007
Publication title -
nucleic acids symposium series
Language(s) - Uncategorized
Resource type - Journals
eISSN - 1746-8272
pISSN - 0261-3166
DOI - 10.1093/nass/nrm113
Subject(s) - proton , chemistry , metal , base (topology) , crystallography , ligand (biochemistry) , proton coupled electron transfer , stereochemistry , computational chemistry , electron transfer , physics , organic chemistry , mathematical analysis , biochemistry , receptor , mathematics , quantum mechanics
We investigated the proton-transfer reactions in guanine-cytosine (GC) pairs with density functional theories. In the GC pair bound to cis-platin, the barrier height of proton-transfer reaction dramatically decreases in comparison with the GC pair without the cis-platin. This is because (a) successive processes of charge transfer from G to cisplatin thereby stabilizing both the GC and G*C pairs and (b) an additional hydrogen bond between G and the ligand of Pt atom. In two GC pairs bound to the cis-platin, the single proton-transfer reaction occurs in one of the two GC pairs. No simultaneous single proton-transfer reaction can occur in both base pairs. From the geometry optimization, two different single proton-transferred structures (cis-(CG*)d-Pt-(GC)p and cis-(CG)d-Pt-(G*C)p, where * means a proton donor of G) are as stable as the original structures (CG)d-Pt-(GC)p.
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