Fluorescence energy transfer monitored competitive equilibria of nucleic acids: applications in thermodynamics and screening.

Precise thermodynamic characterization of nucleic acid complex stability is required to understand a variety of biologically significant events as well as to exploit the specific recognition capabilities of nucleic acids in biotechnology, diagnostics, and therapeutics. The development of a database of nucleic acid thermodynamics with sufficient precision to foster further developments in these areas requires new and improved measurement techniques. The combination of a competitive equilibrium titration with fluorescence energy transfer based detection provides a method for precise measurement of differences in free energy values for nucleic acid duplexes that far exceeds in precision those accessible via conventional methods. The method can be applied to detect and to characterize any deviation in a nucleic acid that alters duplex stability. Such deviations include, but are not limited to, mismatches; single nucleotide polymorphisms (SNP); chemically modified nucleotide bases, sugars or phosphates; and conformational anomalies or folding motifs, such as, loops or hairpins.