Referenced in: none

Automatically associated channels: Kv10.1

Title: Effects of NEM on voltage-activated chloride conductance in toad skin.

Authors: W Nagel, U Katz

Journal, date & volume: J. Membr. Biol., 1997 Sep 15 , 159, 127-35

PubMed link: http://www.ncbi.nlm.nih.gov/pubmed/9307439

Abstract
The regulation of the voltage-activated chloride current conductance (GCl) in toad skin was investigated by the use of the SH reagents N-ethylmaleimide (NEM) and p-chloro-mercuricbenzenesulfonic acid PCMBS. This anion pathway is controlled by a voltage-sensitive gating regulator. Mucosal application of NEM decreased the voltage-activation in a time and concentration dependent manner, half-maximal inhibition being exerted at a concentration of 30 microM within 20 min. At concentrations higher than 100 microM, the voltage-activated GCl was near-completely and irreversibly inhibited in less than 10 min. Resting, deactivated conductance was essentially unaffected. NEM had no effect on active sodium transport (measured as Isc) under conditions, which fully dissipated the voltage-activated GCl. After complete inhibition of the voltage-activated GCl with NEM, chloride conductance could still be stimulated by CPT-cAMP as in control tissues. Under these conditions, NEM at concentrations above 1 mm decreased GCl reversibly. Mucosal application of PCMBS at 500 microM inhibited the activated conductance by 35%, which was slightly reversible. Inhibition of voltage-activated GCl, which was observed after mucosal addition of the membrane-impermeable NEM analogue, eosin-5-maleimide, was completely reversible after washout. This suggests that the binding site for the maleimide is not accessible from the external face of the apical membrane. Brief application of NEM at lower concentrations (1-3 min, </= 100 microM) led to partial inhibition of GCl, followed by occasionally complete recovery upon washout of NEM. Recovery of voltage-activated GCl was progressively attenuated and eventually disappeared after subsequent brief applications of NEM. This could reflect recruitment of permeation/control sites from a finite pool. The data are discussed in the frame of a working model for the voltage-activated Cl--pathway, that contains two principle components, i.e., an anion-selective permeation path which is controlled by regulatory protein(s).