Quantitative and Rapid Estimation of H+ Fluxes in Membrane Vesicles

Abstract

Proton transport is often visualized in membrane vesicles by use of fluorescent monoamines which accumulate in acidic intravesicular compartments and undergo concentration-dependent fluorescence quenching. Software for an IBM microcomputer is described which permits logging and editing of changes in fluorescence monitored by a Perkin-Elmer LS-5 luminescence spectrometer. An accurate estimate of the instantaneous rate of fluorescence quenching or recovery is then facilitated by least squares fitting of fluorescence data to a nonlinear function. The software is tested with tonoplast vesicles from Beta vulgaris. Quenching of acridine orange fluorescence by ATP-driven (primary) transport and relaxation of quenching by Na(+)/H(+) antiport can both be fitted with single exponential functions. Initial rates of ATP- and Na(+) -dependent fluorescence changes are derived and can be used for K(m) determinations. The method constitutes a simple and efficient alternative to manual analysis of analog fluorescence traces and results in a reliable quantitative measurement of the relative rate of proton transport in membrane vesicle preparations.