Influence of membrane potentials upon reversible protonation of acidic residues from the OmpF eyelet.

In this research we employed single-molecule electric recording techniques to investigate effects of the transmembrane and dipole potential on the reversible protonation of acidic residues from the constriction zone of the OmpF porin. Our results support the paradigm according to which the protonation state of aspartate 113 and glutamate 117 residues from the constriction region of OmpF is influenced by the electric potential profile, via an augmentation of the local concentration of protons near these residues mediated by increasing negative transmembrane potentials. We propose that at constant bulk pH, pK(a) values for proton bindings at these residues increase as the applied transmembrane potential increases in its negative values. Our data demonstrate that the apparent pK(a) for proton binding of the acidic aminoacids from the constriction region of OmpF is ionic strength-dependent, in the sense that a low ionic strength in the aqueous phase promotes the increase of the protonation reaction rate of such residues, at any given holding potential. Supplementary, we present evidence suggesting that lower values of the membrane dipole potential lead to an increase in the values of the 'on' rate of the eyelet acidic residues protonation, caused by an elevation of the local concentration of hydrogen ions. Altogether, these results come to support the paradigm according to which transmembrane and dipole potentials are critical parameters for the titration behavior of protein sites embedded lipid membranes.

Ion selectivity, transport properties and dynamics of amphotericin B channels studied over a wide range of acidity changes.

Amphotericin B (AmB) is an antifungal antibiotic which, despite the severe side effects, is still used for the treatment of systemic fungal infections. Herein we studied the influence of pH upon the selectivity and the transport properties of AmB channels inserted in reconstituted, ergosterol-containing zwitterionic lipid membranes. Our electrophysiology experiments carried out on single and multiple AmB channels prove that at pH 2.8 these channels are anion selective, whereas at neutral and alkaline pH's (pH 7 and pH 11) they become cation selective. We attribute this to the pH-dependent ionization state of the carboxyl and amino groups present at the mouth of AmB molecules. Surprisingly, our data reveal that the single-molecule ionic conductance of AmB channels varies in a non-monotonic fashion with pH changes, which we attribute to the pH-dependent variation of the surface and dipole membrane potential. We demonstrate that when added only from one side of the membrane, in symmetrical salt solutions across the membrane and low pH values, AmB channels display a strong rectifying behavior, and their insertion is strongly favored when positive potentials are present on the side of their addition.

Placement of oppositely charged aminoacids at a polypeptide termini determines the voltage-controlled braking of polymer transport through nanometer-scale pores.

Protein and solid-state nanometer-scale pores are being developed for the detection, analysis, and manipulation of single molecules. In the simplest embodiment, the entry of a molecule into a nanopore causes a reduction in the latter's ionic conductance. The ionic current blockade depth and residence time have been shown to provide detailed information on the size, adsorbed charge, and other properties of molecules. Here we describe the use of the nanopore formed by Staphylococcus aureus α-hemolysin and polypeptides with oppositely charged segments at the N- and C-termini to increase both the polypeptide capture rate and mean residence time of them in the pore, regardless of the polarity of the applied electrostatic potential. The technique provides the means to improve the signal to noise of single molecule nanopore-based measurements.

Meet me on the other side: trans-bilayer modulation of a model voltage-gated ion channel activity by membrane electrostatics asymmetry.

While it is accepted that biomembrane asymmetry is generated by proteins and phospholipids distribution, little is known about how electric changes manifested in a monolayer influence functional properties of proteins localized on the opposite leaflet. Herein we used single-molecule electrophysiology and investigated how asymmetric changes in the electrostatics of an artificial lipid membrane monolayer, generated oppositely from where alamethicin--a model voltage-gated ion channel--was added, altered peptide activity. We found that phlorizin, a membrane dipole potential lowering amphiphile, augmented alamethicin activity and transport features, whereas the opposite occurred with RH-421, which enhances the monolayer dipole potential. Further, the monolayer surface potential was decreased via adsorption of sodium dodecyl sulfate, and demonstrated that vectorial modification of it also affected the alamethicin activity in a predictive manner. A new paradigm is suggested according to which asymmetric changes in the monolayer dipole and surface potential extend their effects spatially by altering the intramembrane potential, whose gradient is sensed by distantly located peptides.