Oxidative Processes and Xenobiotic Metabolism in Plants: Mechanisms of Defense and Potential Therapeutic Implications.

IF 6.8 Q1 TOXICOLOGY

Journal of Xenobiotics Pub Date : 2024-10-18 DOI:10.3390/jox14040084

Caterina Vicidomini, Rosanna Palumbo, Maria Moccia, Giovanni N Roviello

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引用次数: 0

Abstract

Plants are continuously exposed to environmental challenges, including pollutants, pesticides, and heavy metals, collectively termed xenobiotics. These substances induce oxidative stress by generating reactive oxygen species (ROS), which can damage cellular components such as lipids, proteins, and nucleic acids. To counteract this, plants have evolved complex metabolic pathways to detoxify and process these harmful compounds. Oxidative stress in plants primarily arises from the overproduction of hydrogen peroxide (H₂O₂), superoxide anions (O₂^•-), singlet oxygen (¹O₂), and hydroxyl radicals (^•OH), by-products of metabolic activities such as photosynthesis and respiration. The presence of xenobiotics leads to a notable increase in ROS, which can result in cellular damage and metabolic disruption. To combat this, plants have developed a strong antioxidant defense mechanism that includes enzymatic antioxidants that work together to eliminate ROS, thereby reducing their harmful effects. In addition to enzymatic defenses, plants also synthesize various non-enzymatic antioxidants, including flavonoids, phenolic acids, and vitamins. These compounds effectively neutralize ROS and help regenerate other antioxidants, offering extensive protection against oxidative stress. The metabolism of xenobiotic substances in plants occurs in three stages: the first involves modification, which refers to the chemical alteration of xenobiotics to make them less harmful. The second involves conjugation, where the modified xenobiotics are combined with other substances to increase their solubility, facilitating their elimination from the plant. The third stage involves compartmentalization, which is the storage or isolation of conjugated xenobiotics in specific parts of the plant, helping to prevent damage to vital cellular functions. Secondary metabolites found in plants, such as alkaloids, terpenoids, and flavonoids, play a vital role in detoxification and the defense against oxidative stress. Gaining a deeper understanding of the oxidative mechanisms and the pathways of xenobiotic metabolism in plants is essential, as this knowledge can lead to the formulation of plant-derived strategies aimed at alleviating the effects of environmental pollution and enhancing human health by improving detoxification and antioxidant capabilities, as discussed in this review.

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植物的氧化过程和异生物代谢：防御机制和潜在的治疗意义》（Mechanisms of Defense and Potential Therapeutic Implications）。

植物不断面临环境挑战，包括污染物、杀虫剂和重金属（统称为异种生物）。这些物质通过产生活性氧（ROS）诱发氧化应激，从而损害细胞成分，如脂类、蛋白质和核酸。为了应对这种情况，植物进化出了复杂的代谢途径来解毒和处理这些有害化合物。植物的氧化应激主要来自过氧化氢（H2O2）、超氧阴离子（O2--）、单线态氧（1O2）和羟自由基（-OH）的过度产生，它们是光合作用和呼吸作用等新陈代谢活动的副产品。异种生物的存在会导致 ROS 明显增加，从而造成细胞损伤和新陈代谢紊乱。为了应对这种情况，植物开发出了一种强大的抗氧化防御机制，其中包括酶抗氧化剂，它们共同消除 ROS，从而减少其有害影响。除了酶抗，植物还能合成各种非酶抗氧化剂，包括类黄酮、酚酸和维生素。这些化合物能有效中和 ROS，并帮助其他抗氧化剂再生，从而提供广泛的抗氧化保护。异生物物质在植物体内的新陈代谢分为三个阶段：第一阶段是修饰，即对异生物进行化学变化，使其危害性降低。第二阶段是共轭作用，即把经过修饰的异生物与其他物质结合在一起，以增加其溶解度，从而促进其从植物体内排出。第三阶段是分隔，即将共轭异生物储存或隔离在植物的特定部位，以防止对重要的细胞功能造成损害。植物中的次生代谢物，如生物碱、萜类化合物和黄酮类化合物，在解毒和抵御氧化压力方面发挥着重要作用。正如本综述所述，深入了解植物的氧化机制和异生物代谢途径至关重要，因为这些知识可以帮助制定植物衍生策略，通过提高解毒和抗氧化能力来减轻环境污染的影响和增进人类健康。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Xenobiotics TOXICOLOGY-

CiteScore

5.30

自引率

1.70%

发文量

审稿时长

10 weeks

期刊介绍： The Journal of Xenobiotics publishes original studies concerning the beneficial (pharmacology) and detrimental effects (toxicology) of xenobiotics in all organisms. A xenobiotic (“stranger to life”) is defined as a chemical that is not usually found at significant concentrations or expected to reside for long periods in organisms. In addition to man-made chemicals, natural products could also be of interest if they have potent biological properties, special medicinal properties or that a given organism is at risk of exposure in the environment. Topics dealing with abiotic- and biotic-based transformations in various media (xenobiochemistry) and environmental toxicology are also of interest. Areas of interests include the identification of key physical and chemical properties of molecules that predict biological effects and persistence in the environment; the molecular mode of action of xenobiotics; biochemical and physiological interactions leading to change in organism health; pathophysiological interactions of natural and synthetic chemicals; development of biochemical indicators including new “-omics” approaches to identify biomarkers of exposure or effects for xenobiotics.