The binding of Arg- and Lys-peptides to single standed polyribonucleotides and its effect on the polymer conformation

The interactions between basic oligopeptides (Lys₂, Lys₃, Arg₂, and Arg₃) and single stranded polynucleotides (poly(A), poly(C), poly(I) and poly(U) were investigated at low ion concentration by UV spectroscopy, circular dichroism and field jump relaxation. Various domains of binding were detected: 1) High concentrations (up to 1 mM) of some peptides induce opalescencs followed by coacervation- Arg₃ causes coacervation in all polynucleotides used, yet Lys₃ only in poly(I). In the case of poly(I) the threshold concentration for coacervation is much lower for Arg₃ (150 μM) than for Lys₃ (500 μM). 2) Medium concentrations (?10 μM) of Arg₃ and Lys₃ induce helix formation in poly(U). In the case of poly(I) cooperative helix formation is only induced by Lys₃, but not by Arg₃. 3) The onset of peptide association is observed at very low peptide concentrations (?1 μM) already by using the field jump method. The association is reflected by a relaxation process, that can be described by a single exponential within experimental accuracy. Measurements of relaxation time constants as a function of the peptide concentration provide information on the association constants K, the number of nucleotide residues per binding place n and the rate constants k_R and k_D. Using a simple model with independent and “separate” binding sites, K for Arg₃ and Lys₃ is found to be in the range of 10⁶ to 10⁷ M^?1. In the case of Arg₂ and K is lower by a factor of about 10. For various polynucleotides K_Arg3 is slightly higher than K_Lys3. except in the case of poly(I), where K_Arg3/K_Lys3 ≈ 5. Similar data are obtained by application of a “sphere model” (see below). These results provide quantitative evidence for specific hydrogen bonding between the guanidino group of Arg and inosine. They also explain the absence of helix formation for poly(I) + Arg₃: Arg blocks the hydrogen bonding sites of inosine. Thus cooperative coupling leads in this case to a considerable amplification of specificity in the peptide-polynucleotide interaction Both field jump and stopped flow data demonstrate a high mobility of the peptide lisands along the polymer, resulting in a redistribution being fast compared with the overall binding step. Based on this result the relaxation data are analysed by a “sphere” model, which considers a) excluded binding under the condition of fast Ugand distribution along the lattice and b) the connection of sites into a polymer sphere. The rate constants obtained by this model are in the range of 4 × 10¹¹ M^?1 s^?1. These high values reflect the large reaction distance for polymers of chain lengths around 1000. A comparison with rate constants obtained previously for oligomer complexes indicates that the recombination rate is approximately a function of the square root of the nucleotide chain length, which is directly related to the mean radius of coiled polymers.