Metal ion effects on ion channel gating

Elinder, Fredrik; Århem, Peter

doi:10.1017/s0033583504003932

Cited by 85 publications

(93 citation statements)

References 241 publications

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“…We have previously identified charged residues that contribute to j out and to V 1/2 (13,15,48). However, we have not been able to completely transfer the effective surface charges from a metal-ion sensitive channel to a relatively metal ion-insensitive channel.…”

Section: Strontium Effects On Seven Wild-type Kv Channelsmentioning

confidence: 84%

“…Based on the model of Gouy and Chapman (26,27), the Grahame equation (28) describes the relation between surface charge and surface potential in terms of the ionic composition of the solution. Even though this equation is based on the simplistic assumption of smeared surface charges it has been shown that it rather well describes the surface potential of a plane with moderately spread out point charges (29) and thus that of most ion channels (15). Approximating the Grahame equation, as shown in the Appendix, we obtain the following:…”

Section: Introductionmentioning

confidence: 94%

“…V 1/2 has been shown to depend on the existence of certain charged residues on the external surface of the channel protein (11)(12)(13), suggesting these charges contribute to an electric potential at the external surface (14)(15)(16). Metal ions were early recognized to alter the excitability of neurons by shifting the G(V) curve of ion channels along the voltage axis (17)(18)(19)(20).…”

Section: Introductionmentioning

confidence: 99%

“…Metal ions were early recognized to alter the excitability of neurons by shifting the G(V) curve of ion channels along the voltage axis (17)(18)(19)(20). For certain metal ions most of this effect is likely to be caused by screening (i.e., damping the electric field by mobile charges rather than by bound charges) of the critical negative charges at the external surface of the channel protein, modifying 4 out at the voltage sensor (14,15,20). Thus, such metal ions can be used as probes to explore the external surface potential.…”

Section: Introductionmentioning

confidence: 99%

“…This fact provides us with a tool to test the validity of the screening hypothesis. In our study we used the strontium ion (Sr 2þ ) as probe, because it seems to act exclusively via a screening mechanism; together with the magnesium ion (Mg 2þ ), it shifts the G(V) curve less than other tested metal ions, and activation time courses, deactivation time courses, gating currents, and G(V) curves are equally affected, as if these metal ions only alter the membrane voltage (11,15,21,22,(33)(34)(35)(36).…”

Section: Introductionmentioning

confidence: 99%

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Extracellular Linkers Completely Transplant the Voltage Dependence from Kv1.2 Ion Channels to Kv2.1

Elinder

Madeja

Zeberg

et al. 2016

Biophysical Journal

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The transmembrane voltage needed to open different voltage-gated K (Kv) channels differs by up to 50 mV from each other. In this study we test the hypothesis that the channels' voltage dependences to a large extent are set by charged amino-acid residues of the extracellular linkers of the Kv channels, which electrostatically affect the charged amino-acid residues of the voltage sensor S4. Extracellular cations shift the conductance-versus-voltage curve, G(V), by interfering with these extracellular charges. We have explored these issues by analyzing the effects of the divalent strontium ion (Sr 2þ ) on the voltage dependence of the G(V) curves of wild-type and chimeric Kv channels expressed in Xenopus oocytes, using the voltage-clamp technique. Out of seven Kv channels, Kv1.2 was found to be most sensitive to Sr 2þ (50 mM shifted G(V) by þ21.7 mV), and Kv2.1 to be the least sensitive (þ7.8 mV). Experiments on 25 chimeras, constructed from Kv1.2 and Kv2.1, showed that the large Sr 2þ -induced G(V) shift of Kv1.2 can be transferred to Kv2.1 by exchanging the extracellular linker between S3 and S4 (L3/4) in combination with either the extracellular linker between S5 and the pore (L5/P) or that between the pore and S6 (LP/6). The effects of the linker substitutions were nonadditive, suggesting specific structural interactions. The free energy of these interactions was~20 kJ/mol, suggesting involvement of hydrophobic interactions and/or hydrogen bonds. Using principles from double-layer theory we derived an approximate linear equation (relating the voltage shifts to altered ionic strength), which proved to well match experimental data, suggesting that Sr 2þ acts on these channels mainly by screening surface charges. Taken together, these results highlight the extracellular surface potential at the voltage sensor as an important determinant of the channels' voltage dependence, making the extracellular linkers essential targets for evolutionary selection.

