posted on 2012-08-07, 00:00authored byYasumasa Kimura, Takeshi Hanami, Yuki Tanaka, Michiel J. L. de Hoon, Takahiro Soma, Matthias Harbers, Alexander Lezhava, Yoshihide Hayashizaki, Kengo Usui
Nucleic acid oligonucleotides are widely used in hybridization
experiments for specific detection of complementary nucleic acid sequences.
For design and application of oligonucleotides, an understanding of
their thermodynamic properties is essential. Recently, exciton-controlled
hybridization-sensitive fluorescent oligonucleotides (ECHOs) were
developed as uniquely labeled DNA oligomers containing commonly one
thymidine having two covalently linked thiazole orange dye moieties.
The fluorescent signal of an ECHO is strictly hybridization-controlled,
where the dye moieties have to intercalate into double-stranded DNA
for signal generation. Here we analyzed the hybridization thermodynamics
of ECHO/DNA duplexes, and thermodynamic parameters were obtained from
melting curves of 64 ECHO/DNA duplexes measured by ultraviolet absorbance
and fluorescence. Both methods demonstrated a substantial increase
in duplex stability (ΔΔG°37 ∼ −2.6 ± 0.7 kcal mol–1) compared
to that of DNA/DNA duplexes of the same sequence. With the exception
of T·G mismatches, this increased stability was mostly unaffected
by other mismatches in the position opposite the labeled nucleotide.
A nearest neighbor model was constructed for predicting thermodynamic
parameters for duplex stability. Evaluation of the nearest neighbor
parameters by cross validation tests showed higher predictive reliability
for the fluorescence-based than the absorbance-based parameters. Using
our experimental data, a tool for predicting the thermodynamics of
formation of ECHO/DNA duplexes was developed that is freely available
at http://genome.gsc.riken.jp/echo/thermodynamics/. It
provides reliable thermodynamic data for using the unique features
of ECHOs in fluorescence-based experiments.