Structural basis of allosteric interactions among Ca2+-binding sites in a K+ channel RCK domain

Youn

Journal of Biological Chemistry

et al. 2015

Section: Discussionmentioning

confidence: 99%

Structural Studies of Potassium Transport Protein KtrA Regulator of Conductance of K+ (RCK) C Domain in Complex with Cyclic Diadenosine Monophosphate (c-di-AMP)

Youn

Journal of Biological Chemistry

et al. 2015

Genes Brain and Behavior

“…First, we tested the role of the RCK1 domain in vivo by generating transgenic strains expressing slo-1(RCK1), which contained two mutations (D391A and D396A, equivalent to mouse D362A and D367A, respectively), in a slo-1(null) mutant background. These mutations were previously shown to strongly reduce Ca 2+ sensitivity of the mammalian BK channel and RCK-type domains in other proteins (Cui et al 2009;Smith et al 2013). Two transgenic strains (#1 and #2) were generated to control for variation in transgenesis.…”

Section: Putative Ca 2+ -Sensing Domains In the Worm Bk Channel Are Nmentioning

confidence: 99%

Putative calcium‐binding domains of the Caenorhabditis elegans BK channel are dispensable for intoxication and ethanol activation

Davis

Scott

Ordemann

et al. 2015

Alcohol modulates the highly conserved, voltage- and calcium-activated potassium (BK) channel, which contributes to alcohol-mediated behaviors in species from worms to humans. Previous studies have shown that the calcium-sensitive domains, RCK1 and the Ca2+ bowl, are required for ethanol activation of the mammalian BK channel in vitro. In the nematode Caenorhabditis elegans, ethanol activates the BK channel in vivo, and deletion of the worm BK channel, SLO-1, confers strong resistance to intoxication. To determine if the conserved RCK1 and calcium bowl domains were also critical for intoxication and basal BK channel-dependent behaviors in C. elegans, we generated transgenic worms that express mutated SLO-1 channels predicted to have the RCK1, Ca2+ bowl or both domains rendered insensitive to calcium. As expected, mutating these domains inhibited basal function of SLO-1 in vivo as neck and body curvature of these mutants mimicked that of the BK null mutant. Unexpectedly, however, mutating these domains singly or together in SLO-1 had no effect on intoxication in C. elegans. Consistent with these behavioral results, we found that ethanol activated the SLO-1 channel in vitro with or without these domains. By contrast, in agreement with previous in vitro findings, C. elegans harboring a human BK channel with mutated calcium-sensing domains displayed resistance to intoxication. Thus, for the worm SLO-1 channel, the putative calcium-sensitive domains are critical for basal in vivo function but unnecessary for in vivo ethanol action.

Biochimica et Biophysica Acta (BBA) - Biomembranes

“…This channel was the second K + -selective channel for which a crystal structure was determined (after KcsA). Additional functional and structural studies revealed details of its activation mechanism, including the locations of Ca 2+ -binding sites at the cytosolic side of the channel that contribute to channel activation, as well as kinetic schemes to describe the allosteric mechanism of activation by cytosolic Ca 2+ and inhibition by H + [105, 107, 109, 180–182]. …”

Section: Key Questions Subject To Interdisciplinary Study In Ion Tmentioning

confidence: 99%

“…Originally used to characterize ion channels isolated and reconstituted from native tissues, however, planar lipid bilayers are gaining increasing importance in reporting electrical properties of membrane proteins overexpressed and purified from heterologous systems such has bacteria, yeast, or insect cells [95–103]. Bilayer recordings typically favor analysis of single ion channels, enabling assessment of scale and duration of individual opening and closing events on microsecond time scales [104–109]. …”

Section: Introductionmentioning

confidence: 99%

Permeating disciplines: Overcoming barriers between molecular simulations and classical structure-function approaches in biological ion transport

Howard¹,

Carnevale²,

Delemotte³

et al. 2018

Self Cite

Ion translocation across biological barriers is a fundamental requirement for life. In many cases, controlling this process-for example with neuroactive drugs-demands an understanding of rapid and reversible structural changes in membrane-embedded proteins, including ion channels and transporters. Classical approaches to electrophysiology and structural biology have provided valuable insights into several such proteins over macroscopic, often discontinuous scales of space and time. Integrating these observations into meaningful mechanistic models now relies increasingly on computational methods, particularly molecular dynamics simulations, while surfacing important challenges in data management and conceptual alignment. Here, we seek to provide contemporary context, concrete examples, and a look to the future for bridging disciplinary gaps in biological ion transport. This article is part of a Special Issue entitled: Beyond the Structure-Function Horizon of Membrane Proteins edited by Ute Hellmich, Rupak Doshi and Benjamin McIlwain.