Thermodynamic study of hybridization properties of heterochiral nucleic acids.

Heterochiral DNA and RNA heptamers, which contained an unnatural L-nucleotide, were synthesized, and thermodynamic analyses of their hybridization properties with complementary DNA and RNA strands were systematically conducted by UV melting experiments. The results clearly demonstrated that the incorporation of an L-ribonucleotide into the RNA strand leads to more significant destabilization of the duplexes than that of an L-deoxyribonucleotide into the DNA strand, regardless of whether the complementary strand is DNA or RNA. The destabilization of the duplexes by the substitution of D-thymidine with L-thymidine in the DNA strand is entropically driven, whereas that by the substitution of D-uridine with L-uridine in the RNA strand is enthalpically driven.

Characterization of DNA, RNA and DNA/RNA duplexes containing an L-nucleotide.

In order to investigate the duplex structure of DNA and RNA containing an L-nucleotide residue, we carried out the UV-melting and CD experiments. Although the introduction of an L-nucleotide into DNA/DNA, DNA/RNA and RNA/RNA duplexes reduced their Tm values, the typical two-state transitions were observed for all of the duplexes. The incorporation of an L-nucleotide into the RNA strand caused more remarkable decreases of the Tm value than that into the DNA strand.

A 2-deoxyribonolactone-containing nucleotide: isolation and characterization of the alkali-sensitive photoproduct of the trideoxyribonucleotide d(ApCpA).

It has been reported that ACA sequences in DNA are mutagenic hot spots in UV-induced mutagenesis and are sites of an alkali-sensitive lesion produced by UV irradiation. In order to characterize the UV-induced lesion of an ACA site, chemically synthesized trideoxyribonucleotide d(ApCpA) was irradiated with UV light and the alkali-sensitive photoproduct was isolated. The structure of this photoproduct was characterized as the trinucleotide containing 2-deoxyribonolactone at the internal residue by 2D DQF-COSY, FT-IR, FAB-MS, and chemical properties.