Thermal unfolding of apolipoprotein a-1 : evaluation of methods and models

Human apolipoprotein A-1 (Apo A-1) was used as a model protein to compare experimental methods and theoretical models for protein unfolding. Thermal unfolding was investigated in aqueous buffer, in β-octylglucoside solution, and with phospholipid bilayer vesicles. The α-helix content of Apo A-1 increased from 50% in aqueous buffer to 75% in the presence of lipid vesicles, but remained constant in solutions of β-octyl glucoside. Differential scanning calorimetry (DSC) measured the thermodynamic properties of the unfolding process and was our reference method. The increased heat capacity of the unfolded protein made an important contribution to the total enthalpy of unfolding. The structural properties of Apo A-1 were studied with circular dichroism (CD) spectroscopy. The CD-recorded unfolding transitions were broader than the corresponding DSC transitions and were shifted toward higher temperatures. DSC and CD data were analyzed with the two-state model and the Zimm-Bragg theory. The two-state model assumes just two species in solution, native (N) and unfolded (U) Apo A-1. However, Apo A-1 unfolding is a highly cooperative event with helical amino acid residues unfolding and refolding rapidly. For such a sequential process, the Zimm-Bragg theory provides an alternative and physically more realistic model. The Zimm-Bragg theory allowed perfect simulations of the DSC and CD experiments. In contrast, incorrect thermodynamic results were obtained with the two-state model. The Zimm-Bragg theory also provided a physically well-defined analysis of the cooperativity of the folding ⇄ unfolding equilibrium. The cooperative unfolding of Apo A-1 increased upon addition of lipids and decreased in detergent solution

Thermodynamic and Biophysical Analysis of the Membrane-Association of a Histidine-Rich Peptide with Efficient Antimicrobial and Transfection Activities

LAH4-L1 is a synthetic amphipathic peptide with antimicrobial activity. The sequence of the 23 amino acid peptide was inspired by naturally occurring frog peptides such as PGLa and magainin. LAH4-L1 also facilitates the transport of nucleic acids through the cell membrane. We have investigated the membrane binding properties and energetics of LAH4-L1 at pH 5.5 with physical-chemical methods. CD spectroscopy was employed to quantitate the membrane-induced random coil-to-helix transition of LAH4-L1. Binding isotherms were obtained with CD spectroscopy as a function of the lipid-to-protein ratio for neutral and negatively charged membranes and were analyzed with both the Langmuir multisite adsorption model and the surface partition/Gouy-Chapman model. According to the Langmuir adsorption model each molecule LAH4-L1 binds 4 POPS molecules, independent of the POPS concentration in the membrane. This is supported by the surface partition/Gouy-Chapman model which predicts an electric charge of LAH4-L1 of z = 4. Binding affinity is dominated by electrostatic attraction. The thermodynamics of the binding process was elucidated with isothermal titration calorimetry. The ITC data revealed that the binding process is composed of at least three different reactions, that is, a coil-to-helix transition with an exothermic enthalpy of about -11 kcal/mol and two endothermic processes with enthalpies of ∼4 and ∼8 kcal/mol, respectively, which partly compensate the exothermic enthalpy of the conformational change. The major endothermic reaction is interpreted as a deprotonation reaction following the insertion of a highly charged cationic peptide into a nonpolar environment