Block of neuronal chloride channels by tetraethylammonium ion derivatives.

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Zeitschriftentitel:	The Journal of general physiology
Personen und Körperschaften:	Sanchez, D Y, Blatz, A L
In:	The Journal of general physiology, 106, 1995, 5, S. 1031-1046
Format:	E-Article
Sprache:	Englisch
veröffentlicht:	Rockefeller University Press
Schlagwörter:	Physiology

author_facet	Sanchez, D Y Blatz, A L Sanchez, D Y Blatz, A L
author	Sanchez, D Y Blatz, A L
spellingShingle	Sanchez, D Y Blatz, A L The Journal of general physiology Block of neuronal chloride channels by tetraethylammonium ion derivatives. Physiology
author_sort	sanchez, d y
spelling	Sanchez, D Y Blatz, A L 0022-1295 1540-7748 Rockefeller University Press Physiology http://dx.doi.org/10.1085/jgp.106.5.1031 <jats:p>The block by the symmetric tetraethylammonium (TEA) ion derivatives tetrapropylammonium (TPrA), tetrabutylammonium (TBA), and tetrapentylammonium (TPeA) ions of fast chloride channels in acutely dissociated rat cortical neurons was studied with the excised inside-out configuration of the patch-clamp technique. When applied to the intracellular membrane surface, all three of the quaternary ammonium compounds (QAs) induced the appearance of short-lived closed states in a manner consistent with a blocking mechanism where the blocker preferentially binds to the open kinetic state and completely blocks ion current through the channel. The drug must leave the channel before the channel can return to a closed state. The mechanism of block was studied using one-dimensional dwell-time analysis. Kinetic models were fit to distributions of open and closed interval durations using the Q-matrix approach. The blocking rate constants for all three of the QAs were similar with values of approximately 12-20 x 10(6) M-1s-1. The unblocking rates were dependent on the size or hydrophobicity of the QA with the smallest derivative, TPrA, inducing a blocked state with a mean lifetime of approximately 90 microseconds, while the most hydrophobic derivative, TPeA, induced a blocked state with a mean lifetime of approximately 1 ms. Thus, it appears as though quaternary ammonium ion block of these chloride channels is nearly identical to the block of many potassium channels by these compounds. This suggests that there must be structural similarities in the conduction pathway between anion and cation permeable channels.</jats:p> Block of neuronal chloride channels by tetraethylammonium ion derivatives. The Journal of general physiology
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imprint	Rockefeller University Press, 1995
imprint_str_mv	Rockefeller University Press, 1995
issn	0022-1295 1540-7748
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publishDateSort	1995
publisher	Rockefeller University Press
recordtype	ai
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series	The Journal of general physiology
source_id	49
title	Block of neuronal chloride channels by tetraethylammonium ion derivatives.
title_unstemmed	Block of neuronal chloride channels by tetraethylammonium ion derivatives.
title_full	Block of neuronal chloride channels by tetraethylammonium ion derivatives.
title_fullStr	Block of neuronal chloride channels by tetraethylammonium ion derivatives.
title_full_unstemmed	Block of neuronal chloride channels by tetraethylammonium ion derivatives.
title_short	Block of neuronal chloride channels by tetraethylammonium ion derivatives.
title_sort	block of neuronal chloride channels by tetraethylammonium ion derivatives.
topic	Physiology
url	http://dx.doi.org/10.1085/jgp.106.5.1031
publishDate	1995
physical	1031-1046
description	<jats:p>The block by the symmetric tetraethylammonium (TEA) ion derivatives tetrapropylammonium (TPrA), tetrabutylammonium (TBA), and tetrapentylammonium (TPeA) ions of fast chloride channels in acutely dissociated rat cortical neurons was studied with the excised inside-out configuration of the patch-clamp technique. When applied to the intracellular membrane surface, all three of the quaternary ammonium compounds (QAs) induced the appearance of short-lived closed states in a manner consistent with a blocking mechanism where the blocker preferentially binds to the open kinetic state and completely blocks ion current through the channel. The drug must leave the channel before the channel can return to a closed state. The mechanism of block was studied using one-dimensional dwell-time analysis. Kinetic models were fit to distributions of open and closed interval durations using the Q-matrix approach. The blocking rate constants for all three of the QAs were similar with values of approximately 12-20 x 10(6) M-1s-1. The unblocking rates were dependent on the size or hydrophobicity of the QA with the smallest derivative, TPrA, inducing a blocked state with a mean lifetime of approximately 90 microseconds, while the most hydrophobic derivative, TPeA, induced a blocked state with a mean lifetime of approximately 1 ms. Thus, it appears as though quaternary ammonium ion block of these chloride channels is nearly identical to the block of many potassium channels by these compounds. This suggests that there must be structural similarities in the conduction pathway between anion and cation permeable channels.</jats:p>
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SOLR
