Aqueous solution secondary structures of minimalist LK-peptides, with the generic sequence defined as KLL(KLLL)nKLLK, have been analyzed by means of circular dichroism (CD) and Raman scattering techniques. Our discussion in the present paper is mainly focused on four synthetic peptides (from 5 to 19 amino acids), KLLLK, KLLKLLLKLLK, KLLKLLLKLLLKLLK, and KLLKLLLKLLLKLLLKLLK, corresponding to the repeat unit, and to the peptide chains with the values of n = 1-3, respectively. CD and Raman spectra were analyzed in order to study both structural features of the peptide chains and their capability to form aggregates. On the basis of the obtained results it was concluded that the conformational flexibility of the shortest peptides (5-mer and 11-mer) is high enough to adopt random, beta-type, and helical chains in aqueous solution. However, the 11-mer shows a clear tendency to form beta-strands in phosphate buffer. The conformational equilibrium can be completely shifted to beta-type structures upon increasing ionic strength, i.e., in PBS and tris buffers. This equilibrium can also be shifted toward helical chains in the presence of methanol. Finally, the longest peptides (15-mer and 19-mer) are shown to form alpha-helical chains with an amphipathic character in aqueous solution. The possibility of bundle formation between helical chains is discussed over the temperature-dependent H-D exchange on labile hydrogens and particularly by considering the particular behavior of an intense Raman mode at 1127 cm-1 originating from the leucine residue side chain. The conformational dependence of this mode observed upon selective deuteration has never been documented up to now.
Circular dichroism (CD) and Raman scattering were applied to the aqueous solution of minimalist LK peptides constructed with successive KL repeats leading to the following generic primary sequence: (KL)nK. Three peptides of this family, a 3-mer (n=1), a 9-mer (n=4), and a 15-mer (n=7), are analyzed in this report. Raman spectra of the 3-mer (KLK, a random chain) and its labile-hydrogen deuterated species yield a set of interesting information for analyzing longer peptides of this series. Although the CD spectrum of the 9-mer (KLKLKLKLK) reveals a signal traditionally assigned to a random structure, the corresponding Raman spectrum allows finding a mixture of conformations in solution, adopting predominantly beta-type structures. This fact proves the utility of Raman spectroscopy to eliminate eventual ambiguity concerning conformational assignments in peptides based only on the use of CD technique. Finally, the 15-mer (KLKLKLKLKLKLKLK) gives rise to CD and Raman spectra clearly assignable to a beta-type structure. On the basis of all the observed results on the 15-mer, we can confirm that this peptide may exist as isolated beta-strands at low concentration (sub-micromolar), flat-oriented at the air/water interface, whereas at high concentrations (millimolar), non-H-bonded immersible aggregates might be formed. A hypothetical model for these beta-strand aggregates could be proposed as stabilized by an interior hydrophobic core and a hydrophilic external face, formed by leucine and lysine side chains, respectively.
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