Application of CEC procedures for the analysis of synthetic peptides: characterization of linear immunogenic peptides that mimic a HIV‐1 gp120 epitope

Abstract

In this study, we describe the application of a new analytical procedure based on capillary electrochromatographic(CEC) techniques for the characterization of different basic and acidic peptides using isocratic eluent conditions containing acetonitrile and ammonium acetate buffers of different molarities between pH 3.8 and 5.2. In particular,10 immunogenic peptide analogs with isoelectric points ranging from 3.7 to 10.1 were investigated; nine of these peptides, 1-9, were truncated analogs of the parent peptide, 10, which is a peptidomimetic related to a HIV-1 gp120 epitope. Several of these peptides have the propensity to form alpha-helical secondary structures in solution. Electrochromatographic separations of these peptides were achieved with packed fused silica capillaries(25 cm packed length, 100 microm i.d.) containing 3 microm n-octadecylsilica particles. The influence of temperature on the CEC elution behavior of these peptides, as well as the impact of changes in the eluent composition, e.g. pH, buffer concentration and acetonitrile content, were examined. The results confirm that improvements in the resolution and analysis of synthetic peptides by CEC procedures result from the increase inelectroosmotic flow (EOF) as the temperature is increased. These findings emphasize the dominant influence of the temperature-dependent viscosity parameter, eta, on the EOF and thus on peptide resolution in CEC. Moreover, these investigations have shown that eluent properties can be specifically chosen to favor either electrophoretic mobility or chromatographic retention, with the overall CEC selectivity peptides of different sequence or composition reflecting the summated contributions from both separation mechanisms. Over the pH range 4.0-5.0, and using eluents with ionic strengths ranging from 6.2 to 15 mM ammonium acetate but containing a fixed volume fraction, psi, of acetonitrile above psi = 0.40, the CEC retention behavior of peptides 1-10 correlated with a linear relationship linking the retention coefficient, kappta(cec), and the differential frictional size-to-mass ratio parameter, Xi(fric), of these peptides. However, using eluents with a low acetonitrile content and low pH values, linear correlations were also observed between the incremental retention coefficient, Delta(Kappa)cec, and the product term [-0.66(Delta(Sigma[Xn]) log(Mi/Mj)], which links the difference in intrinsic hydrophobicities and molecular masses of two peptides, Pi and Pj. This study thus demonstrates the power of CEC procedures in the analysis of synthetic bioactive peptides and provides a general experimental framework to evaluate,using CEC procedures, the influence of the key molecular attributes of peptides on their structure-retention dependencies.Finally, these studies provide additional, practical insights into the use of CEC procedures for the analysis, resolution and biophysical characterization of closely related peptide analogs derived from solid-state peptide synthesis under conditions of different eluent composition or temperature.