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author	Sanchez, D Y, Blatz, A L
author_facet	Sanchez, D Y, Blatz, A L, Sanchez, D Y, Blatz, A L
author_sort	sanchez, d y
container_issue	5
container_start_page	1031
container_title	The Journal of general physiology
container_volume	106
description	<jats:p>The block by the symmetric tetraethylammonium (TEA) ion derivatives tetrapropylammonium (TPrA), tetrabutylammonium (TBA), and tetrapentylammonium (TPeA) ions of fast chloride channels in acutely dissociated rat cortical neurons was studied with the excised inside-out configuration of the patch-clamp technique. When applied to the intracellular membrane surface, all three of the quaternary ammonium compounds (QAs) induced the appearance of short-lived closed states in a manner consistent with a blocking mechanism where the blocker preferentially binds to the open kinetic state and completely blocks ion current through the channel. The drug must leave the channel before the channel can return to a closed state. The mechanism of block was studied using one-dimensional dwell-time analysis. Kinetic models were fit to distributions of open and closed interval durations using the Q-matrix approach. The blocking rate constants for all three of the QAs were similar with values of approximately 12-20 x 10(6) M-1s-1. The unblocking rates were dependent on the size or hydrophobicity of the QA with the smallest derivative, TPrA, inducing a blocked state with a mean lifetime of approximately 90 microseconds, while the most hydrophobic derivative, TPeA, induced a blocked state with a mean lifetime of approximately 1 ms. Thus, it appears as though quaternary ammonium ion block of these chloride channels is nearly identical to the block of many potassium channels by these compounds. This suggests that there must be structural similarities in the conduction pathway between anion and cation permeable channels.</jats:p>
doi_str_mv	10.1085/jgp.106.5.1031
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id	ai-49-aHR0cDovL2R4LmRvaS5vcmcvMTAuMTA4NS9qZ3AuMTA2LjUuMTAzMQ
imprint	Rockefeller University Press, 1995
imprint_str_mv	Rockefeller University Press, 1995
institution	DE-Gla1, DE-Zi4, DE-15, DE-Pl11, DE-Rs1, DE-105, DE-14, DE-Ch1, DE-L229, DE-D275, DE-Bn3, DE-Brt1, DE-D161, DE-Zwi2
issn	0022-1295, 1540-7748
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language	English
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mega_collection	Rockefeller University Press (CrossRef)
physical	1031-1046
publishDate	1995
publishDateSort	1995
publisher	Rockefeller University Press
record_format	ai
recordtype	ai
series	The Journal of general physiology
source_id	49
spelling	Sanchez, D Y Blatz, A L 0022-1295 1540-7748 Rockefeller University Press Physiology http://dx.doi.org/10.1085/jgp.106.5.1031 <jats:p>The block by the symmetric tetraethylammonium (TEA) ion derivatives tetrapropylammonium (TPrA), tetrabutylammonium (TBA), and tetrapentylammonium (TPeA) ions of fast chloride channels in acutely dissociated rat cortical neurons was studied with the excised inside-out configuration of the patch-clamp technique. When applied to the intracellular membrane surface, all three of the quaternary ammonium compounds (QAs) induced the appearance of short-lived closed states in a manner consistent with a blocking mechanism where the blocker preferentially binds to the open kinetic state and completely blocks ion current through the channel. The drug must leave the channel before the channel can return to a closed state. The mechanism of block was studied using one-dimensional dwell-time analysis. Kinetic models were fit to distributions of open and closed interval durations using the Q-matrix approach. The blocking rate constants for all three of the QAs were similar with values of approximately 12-20 x 10(6) M-1s-1. The unblocking rates were dependent on the size or hydrophobicity of the QA with the smallest derivative, TPrA, inducing a blocked state with a mean lifetime of approximately 90 microseconds, while the most hydrophobic derivative, TPeA, induced a blocked state with a mean lifetime of approximately 1 ms. Thus, it appears as though quaternary ammonium ion block of these chloride channels is nearly identical to the block of many potassium channels by these compounds. This suggests that there must be structural similarities in the conduction pathway between anion and cation permeable channels.</jats:p> Block of neuronal chloride channels by tetraethylammonium ion derivatives. The Journal of general physiology
spellingShingle	Sanchez, D Y, Blatz, A L, The Journal of general physiology, Block of neuronal chloride channels by tetraethylammonium ion derivatives., Physiology
title	Block of neuronal chloride channels by tetraethylammonium ion derivatives.
title_full	Block of neuronal chloride channels by tetraethylammonium ion derivatives.
title_fullStr	Block of neuronal chloride channels by tetraethylammonium ion derivatives.
title_full_unstemmed	Block of neuronal chloride channels by tetraethylammonium ion derivatives.
title_short	Block of neuronal chloride channels by tetraethylammonium ion derivatives.
title_sort	block of neuronal chloride channels by tetraethylammonium ion derivatives.
title_unstemmed	Block of neuronal chloride channels by tetraethylammonium ion derivatives.
topic	Physiology
url	http://dx.doi.org/10.1085/jgp.106.5.1031