Jin-Mei Yu scite author profile

Jin-Mei Yu

2Publications

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Beijing Institute of Petrochemical Technology

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External Ba2+ Block of the Two-pore Domain Potassium Channel TREK-1 Defines Conformational Transition in Its Selectivity Filter

Zhang

et al. 2011

Journal of Biological Chemistry

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TREK-1 is a member of the two-pore domain potassium channel family that is known as a leak channel and plays a key role in many physiological and pathological processes. The conformational transition of the selectivity filter is considered as an effective strategy for potassium channels to control the course of potassium efflux. It is well known that TREK-1 is regulated by a large volume of extracellular and intracellular signals. However, until now, little was known about the selectivity filter gating mechanism of the channel. In this research, it was found that Ba 2؉ blocked the TREK-1 channel in a concentration-and timedependent manner. A mutagenesis analysis showed that overlapped binding of Ba 2؉ at the assumed K ؉ binding site 4 (S4) within the selectivity filter was responsible for the inhibitory effects on TREK-1. Then, Ba 2؉ was used as a probe to explore the conformational transition in the selectivity filter of the channel. It was confirmed that collapsed conformations were induced by extracellular K ؉ -free and acidification at the selectivity filters, leading to nonconductive to permeable ions. Further detailed characterization demonstrated that the two conformations presented different properties. Additionally, the N-terminal truncated isoform (⌬N41), a product derived from alternative translation initiation, was identified as a constitutively nonconductive variant. Together, these results illustrate the important role of selectivity filter gating in the regulation of TREK-1 by the extracellular K ؉ and proton.Potassium channels are ubiquitous pore-forming transmembrane proteins that transport K ϩ ions selectively and rapidly across the biological membranes. The efflux of K ϩ ions is controlled not only by the electrochemical gradient, but also by the gating mechanism. Along the ion conduction pathway of potassium channels, three structures are arranged from intercellular to extracellular: the lower activation gate, the selectivity filter (SF) 2 , and the upper inactivation gate (also termed the C-type inactivation gate). Correspondingly, there are mainly two kinds of mechanisms controlling K ϩ ion passage. Manipulation of the lower activation gate controls the transition between the open and close state of the channel. The upper inactivation gate, which is characterized by slow kinetics, controls the transition between conduction and nonconduction of the pore. The selectivity filter of the K ϩ channels, formed by the highly conserved sequence TV(I)GY(F)G, plays a pivotal role in both mechanisms. Accumulating evidence shows that the selectivity filter itself has the ability to act as the inactivation gate (1-4). High resolution crystallographic analysis has revealed detailed structural changes in the selectivity filter associated with the activation gating and inactivation gating (5, 6). The carbonyl oxygens together with the side chain hydroxyl oxygen of the threonine define four equally spaced ion-binding sites that are commonly termed S1-S4, from the extracellular to the intracellular region (7)...

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Effects of Ouabain, DBcAMP, Caffeine, and High (Ca2+)o on Twitch Tension, Intracellular Na+ Activity, and Action Potential of Guinea Pig Papillary Muscles.

Yang

Lee²,

Yu³

1992

JJP

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To explore ionic mechanisms of the positive inotropic process in guinea pig ventricular papillary muscles, we simultaneously measured twitch tension, intracellular Na+ activity (aiNa) and action potential at a stimulus rate of 60/min. The aiNa was 5.0 +/- 0.1 mM in the steady state. When the Na-K pump was inhibited by ouabain (1 microM), the twitch tension was increased in proportion to the aiNa, and the action potential was decreased at diastolic state and at duration for 90% of repolarization (APD90). While exposed to caffeine (3 mM), the aiNa kept increasing even when the twitch tension achieved a peak level. Concomitantly, the action potential slightly depolarized at diastolic state with a prolonged APD90. An application of DBcAMP (1 mM) or an increase in [Ca2+]o (from 1.8 to 3.6 mM) enhanced the twitch tension with a fall of aiNa and a shortening of APD90. These results suggest that in guinea pig papillary muscles Na-Ca exchange plays an important role in the regulation of contractile force and membrane potential, and that the Na influx should be balanced by the activation of the sarcolemmal Na-K pump, a negative feedback mechanism, to prevent calcium overload and abnormal pacemaker activity in electrical excitation.

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Jin-Mei Yu

External Ba2+ Block of the Two-pore Domain Potassium Channel TREK-1 Defines Conformational Transition in Its Selectivity Filter

Effects of Ouabain, DBcAMP, Caffeine, and High (Ca2+)o on Twitch Tension, Intracellular Na+ Activity, and Action Potential of Guinea Pig Papillary Muscles.

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