Robert Leach scite author profile

The glycine-tyrosine-glycine (GYG) sequence in the p-loop of K+ channel subunits lines a narrow pore through which K+ ions pass in single file intercalated by water molecules. Mutation of the motif can give rise to non-selective channels, but it is clear that other structural features are also required for selectivity because, for instance, a recently identified class of cyclic nucleotide-gated pacemaker channels has the GYG motif but are poorly K+ selective. We show that mutation of charged glutamate and arginine residues behind the selectivity filter in the Kir3.1/Kir3.4 K+ channel reduces or abolishes K+ selectivity, comparable with previously reported effects in the Kir2.1 K+ channel. It has been suggested that a salt bridge exists between the glutamate-arginine residue pair. Molecular modeling indicates that the salt bridge does exist, and that it acts as a "bowstring" to maintain the rigid bow-like structure of the selectivity filter and restrict selectivity to K+. The modeling shows that relaxation of the bowstring by mutation of the residue pair leads to enhanced flexibility of the p-loop, allowing permeation of other cations, including polyamines. In experiments, mutation of the residue pair can also abolish polyamine-induced inward rectification. The latter effect occurs because polyamines now permeate rather than block the channel, to the remarkable extent that large polyamine currents can be measured.

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European Society For Emergency Medicine position paper on emergency medical systems’ response to COVID-19

Garcı́a-Castrillo

Petrino

Leach

et al. 2020

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The 2019 novel coronavirus acute respiratory epidemic is creating a stressed situation in all the health systems of the affected countries. Emergency medical systems and specifically the emergency departments as the front line of the health systems are suffering from overload and severe working conditions, the risk of contagion and transmission of the health professionals adds a substantial burden to their daily work. Under the perspective of European Society For Emergency Medicine, the recommendations provided by the health authorities are reviewed focus on the emergency department's activity.

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Inhibition of the K⁺ channel Kv1.4 by acidosis: protonation of an extracellular histidine slows the recovery from N‐type inactivation

Claydon

Boyett

Sivaprasadarao

et al. 2000

The Journal of Physiology

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Acidosis alters the transient outward current, ito, in the heart. We have studied the mechanism underlying the effect of acidosis on one of the K+ channels, Kv1.4 (heterologously expressed in Xenopus laevis oocytes), known to underlie ito. At pH 6.5, wild‐type Kv1.4 current was inhibited during repetitive pulsing, in part as a result of a slowing of recovery from N‐type inactivation. Acidosis still caused slowing of recovery after deletion of just one (either the first or second) of the N‐terminal inactivation ball domains. However, deletion of both the N‐terminal inactivation ball domains greatly reduced the inhibition. As well as the N‐terminus, other parts of the channel are also required for the effect of acidosis, because, whereas the transfer of the N‐terminus of Kv1.4 to Kv1.2 conferred N‐type inactivation, it did not confer acidosis sensitivity. Replacement of an extracellular histidine with a glutamine residue (H508Q) abolished the slowing of recovery by acidosis. Reduction of C‐type inactivation by raising the bathing K+ concentration or by the mutation K532Y also abolished the slowing. It is concluded that binding of protons to H508 enhances C‐type inactivation and this causes a slowing of recovery from N‐type inactivation and, thus, an inhibition of current during repetitive pulsing.

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Effects of ACh and adenosine mediated by Kir3.1 and Kir3.4 on ferret ventricular cells

Dobrzynski

Janvier

Leach

et al. 2002

American Journal of Physiology-Heart and Circulatory Physiology

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The inotropic effects of ACh and adenosine on ferret ventricular cells were investigated with the action potential-clamp technique. Under current clamp, both agonists resulted in action potential shortening and a decrease in contraction. Under action potential clamp, both agonists failed to decrease contraction substantially. In the absence of agonist, application of the short action potential waveform (recorded previously in the presence of agonist) also resulted in a decrease in contraction. Under action potential clamp, application of ACh resulted in a Ba2+-sensitive outward current with the characteristics of muscarinic K+ current ( I K,ACh); the presence of the muscarinic K+ channel was confirmed by PCR and immunocytochemistry. In the absence of agonist, on application of the short ACh action potential waveform, the decrease in contraction was accompanied by loss of the inward Na+/Ca2+exchange current ( I NaCa). ACh also inhibited the background inward K+ current ( I K,1). It is concluded that ACh activates I K,ACh, inhibits I K,1, and indirectly inhibits I NaCa; this results in action potential shortening, decrease in contraction, and, as a result of the inhibition of I K,1, minimum decrease in excitability.

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Approaching acute pain in emergency settings; European Society for Emergency Medicine (EUSEM) guidelines—part 2: management and recommendations

et al. 2020

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Robert Leach

Molecular Basis of Ion Selectivity, Block, and Rectification of the Inward Rectifier Kir3.1/Kir3.4 K+ Channel

European Society For Emergency Medicine position paper on emergency medical systems’ response to COVID-19

Inhibition of the K⁺ channel Kv1.4 by acidosis: protonation of an extracellular histidine slows the recovery from N‐type inactivation

Effects of ACh and adenosine mediated by Kir3.1 and Kir3.4 on ferret ventricular cells

Approaching acute pain in emergency settings; European Society for Emergency Medicine (EUSEM) guidelines—part 2: management and recommendations

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Robert Leach

Molecular Basis of Ion Selectivity, Block, and Rectification of the Inward Rectifier Kir3.1/Kir3.4 K+ Channel

European Society For Emergency Medicine position paper on emergency medical systems’ response to COVID-19

Inhibition of the K+ channel Kv1.4 by acidosis: protonation of an extracellular histidine slows the recovery from N‐type inactivation

Effects of ACh and adenosine mediated by Kir3.1 and Kir3.4 on ferret ventricular cells

Approaching acute pain in emergency settings; European Society for Emergency Medicine (EUSEM) guidelines—part 2: management and recommendations

Contact Info

Product

Resources

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Inhibition of the K⁺ channel Kv1.4 by acidosis: protonation of an extracellular histidine slows the recovery from N‐type inactivation