Silver(I)-Ion-Mediated Cytosine-Containing Base Pairs: Metal Ion Specificity for Duplex Stabilization and Susceptibility toward DNA Polymerases.

Spectroscopic characterization of AgI -ion-mediated C-AgI -A and C-AgI -T base pairs found in primer extension reactions catalyzed by DNA polymerases was conducted. UV melting experiments revealed that C-A and C-T mismatched base pairs in oligodeoxynucleotide duplexes are specifically stabilized by AgI ions in 1:1 stoichiometry in the same manner as a C-C mismatched base pair. Although the stability of the mismatched base pairs in the absence of AgI ions is in the order C-A≈C-T>C-C, the stabilizing effect of AgI ions follows the order C-C>C-A≈C-T. However, the comparative susceptibility of dNTPs to AgI -mediated enzymatic incorporation into the site opposite templating C is dATP>dTTP≫dCTP, as reported. The net charge, as well as the size and/or shape complementarity of the metal-mediated base pairs, or the stabilities of mismatched base pairs in the absence of metal ions, would be more important than the stability of the metallo-base pairs in the replicating reaction catalyzed by DNA polymerases.

Regulated incorporation of two different metal ions into programmed sites in a duplex by DNA polymerase catalyzed primer extension.

Metal-mediated base pairs formed by the coordination of metal ions to natural or artificial bases impart unique chemical and physical properties to nucleic acids and have attracted considerable interest in the field of nanodevices. Ag(I) ions were found to mediate DNA polymerase catalyzed primer extension through the formation of a C-Ag(I)-T base pair, as well as the previously reported C-Ag(I)-A base pair. The comparative susceptibility of dNTPs to Ag(I)-mediated enzymatic incorporation into the site opposite cytosine in the template was shown to be dATP>dTTP≫dCTP. Furthermore, two kinds of metal ions, Ag(I) and Hg(II), selectively mediate the incorporation of thymidine 5'-triphosphate into sites opposite cytosine and thymine in the template, respectively. In other words, the regulated incorporation of different metal ions into programmed sites in the duplex by DNA polymerase was successfully achieved.

Ag(I) ion mediated formation of a C-A mispair by DNA polymerases.

Silver turns up the A-C: In the presence of Ag(I) ions, a DNA polymerase incorporated deoxyadenosine (from dATP) at the site opposite cytosine in the template strand to afford the full-length product (see scheme), meaning that DNA polymerases prefer a C-Ag(I)-A base pair to the more thermodynamically stable C-Ag(I)-C base pair.

Enzymatic formation of consecutive thymine-HgII-thymine base pairs by DNA polymerases.

From the perspective of the preparation of a DNA-based nanowire containing an array of metal ions, DNA-polymerase-catalyzed primer extension reactions were investigated and the formation of up to ten consecutive T-HgII-T base pairs was achieved by the HgII-mediated primer extension reaction in the presence of MnII ions. This enzymatic approach may be one of the promising techniques for preparing a DNA-based metal array.

Effects of metal ions on thermal stabilities of DNA duplexes containing homo- and heterochiral mismatched base pairs: comparison of internal and terminal substitutions.

The effects of metal ions on the stabilities of duplexes containing a D-homochiral and heterochiral mismatched base pairs were studied. In some duplexes containing an internal mismatched base pair, significant stabilization by HgII and AgI ions was observed. While, in duplexes containing a terminal mismatched base pair, only the duplexes containing T-T and LT-T mispairs were significantly stabilized by HgII ions, and the stabilities of the duplexes containing T-T and LT-T mispairs exceeded those of the corresponding homochiral matched duplex. The results suggest that the formation of homo- and heterochiral T-HgII-T base pairs at duplex termini would be useful for the thermal and enzymatic stabilization of DNA-based nanodevice.