一个位于Shaker钾离子通道两个门之间的永久性离子结合位点。
A permanent ion binding site located between two gates of the Shaker K+ channel.
作者信息
Harris R E, Larsson H P, Isacoff E Y
机构信息
Department of Molecular and Cell Biology, University of California, Berkeley 94720-3200, USA.
出版信息
Biophys J. 1998 Apr;74(4):1808-20. doi: 10.1016/s0006-3495(98)77891-9.
Abstract
K+ channels can be occupied by multiple permeant ions that appear to bind at discrete locations in the conduction pathway. Neither the molecular nature of the binding sites nor their relation to the activation or inactivation gates that control ion flow are well understood. We used the permeant ion Ba2+ as a K+ analog to probe for K+ ion binding sites and their relationship to the activation and inactivation gates. Our data are consistent with the existence of three single-file permeant-ion binding sites: one deep site, which binds Ba2+ with high affinity, and two more external sites whose occupancy influences Ba2+ movement to and from the deep site. All three sites are accessible to the external solution in channels with a closed activation gate, and the deep site lies between the activation gate and the C-type inactivation gate. We identify mutations in the P-region that disrupt two of the binding sites, as well as an energy barrier between the sites that may be part of the selectivity filter.
摘要
钾离子通道可被多个通透离子占据,这些离子似乎结合在传导通路中的离散位置。结合位点的分子性质及其与控制离子流动的激活或失活门的关系都还不太清楚。我们使用通透离子Ba2+作为钾离子类似物来探测钾离子结合位点及其与激活和失活门的关系。我们的数据与存在三个单排通透离子结合位点一致:一个深部位点,它以高亲和力结合Ba2+,还有两个更靠外的位点,它们的占据情况会影响Ba2+进出深部位点的移动。在激活门关闭的通道中,所有这三个位点都可与外部溶液接触,且深部位点位于激活门和C型失活门之间。我们鉴定出P区域中的突变,这些突变破坏了其中两个结合位点,以及位点之间可能作为选择性过滤器一部分的能量屏障。
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