BACKGROUND: We previously described a general class of DNA polyintercalators in which 1,4,5,8-naphthalenetetracarboxylic diimide (NDI) intercalating units are connected via peptide linkers, resulting in the first known tetrakis- and octakis-intercalators. We showed further that changes in the composition of the peptide tether result in novel DNA binding site specificities. We now examine in detail the DNA binding mode and sequence specific recognition of Compound 1, an NDI bis-intercalator containing the peptide linker gly-gly-gly-lys. RESULTS: 1H-NMR structural studies of Compound 1 bound to d(CGGTACCG)(2) confirmed a threading mode of intercalation, with four base pairs between the diimide units. The NMR data, combined with DNAse I footprinting of several analogs, suggest that specificity depends on a combination of steric and electrostatic contacts by the peptide linker in the floor of the major groove. CONCLUSIONS: In view of the modular nature and facile synthesis of our NDI-based polyintercalators, such structural knowledge can be used to improve or alter the specificity of the compounds and design longer polyintercalators that recognize correspondingly longer DNA sequences with alternating access to both DNA grooves.
BACKGROUND: We previously described a general class of DNA polyintercalators in which 1,4,5,8-naphthalenetetracarboxylic diimide (NDI) intercalating units are connected via peptide linkers, resulting in the first known tetrakis- and octakis-intercalators. We showed further that changes in the composition of the peptide tether result in novel DNA binding site specificities. We now examine in detail the DNA binding mode and sequence specific recognition of Compound 1, an NDI bis-intercalator containing the peptide linker gly-gly-gly-lys. RESULTS:1H-NMR structural studies of Compound 1 bound to d(CGGTACCG)(2) confirmed a threading mode of intercalation, with four base pairs between the diimide units. The NMR data, combined with DNAse I footprinting of several analogs, suggest that specificity depends on a combination of steric and electrostatic contacts by the peptide linker in the floor of the major groove. CONCLUSIONS: In view of the modular nature and facile synthesis of our NDI-based polyintercalators, such structural knowledge can be used to improve or alter the specificity of the compounds and design longer polyintercalators that recognize correspondingly longer DNA sequences with alternating access to both DNA grooves.
Authors: Carolyn L Mazzitelli; Yongjun Chu; Joseph J Reczek; Brent L Iverson; Jennifer S Brodbelt Journal: J Am Soc Mass Spectrom Date: 2006-11-13 Impact factor: 3.109