Studies on energy supply for genetic processes. Requirement for membrane potential in Escherichia coli infection by phage T4.

E. Kalasauskaĭte, D. Kadisaite, R. Daugelavičius, L. Grinius, A. Jasaitis
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引用次数: 40

Abstract

In this study the hypothesis considering the requirement for an electrochemical proton gradient in the injection of phage T4 DNA into Escherichia coli cell has been verified experimentally. The phage caused a reversible depolarization of cell membrane, while phage 'ghosts' induced an irreversible depolarization. The phage infection was strictly dependent on E. coli membrane potential value when phage/cell ratio was 5 and higher. When the ratio was close to 1, the decrease in the membrane potential up to -100 mV caused practically no effect on the phage infection. The infection inhibition was observed when the membrane potential was lowered below this 'threshold' value. On the other hand, the decrease in the membrane potential caused no effect on the phage infection under conditions promoting a concomitant increase in the value of the transmembranous pH gradient. The phage DNA transfer through the membrane of ATPase-deficient cells was reversibly inhibited by switching off the respiratory chain - the sole generator of a protonmotive force in these mutant cells. The membrane should be kept in the energized state during the phage DNA entrance into the cell. Adsorption of the phage on E. coli was followed by the reversible release of the respiratory control. Thus the results presented here indicate the requirement of the electrochemical proton gradient across the plasma membrane for injection of phage T4 DNA into E. coli. They support the concept postulating an expenditure of host cell metabolic energy for phage T4 DNA transfer through the membrane.
遗传过程的能量供应研究。T4噬菌体感染大肠杆菌对膜电位的要求。
在本研究中,考虑到T4噬菌体DNA注射到大肠杆菌细胞中需要电化学质子梯度的假设得到了实验验证。噬菌体引起了细胞膜的可逆去极化,而噬菌体“幽灵”则引起了不可逆的去极化。当噬菌体/细胞比大于5时,噬菌体感染严格依赖于大肠杆菌膜电位值。当该比值接近1时,膜电位下降至-100 mV时,对噬菌体感染几乎没有影响。当膜电位低于该“阈值”时,观察到感染抑制。另一方面,在促进跨膜pH梯度值同时增加的条件下,膜电位的降低对噬菌体感染没有影响。通过关闭呼吸链(在这些突变细胞中唯一产生原动力的细胞),通过atp酶缺陷细胞的膜的噬菌体DNA转移被可逆地抑制。在噬菌体DNA进入细胞期间,膜应保持在通电状态。噬菌体在大肠杆菌上吸附后,呼吸控制因子可逆释放。因此,本文的结果表明,噬菌体T4 DNA注入大肠杆菌需要跨质膜的电化学质子梯度。他们支持宿主细胞代谢能量消耗的概念,噬菌体T4 DNA通过膜转移。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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