Ion fluxes considered in terms of membrane-surface electrical potentials
Australian Journal of Plant Physiology
28(7) 607 - 618
Published: 2001
Abstract
Ions transported through plasma membranes encounter electrical charges, and associated electrical potentials, at the membrane surfaces. The ionic composition of the tissue-bathing medium influences both the surface charge density and the surface electrical potential. Changes in surface electrical potential may affect ion transport by altering two components of the chemical potential difference (Δµj ) of an ion through the membrane. First, the surface activity of the transported ion will change because of electrostatic attraction or repulsion. Second, the surface-to-surface transmembrane potential difference will change. (This is different from the bulk-phase-to-bulk-phase transmembrane potential difference measured with microelectrodes.) These changes in the components of the chemical potential may change the flux of an ion through the membrane even if the surface-to-surface Δµj (equal to the bulk-phase-to-bulk-phase Δµj ) remains constant. The Goldman-Hodgkin-Katz (GHK) flux equation does not take into account these surface-potential effects. The equation has been modified to incorporate surface potentials computed by a Gouy-Chapman-Stern model and surface ion activities computed by Nernst equations. The modified equation (despite several additional deficiencies of the GHK model) successfully predicts many transport phenomena not predicted by the standard GHK equation. Thus electrostatic effects may account for saturation, cis- and trans-inhibition, rectification, voltage gating, shifts in voltage optima, and other phenomena also attributable to other mechanisms.Keywords: electrical potential, Goldman-Hodgkin-Katz, Gouy-Chapman-Stern, ion channels, ion transport, plasma membrane, zeta potential.
https://doi.org/10.1071/PP01019
© CSIRO 2001