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Section: Strontium Effects On Seven Wild-type Kv Channelsmentioning

confidence: 84%

Section: Introductionmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Extracellular Linkers Completely Transplant the Voltage Dependence from Kv1.2 Ion Channels to Kv2.1

Elinder

Madeja

Zeberg

et al. 2016

Biophysical Journal

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Voltage‐Gated Proton Channels

DeCoursey

2012

Comprehensive Physiology

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Voltage‐gated proton channels, H V 1, have vaulted from the realm of the esoteric into the forefront of a central question facing ion channel biophysicists, namely, the mechanism by which voltage‐dependent gating occurs. This transformation is the result of several factors. Identification of the gene in 2006 revealed that proton channels are homologues of the voltage‐sensing domain of most other voltage‐gated ion channels. Unique, or at least eccentric, properties of proton channels include dimeric architecture with dual conduction pathways, perfect proton selectivity, a single‐channel conductance approximately 10 3 times smaller than most ion channels, voltage‐dependent gating that is strongly modulated by the pH gradient, ΔpH, and potent inhibition by Zn 2+ (in many species) but an absence of other potent inhibitors. The recent identification of H V 1 in three unicellular marine plankton species has dramatically expanded the phylogenetic family tree. Interest in proton channels in their own right has increased as important physiological roles have been identified in many cells. Proton channels trigger the bioluminescent flash of dinoflagellates, facilitate calcification by coccolithophores, regulate pH‐dependent processes in eggs and sperm during fertilization, secrete acid to control the pH of airway fluids, facilitate histamine secretion by basophils, and play a signaling role in facilitating B‐cell receptor mediated responses in B‐lymphocytes. The most elaborate and best‐established functions occur in phagocytes, where proton channels optimize the activity of NADPH oxidase, an important producer of reactive oxygen species. Proton efflux mediated by H V 1 balances the charge translocated across the membrane by electrons through NADPH oxidase, minimizes changes in cytoplasmic and phagosomal pH, limits osmotic swelling of the phagosome, and provides substrate H + for the production of H 2 O 2 and HOCl, reactive oxygen species crucial to killing pathogens. © 2012 American Physiological Society. Compr Physiol 2:1355‐1385, 2012.

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Molecular neurochemistry of the lanthanides

Pałasz

Segovia

Skowronek

et al. 2019

Synapse

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Lanthanides, once termed rare‐earth elements, are not as sparce in the environment as their traditional name suggests. Mean litospheric concentrations are in fact comparable to the physiologically fundamental elements such as iodine, cobalt, and selenium. Recent advances in medical technology have resulted in accumulation of lanthanides presenting potential exposure to both our central and peripheral nervous systems. Extensive and detailed studies on these peculiar active metals in the context of their influence on neural functions are therefore urgently required. Almost all neurochemical effects of trivalent lanthanide ions appear to result from the similarity of their radii to the key signaling ion calcium. Lanthanides, especially La3+ and Gd3+ block different types of calcium, potassium, and sodium channels in human and animal neurons, regulate neurotransmitter turnover and release, as well as synaptic activity. Lanthanides also act as modulators of several ionotropic receptors, e.g., GABA, NMDA, and kainate and can also affect numerous signaling mechanisms including NF‐κB and apoptotic‐related endoplasmic reticulum IRE1‐XBP1, PERK, and ATF6 pathways. Several lanthanide ions may cause oxidative neuronal injuries and functional impairment by promoting reactive oxygen species production. However, cerium and yttrium oxides have some unique and promising neuroprotective properties, being able to decrease free radical cell injury and even alleviate motor impairment and cognitive function in animal models of multiple sclerosis and mild traumatic brain damage, respectively. In conclusion, lanthanides affect various neurophysiological processes, altering a large spectrum of brain functions. Thus, a deeper understanding of their potential mechanistic roles during disease and as therapeutic agents requires urgent elucidation.

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Metal ion effects on ion channel gating

Cited by 85 publications

References 241 publications

Extracellular Linkers Completely Transplant the Voltage Dependence from Kv1.2 Ion Channels to Kv2.1

Extracellular Linkers Completely Transplant the Voltage Dependence from Kv1.2 Ion Channels to Kv2.1

Voltage‐Gated Proton Channels

Molecular neurochemistry of the lanthanides

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