Ken-Dror S, Lanyi J K, Schobert B, Silver B, Avi-Dor Y
Arch Biochem Biophys. 1986 Feb 1;244(2):766-72. doi: 10.1016/0003-9861(86)90645-4.
The rate of NADH oxidation by inverted membrane vesicles prepared from the halotolerant bacterium Ba1 of the Dead Sea is increased specifically by sodium ions, as observed earlier in whole cells. The site of this sodium effect is identified as the NADH: quinone oxidoreductase, similarly to the other such system known, Vibrio alginolyticus (H. Tokuda and T. Unemoto (1984) J. Biol. Chem. 259, 7785-7790). Sodium accelerates quinone reduction severalfold, but oxidation of the quinol, with oxygen as terminal electron acceptor, is unaffected. The sodium-dependent pathway of quinone reduction exhibits higher apparent affinity to extraneous quinone (Q-2) than the sodium-insensitive pathway, and is specifically inhibited by 2-heptyl-4-hydroxyquinoline N-oxide. ESR spectra of the membranes contain a feature at g = 1.98 which is tentatively identified as one originating from semiquinone. This feature is increased by NADH and decreased by addition of Na+, suggesting that, as proposed from different kinds of evidence for the V. alginolyticus system, sodium affects the semiquinone reduction step. As in the other system, the site of sodium stimulation in Ba1 probably corresponds to the site of sodium translocation, which was shown earlier (S. Ken-Dror, R. Shnaiderman, and Y. Avi-Dor (1984) Arch. Biochem. Biophys. 229, 640-649) to be linked directly to a redox reaction in the respiratory chain.
正如之前在完整细胞中观察到的那样,从死海盐耐受细菌巴氏芽孢杆菌1制备的反向膜囊泡对NADH的氧化速率会因钠离子而特异性增加。这种钠效应的位点被确定为NADH:醌氧化还原酶,类似于另一个已知的此类系统——溶藻弧菌(H. 德田和T. 上本(1984年)《生物化学杂志》259卷,7785 - 7790页)。钠能使醌还原加速数倍,但以氧气作为终端电子受体时,对醌醇的氧化没有影响。与不依赖钠的途径相比,依赖钠的醌还原途径对外源醌(Q - 2)表现出更高的表观亲和力,并且会被2 - 庚基 - 4 - 羟基喹啉N - 氧化物特异性抑制。膜的电子顺磁共振光谱在g = 1.98处有一个特征峰,初步确定为源自半醌。这个特征峰因NADH而增强,因添加Na⁺而减弱,这表明,正如从溶藻弧菌系统的不同证据所推断的那样,钠影响半醌还原步骤。与另一个系统一样,巴氏芽孢杆菌1中钠刺激的位点可能与钠转运的位点相对应,之前已表明(S. 肯 - 德罗尔、R. 施奈德曼和Y. 阿维 - 多尔(1984年)《生物化学与生物物理学报》229卷,640 - 649页)该位点与呼吸链中的氧化还原反应直接相关。
