DNA recognition by lexitropsins, minor groove binding agents.

Consideration is given to alternative approaches to the development of DNA sequence selective binding agents because of their potential applications in diagnosis and treatment of cancer as well as in molecular biology. The concept of lexitropsins, or information-reading molecules, is introduced within the antigene strategy as an alternative to, and complementary with, the antisense approach for cellular intervention and gene control. The chemical, physical and pharmacological factors involved in the design of effective lexitropsins are discussed and illustrated with experimental results. Among the factors contributing to the molecular recognition processes are: the presence and disposition of hydrogen bond accepting and donating groups, ligand shape, chirality, stereochemistry, flexibility and charge. For longer ligands, such as are required to target unique sequences in biological systems (14-16 base pairs), the critical feature is the phasing or spatial correspondence between repeat units in the ligand and the receptor. The recently discovered 2:1 lexitropsin-DNA binding motif provides a further refinement in molecular recognition in permitting discrimination between GC and CG base pairs. The application of these factors in the design and synthesis of novel agents which exhibit anticancer, antiviral and antiretroviral properties, and inhibition of critical cellular enzymes including topoisomerases is discussed. The emerging evidence of a relationship between sequence selectivity of the new agents and the biological responses they invoked is also described.