SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W1506201712> ?p ?o ?g. }

Showing items 1 to 100 of ±131 with 100 items per page.

W1506201712 endingPage "870" @default.
W1506201712 startingPage "857" @default.
W1506201712 abstract "Desensitization and inactivation provide a form of short-term memory controlling the firing patterns of excitable cells and adaptation in sensory systems. Unlike many of their cousin K(+) channels, cyclic nucleotide-gated (CNG) channels are thought not to desensitize or inactivate. Here we report that CNG channels do inactivate and that inactivation is controlled by extracellular protons. Titration of a glutamate residue within the selectivity filter destabilizes the pore architecture, which collapses towards a non-conductive, inactivated state in a process reminiscent of the usual C-type inactivation observed in many K(+) channels. These results indicate that inactivation in CNG channels represents a regulatory mechanism that has been neglected thus far, with possible implications in several physiological processes ranging from signal transduction to growth cone navigation.Ion channels control ionic fluxes across biological membranes by residing in any of three functionally distinct states: deactivated (closed), activated (open) or inactivated (closed). Unlike many of their cousin K(+) channels, cyclic nucleotide-gated (CNG) channels do not desensitize or inactivate. Using patch recording techniques, we show that when extracellular pH (pHo ) is decreased from 7.4 to 6 or lower, wild-type CNGA1 channels inactivate in a voltage-dependent manner. pHo titration experiments show that at pHo < 7 the I-V relationships are outwardly rectifying and that inactivation is coupled to current rectification. Single-channel recordings indicate that a fast mechanism of proton blockage underlines current rectification while inactivation arises from conformational changes downstream from protonation. Furthermore, mutagenesis and ionic substitution experiments highlight the role of the selectivity filter in current decline, suggesting analogies with the C-type inactivation observed in K(+) channels. Analysis with Markovian models indicates that the non-independent binding of two protons within the transmembrane electrical field explains both the voltage-dependent blockage and the inactivation. Low pH, by inhibiting the CNGA1 channels in a state-dependent manner, may represent an unrecognized endogenous signal regulating CNG physiological functions in diverse tissues." @default.
W1506201712 created "2016-06-24" @default.
W1506201712 creator A5041399922 @default.
W1506201712 creator A5056832410 @default.
W1506201712 creator A5080095578 @default.
W1506201712 creator A5083032296 @default.
W1506201712 date "2015-01-07" @default.
W1506201712 modified "2023-10-15" @default.
W1506201712 title "Proton transfer unlocks inactivation in cyclic nucleotide‐gated A1 channels" @default.
W1506201712 cites W1233451781 @default.
W1506201712 cites W1483455478 @default.
W1506201712 cites W1555466324 @default.
W1506201712 cites W1862230085 @default.
W1506201712 cites W1969152739 @default.
W1506201712 cites W1979694517 @default.
W1506201712 cites W1980494327 @default.
W1506201712 cites W1997511216 @default.
W1506201712 cites W2006129103 @default.
W1506201712 cites W2008303351 @default.
W1506201712 cites W2009667219 @default.
W1506201712 cites W2015426350 @default.
W1506201712 cites W2015766644 @default.
W1506201712 cites W2017658177 @default.
W1506201712 cites W2027788236 @default.
W1506201712 cites W2034176125 @default.
W1506201712 cites W2035584685 @default.
W1506201712 cites W2040083201 @default.
W1506201712 cites W2040102418 @default.
W1506201712 cites W2044094305 @default.
W1506201712 cites W2046381710 @default.
W1506201712 cites W2049072066 @default.
W1506201712 cites W2057001000 @default.
W1506201712 cites W2065466405 @default.
W1506201712 cites W2065565137 @default.
W1506201712 cites W2068201018 @default.
W1506201712 cites W2069480791 @default.
W1506201712 cites W2072945476 @default.
W1506201712 cites W2074989782 @default.
W1506201712 cites W2075286038 @default.
W1506201712 cites W2087256484 @default.
W1506201712 cites W2089338912 @default.
W1506201712 cites W2091854457 @default.
W1506201712 cites W2095529674 @default.
W1506201712 cites W2108571273 @default.
W1506201712 cites W2110479875 @default.
W1506201712 cites W2118571245 @default.
W1506201712 cites W2122167535 @default.
W1506201712 cites W2125530007 @default.
W1506201712 cites W2127735309 @default.
W1506201712 cites W2133464980 @default.
W1506201712 cites W2138864044 @default.
W1506201712 cites W2141153221 @default.
W1506201712 cites W2143125286 @default.
W1506201712 cites W2154420009 @default.
W1506201712 cites W2157409937 @default.
W1506201712 cites W2167652900 @default.
W1506201712 cites W2169043610 @default.
W1506201712 cites W2169475423 @default.
W1506201712 doi "https://doi.org/10.1113/jphysiol.2014.284216" @default.
W1506201712 hasPubMedCentralId "https://www.ncbi.nlm.nih.gov/pmc/articles/4398526" @default.
W1506201712 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/25480799" @default.
W1506201712 hasPublicationYear "2015" @default.
W1506201712 type Work @default.
W1506201712 sameAs 1506201712 @default.
W1506201712 citedByCount "4" @default.
W1506201712 countsByYear W15062017122018 @default.
W1506201712 countsByYear W15062017122019 @default.
W1506201712 countsByYear W15062017122021 @default.
W1506201712 countsByYear W15062017122022 @default.
W1506201712 crossrefType "journal-article" @default.
W1506201712 hasAuthorship W1506201712A5041399922 @default.
W1506201712 hasAuthorship W1506201712A5056832410 @default.
W1506201712 hasAuthorship W1506201712A5080095578 @default.
W1506201712 hasAuthorship W1506201712A5083032296 @default.
W1506201712 hasBestOaLocation W15062017121 @default.
W1506201712 hasConcept C104317684 @default.
W1506201712 hasConcept C12554922 @default.
W1506201712 hasConcept C131829789 @default.
W1506201712 hasConcept C145148216 @default.
W1506201712 hasConcept C15152581 @default.
W1506201712 hasConcept C170493617 @default.
W1506201712 hasConcept C178790620 @default.
W1506201712 hasConcept C181911157 @default.
W1506201712 hasConcept C185592680 @default.
W1506201712 hasConcept C2778524494 @default.
W1506201712 hasConcept C28406088 @default.
W1506201712 hasConcept C30095370 @default.
W1506201712 hasConcept C50254741 @default.
W1506201712 hasConcept C512185932 @default.
W1506201712 hasConcept C55493867 @default.
W1506201712 hasConcept C86803240 @default.
W1506201712 hasConceptScore W1506201712C104317684 @default.
W1506201712 hasConceptScore W1506201712C12554922 @default.
W1506201712 hasConceptScore W1506201712C131829789 @default.
W1506201712 hasConceptScore W1506201712C145148216 @default.
W1506201712 hasConceptScore W1506201712C15152581 @default.
W1506201712 hasConceptScore W1506201712C170493617 @default.
W1506201712 hasConceptScore W1506201712C178790620 @default.