Gnipová Anna, Panicucci Brian, Paris Zdeněk, Verner Zdeněk, Horváth Anton, Lukeš Julius, Zíková Alena
Institute of Parasitology, Biology Centre, České Budějovice, Czech Republic.
Mol Biochem Parasitol. 2012 Aug;184(2):90-8. doi: 10.1016/j.molbiopara.2012.04.013. Epub 2012 May 5.
The Trypanosoma brucei cytochrome c oxidase (respiratory complex IV) is a very divergent complex containing a surprisingly high number of trypanosomatid-specific subunits with unknown function. To gain insight into the functional organization of this large protein complex, the expression of three novel subunits (TbCOX VII, TbCOX X and TbCOX 6080) were down-regulated by RNA interference. We demonstrate that all three subunits are important for the proper function of complex IV and the growth of the procyclic stage of T. brucei. These phenotypes were manifested by the structural instability of the complex when these indispensible subunits were repressed. Furthermore, the impairment of cytochrome c oxidase resulted in other severe mitochondrial phenotypes, such as a decreased mitochondrial membrane potential, reduced ATP production via oxidative phoshorylation and redirection of oxygen consumption to the trypanosome-specific alternative oxidase, TAO. Interestingly, the inspected subunits revealed some disparate phenotypes, particularly regarding the activity of cytochrome c reductase (respiratory complex III). While the activity of complex III was down-regulated in RNAi induced cells for TbCOX X and TbCOX 6080, the TbCOX VII silenced cell line actually exhibited higher levels of complex III activity and elevated levels of ROS formation. This result suggests that the examined subunits may have different functional roles within complex IV of T. brucei, perhaps involving the ability to communicate between sequential enzymes in the respiratory chain. In summary, by characterizing the function of three hypothetical components of complex IV, we are able to assign these proteins as genuine and indispensable subunits of the procyclic T. brucei cytochrome c oxidase, an essential component of the respiratory chain in these evolutionary ancestral and medically important parasites.
布氏锥虫细胞色素c氧化酶(呼吸复合体IV)是一种非常独特的复合体,含有数量惊人的功能未知的锥虫特异性亚基。为深入了解这种大型蛋白质复合体的功能组织,通过RNA干扰下调了三个新亚基(TbCOX VII、TbCOX X和TbCOX 6080)的表达。我们证明这三个亚基对于复合体IV的正常功能以及布氏锥虫前循环期的生长都很重要。当这些不可或缺的亚基受到抑制时,这些表型通过复合体的结构不稳定性表现出来。此外,细胞色素c氧化酶的损伤导致了其他严重的线粒体表型,如线粒体膜电位降低、通过氧化磷酸化产生的ATP减少以及耗氧转向锥虫特异性替代氧化酶TAO。有趣的是,所检测的亚基显示出一些不同的表型,特别是在细胞色素c还原酶(呼吸复合体III)的活性方面。虽然在针对TbCOX X和TbCOX 6080的RNA干扰诱导细胞中复合体III的活性下调,但TbCOX VII沉默细胞系实际上表现出更高水平的复合体III活性和更高水平的活性氧形成。这一结果表明,所检测的亚基在布氏锥虫复合体IV中可能具有不同的功能作用,也许涉及呼吸链中顺序酶之间的通讯能力。总之,通过表征复合体IV的三个假设组分的功能,我们能够将这些蛋白质确定为布氏锥虫前循环期细胞色素c氧化酶的真正且不可或缺的亚基,而细胞色素c氧化酶是这些进化上古老且具有医学重要性的寄生虫呼吸链的重要组成部分。
