Comparison of the sequence-selective DNA binding by peptide dimers with covalent and noncovalent dimerization domains

Sequence-specific DNA binding proteins generally consist of more than two DNA-contacting regions to ensure the selectivity of recognition. The multiple DNA binding modules are connected either through the covalent linker or through the noncovalent dimerization domain. We have compared the DNA binding of peptide dimers with covalent and noncovalent dimerization domains to explore the potential advantage of each linkage on the sequence-specific DNA binding. Three sets of head-to-tail peptide dimers were synthesized by using the same basic region peptide to target the same DNA sequence; one dimer was assembled with a bridged biphenyl derivative as a covalent dimerization domain, and two other dimers were assembled with the cyclodextrin guest noncovalent dimerization domains. One of the noncovalent dimers was a heterodimer that consisted of cyclodextrin and guest peptides, while the other was a homodimer that consisted of peptides bearing both cyclodextrin and the guest molecule within the same chain. Both noncovalent dimers formed the specific DNA complexes within narrower ranges of peptide concentrations and showed higher sequence selectivity than the covalent dimer did. Among the three dimers, the noncovalent homodimer that can form an intramolecular inclusion complex showed the highest sequence selectivity. Because the noncovalent homodimer with the higher stability of the circular intramolecular inclusion complex exhibited the higher sequence selectivity, it was concluded that an equilibrium involving a conformational transition of a monomeric peptide effectively reduced the stability of its nonspecific binding complex, hence increasing the efficacy of cooperative dimer formation at the specific DNA sequence.