豚鼠心室肌细胞中核苷二磷酸激活ATP敏感性钾通道的机制
On the mechanism of nucleotide diphosphate activation of the ATP-sensitive K+ channel in ventricular cell of guinea-pig.
作者信息
Tung R T, Kurachi Y
机构信息
Department of Internal Medicine, Mayo Clinic, Rochester, MN 55905.
出版信息
J Physiol. 1991 Jun;437:239-56. doi: 10.1113/jphysiol.1991.sp018593.
Abstract
- Effects of intracellular nucleotide diphosphates (NDPs) on the ATP-sensitive K+ channel (K+ATP channel) were examined in ventricular cells of guinea-pig heart, using the inside-out patch clamp technique. On formation of inside-out patches in the ATP-free internal solution, the K+ATP channel appeared and then ran down spontaneously. This run-down of the K+ATP channel activity was probably due to dephosphorylation. 2. Millimolar concentrations of various NDPs, e.g. UDP (uridine diphosphate), IDP (inosine diphosphate), CDP (cytidine diphosphate) and GDP (guanosine diphosphate), applied to the internal side of the patch membrane, induced openings of the K+ATP channel after run-down, i.e. in the dephosphorylated state. ADP opened the channel weakly at low concentrations (100 microM) but inhibited it at higher concentrations (1-10 mM). 3. NDP-induced openings of the channel were Mg2+ dependent and inhibited by ATP (100 microM) and glibenclamide (1 microM). None of nucleosides, nucleotide monophosphates nor nucleotide triphosphates induced openings of the channel. Thus, the K+ATP channel may have a Mg(2+)-dependent NDP-binding site, which induces openings of the dephosphorylated channel in ATP-free solution, in addition to the Mg(2+)-independent ATP-binding inactivation site and phosphorylation site. 4. In inside-out patches, pinacidil (a K+ATP channel opener) activated the K+ATP channel in the phosphorylated state but not in the dephosphorylated state. In the presence of NDPs (UDP, IDP, CDP, GDP), however, pinacidil (30 microM) enhanced openings of the dephosphorylated K+ATP channel prominently. 5. From the above results, we concluded that NDP-binding to the specific site has similar effects to channel phosphorylation, i.e. it keeps the K+ATP channel in an operative state in ATP-free solution and enhances the pinacidil-induced channel openings.
摘要
- 运用内面向外式膜片钳技术,在豚鼠心室肌细胞中研究了细胞内核苷酸二磷酸(NDPs)对ATP敏感性钾通道(K⁺ATP通道)的影响。在无ATP的细胞内溶液中形成内面向外式膜片时,K⁺ATP通道出现,随后自发衰减。K⁺ATP通道活性的这种衰减可能是由于去磷酸化作用。2. 向膜片内侧施加毫摩尔浓度的各种NDPs,如UDP(尿苷二磷酸)、IDP(肌苷二磷酸)、CDP(胞苷二磷酸)和GDP(鸟苷二磷酸),在通道衰减后,即处于去磷酸化状态时,可诱导K⁺ATP通道开放。ADP在低浓度(100μM)时可微弱地开放通道,但在高浓度(1 - 10 mM)时则抑制通道开放。3. NDP诱导的通道开放依赖于Mg²⁺,并受到ATP(100μM)和格列本脲(1μM)的抑制。核苷、核苷酸单磷酸和核苷酸三磷酸均不能诱导通道开放。因此,K⁺ATP通道除了有不依赖Mg²⁺的ATP结合失活位点和磷酸化位点外,可能还有一个依赖Mg²⁺的NDP结合位点,该位点在无ATP溶液中可诱导去磷酸化通道开放。4. 在内面向外式膜片中,吡那地尔(一种K⁺ATP通道开放剂)可激活磷酸化状态的K⁺ATP通道,但不能激活去磷酸化状态的通道。然而,在存在NDPs(UDP、IDP、CDP、GDP)时,吡那地尔(30μM)可显著增强去磷酸化K⁺ATP通道的开放。5. 根据上述结果,我们得出结论:NDP与特定位点的结合具有与通道磷酸化类似的作用,即在无ATP溶液中使K⁺ATP通道保持在可操作状态,并增强吡那地尔诱导的通道开放。
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