铁及其与细胞内酚类代谢物的络合:从氧化应激到化学武器。
Iron and its complexation by phenolic cellular metabolites: from oxidative stress to chemical weapons.
机构信息
Department of Chemical Ecology and Ecosystem Research, Faculty of Life Sciences, University of Vienna, Vienna, Austria.
出版信息
Plant Signal Behav. 2010 Jan;5(1):4-8. doi: 10.4161/psb.5.1.10197.
Abstract
Iron is a transition metal that forms chelates and complexes with various organic compounds, also with phenolic plant secondary metabolites. The ligands of iron affect the redox potential of iron. Electrons may be transferred either to hydroxyl radicals, hydrogen peroxide or molecular oxygen. In the first case, oxidative stress is decreased, in the latter two cases, oxidative stress is increased. This milieu-dependent mode of action may explain the non-linear mode of action of juglone and other secondary metabolites. Attention to this phenomenon may help to explain idiosyncratic and often nonlinear effects that result in biological assays. Current chemical assays are discussed that help to explore these aspects of redox chemistry.
摘要
铁是一种过渡金属,它与各种有机化合物形成螯合物和配合物,也与酚类植物次生代谢物形成螯合物和配合物。铁的配体影响铁的氧化还原电位。电子可以转移到羟基自由基、过氧化氢或分子氧。在前一种情况下,氧化应激减少,在后两种情况下,氧化应激增加。这种依赖环境的作用模式可以解释胡桃醌和其他次生代谢物的非线性作用模式。关注这一现象可能有助于解释导致生物测定出现特异性且通常是非线性的作用。目前讨论了有助于探索这些氧化还原化学方面的化学分析方法。
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