Laboratory of Microbial Physiology, Institute of Molecular and Cellular Biology of Rosario, National Scientific and Technical Research Council, Rosario, Santa Fe, Argentina; Department of Microbiology, Faculty of Biochemical and Pharmaceutical Sciences, National University of Rosario, Rosario, Santa Fe, Argentina.
Laboratory of Microbial Physiology, Institute of Molecular and Cellular Biology of Rosario, National Scientific and Technical Research Council, Rosario, Santa Fe, Argentina; Department of Microbiology, Faculty of Biochemical and Pharmaceutical Sciences, National University of Rosario, Rosario, Santa Fe, Argentina.
J Biol Chem. 2020 Oct 30;295(44):14973-14986. doi: 10.1074/jbc.RA120.013760. Epub 2020 Aug 25.
Lipoic acid (LA) is a sulfur-containing cofactor that covalently binds to a variety of cognate enzymes that are essential for redox reactions in all three domains of life. Inherited mutations in the enzymes that make LA, namely lipoyl synthase, octanoyltransferase, and amidotransferase, result in devastating human metabolic disorders. Unfortunately, because many aspects of this essential pathway are still obscure, available treatments only serve to alleviate symptoms. We envisioned that the development of an organismal model system might provide new opportunities to interrogate LA biochemistry, biology, and physiology. Here we report our investigations on three orthologous proteins involved in this post-translational modification. We established that M01F1.3 is a lipoyl synthase, ZC410.7 an octanoyltransferase, and C45G3.3 an amidotransferase. Worms subjected to RNAi against and manifest larval arrest in the second generation. The arrest was not rescued by LA supplementation, indicating that endogenous synthesis of LA is essential for development. Expression of the enzymes M01F1.3, ZC410.7, and C45G3.3 completely rescue bacterial or yeast mutants affected in different steps of the lipoylation pathway, indicating functional overlap. Thus, we demonstrate that, similarly to humans, is able to synthesize LA via a lipoyl-relay pathway, and suggest that this nematode could be a valuable model to dissect the role of protein mislipoylation and to develop new therapies.
硫辛酸(LA)是一种含硫辅因子,与多种相关酶共价结合,这些酶对于所有三个生命领域的氧化还原反应都是必不可少的。使 LA 的酶(即 lipoyl 合酶、辛酰基转移酶和酰胺转移酶)发生遗传突变会导致严重的人类代谢紊乱。不幸的是,由于该必需途径的许多方面仍然不清楚,因此可用的治疗方法只能缓解症状。我们设想,开发一种生物体模型系统可能会为研究 LA 的生物化学、生物学和生理学提供新的机会。在这里,我们报告了我们对参与这种翻译后修饰的三个同源蛋白的研究。我们确定 M01F1.3 是 lipoyl 合酶,ZC410.7 是辛酰基转移酶,C45G3.3 是酰胺转移酶。针对 和 进行 RNAi 的蠕虫在第二代中表现出幼虫停滞。LA 补充并不能挽救停滞,表明内源性 LA 合成对于 发育是必需的。酶 M01F1.3、ZC410.7 和 C45G3.3 的表达完全挽救了细菌或酵母突变体在不同的脂酰化途径步骤中的缺陷,表明存在功能重叠。因此,我们证明,类似于人类, 能够通过脂酰基接力途径合成 LA,并且表明这种线虫可能是一个有价值的模型,可以剖析蛋白质错误脂酰化的作用,并开发新的治疗方法。
