Samartzidou H, Delcour A H
Department of Biology, University of Houston, Houston, TX 77204-5513, USA.
EMBO J. 1998 Jan 2;17(1):93-100. doi: 10.1093/emboj/17.1.93.
We used patch clamp analysis to compare the electrophysiological behavior of two related porins from Escherichia coli, the anion-specific PhoE and the cation-selective OmpF. Outer membrane fractions were obtained from strains expressing just one of these porin types, and the channels were reconstituted into liposomes without prior purification. We show that the orientation of the reconstituted channels is not random and is the same for both PhoE and OmpF. Like cation-selective porins, PhoE shows fast and slow gating to closed levels of various amplitudes, testifying that the channels visit multiple functional states and behave as cooperative entities. The voltage-dependence of PhoE closure is asymmetric, but strikingly, occurs at voltages of inverse polarity from those promoting closures of OmpC and OmpF. Both slow kinetics and inverse voltage-dependence are removed when 70 amino acids from the N-terminal of OmpF are introduced into the homologous region of PhoE. This novel observation regarding the voltage-dependence of the two channel types, along with published results on PhoE and OmpF mutants, allows us to propose a molecular mechanism for voltage sensing and sensor charge movements in bacterial porins. It also offers new cues on the possible physiological relevance in bacteria of this common form of channel modulation.
我们使用膜片钳分析来比较来自大肠杆菌的两种相关孔蛋白的电生理行为,即阴离子特异性的PhoE和阳离子选择性的OmpF。外膜组分从仅表达其中一种孔蛋白类型的菌株中获得,并且通道在没有预先纯化的情况下被重构到脂质体中。我们表明,重构通道的取向不是随机的,并且PhoE和OmpF的取向相同。与阳离子选择性孔蛋白一样,PhoE表现出快速和缓慢的门控至各种幅度的关闭水平,证明通道会进入多种功能状态并表现为协同实体。PhoE关闭的电压依赖性是不对称的,但令人惊讶的是,其发生的电压极性与促进OmpC和OmpF关闭的电压极性相反。当将来自OmpF N端的70个氨基酸引入PhoE的同源区域时,慢速动力学和反向电压依赖性都被消除。关于这两种通道类型电压依赖性的这一新发现,以及关于PhoE和OmpF突变体的已发表结果,使我们能够提出细菌孔蛋白中电压传感和传感器电荷移动的分子机制。它还为这种常见的通道调节形式在细菌中的可能生理相关性提供了新线索。