Abstract

The effects of surface potential and transmembrane potential on the binding and fluorescence of 1-anilinonaphthalene-8-sulfonate (ANS) in suspensions of rat liver mitochondria was investigated. The binding of ANS is characterized by two classes of binding site: a high affinity (Kd = 10-50 microM), low capacity (n = 3-8 nmol/mg of protein) class in which bound ANS fluoresces strongly, and a low affinity (greater than 500 microM), high capacity (greater than 50 nmol/mg of protein) class with little fluorescence. The dissociation constant, Kd, of the high affinity site strongly depends on the surface potential of the external surface of the inner mitochondrial membrane. Hence, the binding and fluorescence of ANS can be used to estimate the surface potential. The dependence of ANS binding on the medium salt concentration is compatible with the Gouy-Chapman theory and allows accurate determination of surface potential and surface charge. The generation of transmembrane potential, either by oxidizable substrates, ATP, or potassium gradient leads to a decrease in the fluorescence. This decrease is the result of reduced ANS binding. However, the external surface potential as estimated from the charge screening effect of salt solutions is unchanged in energized membranes. The extent of decreased fluorescence correlates reasonably well with the magnitude of the transmembrane potential. The potential-induced quenching depends on pre-equilibration of ANS with the mitochondria, suggesting that the response is due to extrusion of ANS from the mitochondrial matrix. These findings do not support the suggestion that ANS quenching in energized mitochondria is due to an increase in the negative surface charge of the cytosolic surface of the inner membrane. The results are compatible with the suggestion that the response to energization is largely due to the formation of delta psi. However, because of the complex nature of the ANS response, it is concluded that neither the magnitude of surface potential nor the magnitude of membrane potential can be determined from the ANS response in energized mitochondria.

Highlights

  • The effectsof surface potentialand transmembrane ANSI [1].This discovery, over 13 years ago, was followed by potential on the binding and fluorescence of 1-anili- a rapid spread of the use of ANS as a probe for energization nonaphthalene-8-sulfonate (ANS) in suspensions of rat in mitochondria and in many other membrane systems

  • The dissociation constant, Kd, of the high affinity site stronglydepends on the surface potential of theexternalsurface of theinner mitochondrial membrane

  • Chromatophores, and other vesicles which generate positive membrane potential, ANS is believed to accumulate internally which leads to enhancement of the fluorescence

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Summary

Membrane Potential and Surface Potential Minitochondria

It has been suggested that the negatively charged ANS responds to the formation of membrane potential by diffusing across the membrane to reach a new electrochemical equilibrium [5] This equilibration, it was suggeted, led to quenching of the fluorescence in mitochondria as a result of the depletion of the matrix ANS. The results are compatible with the suggestion that the response fluorescence of ANS in various membrane preparations are determined by the surface potential [9,10,11]. The data arebest fit by a model which includes the surface potential nor themagnitude of membrane po- effects of both surface potential and transmembrane potentential can be determined from the ANS response in tial It is demonstrated thawt hile ANS binding and fluoresenergized mitochondria. All other chemicals were reagent grade and were purchased from commercial sources

RESULTS
Fluorescence binding versus medium p H
The effect of
Findings
DISCUSSION
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