Cooley Jason W, Roberts Arthur G, Bowman Michael K, Kramer David M, Daldal Fevzi
Department of Biology, Institute for Plant Sciences, University of Pennsylvania, Philadelphia, Pennsylvania 19104-6018, USA.
Biochemistry. 2004 Mar 2;43(8):2217-27. doi: 10.1021/bi035938u.
We have previously reported that mutant strains of Rhodobacter capsulatus that have alanine insertions (+nAla mutants) in the hinge region of the iron sulfur (Fe-S) containing subunit of the bc(1) complex have increased redox midpoint potentials (E(m)) for their [2Fe2S] clusters. The alteration of the E(m) in these strains, which contain mutations far from the metal binding site, implied that the local environment of the metal center is indirectly altered by a change in the interaction of this subunit with the hydroquinone oxidizing (Q(o)) site [Darrouzet, E., Valkova-Valchanova, M., and Daldal, F. (2002) J. Biol. Chem. 277, 3464-3470]. Subsequently, the E(m) changes have been proposed to be predominantly due to a stronger or more stabilized hydrogen bonding between the reduced [2Fe2S] cluster and the Q(o) site inhabitant ubiquinone (Q) [Shinkarev, V. P., Kolling, D. R. J., Miller, T. J., and Crofts, A. R. (2002) Biochemistry 41, 14372-14382]. To further investigate this issue, Fe-S protein-Q interactions were monitored by electron paramagnetic resonance (EPR) spectroscopy and the findings indicated that the wild type and mutant proteins interactions with Q are similar. Moreover, when the Q(pool) was chemically depleted, the E(m) of the [2Fe2S] cluster in mutant bc(1) complexes remained more positive than a similarly treated native enzyme (e.g., the [2Fe2S] E(m) of the +2Ala mutant was 55 mV more positive than the wild type). These data suggest that the increased E(m) of the [2Fe2S] cluster in the +nAla mutants is in part due to the cluster's interaction with Q, and in part to additional factors that are independent of hydrogen bonding to Q. One such factor, the possibility of a different position of the Fe-S at the Q(o) site of the mutant proteins versus the native enzyme, was addressed by determining the orientation of the [2Fe2S] cluster in the membrane using EPR spectroscopy. In the case of the +2Ala mutant, the [2Fe2S] cluster orientation in the absence of inhibitor is different than that seen in the native enzyme. However, the +2Ala mutant cluster shared a similar orientation with the native enzyme when both samples were exposed to either stigmatellin or myxothiazol. In addition, Q(pool) extracted membranes of +2Ala mutant exhibited fewer overall orientations, with the predominant one being more similar to that observed in the non-Q-depleted membranes of the +2Ala mutant than the Q-depleted membranes of a wild-type strain. Therefore, additional component(s) that are independent of Q(o) site inhabitants and that originate from the newly observed orientations of the [2Fe2S] clusters in the +nAla mutants also contribute to the increased midpoint potentials of their [2Fe2S] clusters. While the molecular basis of these components remains to be determined, salient implications of these findings in terms of Q(o) site catalysis are discussed.
我们之前报道过,红假单胞菌的突变菌株在bc(1)复合物含铁硫(Fe-S)亚基的铰链区有丙氨酸插入(+nAla突变体),其[2Fe2S]簇的氧化还原中点电位(E(m))升高。这些菌株中E(m)的改变,其突变位点远离金属结合位点,这意味着金属中心的局部环境通过该亚基与对苯二酚氧化(Q(o))位点相互作用的变化而间接改变[达鲁泽,E.,瓦尔科娃 - 瓦尔恰诺娃,M.,和达尔达尔,F.(2002年)《生物化学杂志》277,3464 - 3470]。随后,有人提出E(m)的变化主要是由于还原态的[2Fe2S]簇与Q(o)位点的驻留泛醌(Q)之间更强或更稳定的氢键作用[申卡列夫,V. P.,科林,D. R. J.,米勒,T. J.,和克罗夫茨,A. R.(2002年)《生物化学》41,14372 - 14382]。为了进一步研究这个问题,通过电子顺磁共振(EPR)光谱监测了Fe-S蛋白与Q的相互作用,结果表明野生型和突变型蛋白与Q的相互作用相似。此外,当Q(pool)被化学耗尽时,突变型bc(1)复合物中[2Fe2S]簇的E(m)仍比经类似处理的天然酶更正(例如,+2Ala突变体的[2Fe2S] E(m)比野生型高55 mV)。这些数据表明,+nAla突变体中[2Fe2S]簇E(m)升高部分是由于该簇与Q的相互作用,部分是由于与Q氢键无关的其他因素。其中一个因素,即突变型蛋白与天然酶相比,Fe-S在Q(o)位点可能有不同位置,通过EPR光谱确定膜中[2Fe2S]簇的方向来进行研究。对于+2Ala突变体,在没有抑制剂的情况下,[2Fe2S]簇的方向与天然酶不同。然而,当两个样品都暴露于抑霉素或粘噻唑时,+2Ala突变体簇与天然酶具有相似的方向。此外,+2Ala突变体的Q(pool)提取膜显示出更少的总体方向,主要方向与+2Ala突变体未耗尽Q的膜中观察到的方向比与野生型菌株耗尽Q的膜中观察到的方向更相似。因此,独立于Q(o)位点驻留物且源自+nAla突变体中[2Fe2S]簇新观察到的方向的其他成分也导致其[2Fe2S]簇中点电位升高。虽然这些成分的分子基础仍有待确定,但讨论了这些发现对Q(o)位点催化的显著影响。
