纠正通道视紫红质的早期电导率。
Rectification of the channelrhodopsin early conductance.
机构信息
A.-v.-Haller-Institut der Universität, Göttingen, Germany.
出版信息
Biophys J. 2011 Sep 7;101(5):1057-68. doi: 10.1016/j.bpj.2011.07.040.
Abstract
We analyzed the nonlinear current-voltage relationships of the early conducting state of channelrhodopsin-2 expressed in Xenopus oocytes and human embryonic kidney cells with respect to changes of the electrochemical gradients of H(+), Na(+)/K(+), and Ca(2+)/Mg(2+). Several models were tested for wild-type ChR2 and mutations at positions E90, E123, H134, and T159. Voltage-gating was excluded as cause for the nonlinearity. However, a general enzyme kinetic model with one predominant binding site yielded good fits throughout. The empty site with an apparent charge number of about -0.3 and strong external cation binding causes some inward rectification of the uniport function. Additional inward rectification is due to asymmetric competition from outside between the transported ion species. Significant improvement of the fits was achieved by introducing an elastic voltage-divider formed by the voltage-sensitive barriers.
摘要
我们分析了在非洲爪蟾卵母细胞和人胚肾细胞中表达的通道视紫红质-2 的早期导通电-压关系,以了解 H(+)、Na(+)/K(+)和 Ca(2+)/Mg(2+)电化学梯度的变化。我们测试了野生型 ChR2 以及 E90、E123、H134 和 T159 位置突变的几种模型。电压门控被排除为非线性的原因。然而,具有一个主要结合位点的通用酶动力学模型在整个过程中都能得到很好的拟合。空位点的表观电荷数约为-0.3,对外界阳离子的结合能力很强,导致单通道功能的内向整流。由于转运离子的外部不对称竞争,进一步导致内向整流。通过引入由电压敏感屏障形成的弹性电压分配器,可以显著提高拟合度。
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