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用叶片和根系的蛋白质组图谱评估 Mn 对幼年可可植株 Cd 毒性的缓解作用。

Mitigation of Cd toxicity by Mn in young plants of cacao, evaluated by the proteomic profiles of leaves and roots.

机构信息

Department of Biological Sciences, State University of Santa Cruz, Rodovia Jorge Amado, km 16, Ilhéus, BA, 45662-900, Brazil.

USDA-ARS-Beltsville Agricultural Research Center, Beltsville, MD, USA.

出版信息

Ecotoxicology. 2020 Apr;29(3):340-358. doi: 10.1007/s10646-020-02178-4. Epub 2020 Feb 27.

DOI:10.1007/s10646-020-02178-4
PMID:32107699
Abstract

Cd is a non-essential metal and highly toxic to plants, animals and humans, even at very low concentrations. Cd has been found in cocoa beans and in their products, as in the case of chocolate. Mn plays an important role in photosynthetic and can interact with Cd and attenuate its toxic effects on plants. The objective of this work was to evaluate the mechanisms of Mn response in the mitigation of Cd toxicity in young plants of the CCN 51 cacao genotype submitted to 0.8 mmol Cd kg, 1.6 mmol Mn kg or the combination of 0.4 mmol Cd kg + 0.8 mmol Mn kg soil, together with the control treatment (without addition of Cd and Mn in soil), by means of analysis of changes in the profile of exclusive proteins (EP) and differentially accumulated proteins (DAP). Leaf and root proteins were extracted and quantified from the different treatments, followed by proteomic analysis. About eight DAP and 38 EP were identified in leaves, whereas in roots 43 DAP and 21 EP were identified. Some important proteins induced in the presence of Cd and repressed in the presence of Cd + Mn or vice versa, were ATPases, isoflavone reductase, proteasome and chaperonin. It was concluded that proteins involved in oxidoreduction and defense and stress response processes, in addition to other processes, were induced in the presence of Cd and repressed in the presence of Cd + Mn. This demonstrated that Mn was able to mitigate the toxic effects of Cd on young plants of the CCN 51 cocoa genotype.

摘要

镉是一种非必需的重金属,对植物、动物和人类都有剧毒,即使浓度非常低也是如此。在可可豆及其产品中发现了镉,如巧克力。锰在光合作用中起着重要作用,可以与镉相互作用,减轻其对植物的毒性影响。本工作的目的是评估 Mn 响应机制在缓解 0.8mmol Cd kg、1.6mmol Mn kg 或 0.4mmol Cd kg+0.8mmol Mn kg 土壤中添加 Cd 和 Mn 对年轻可可 CCN 51 基因型植物的毒性中的作用,通过分析专享蛋白 (EP) 和差异积累蛋白 (DAP) 的变化来实现。从不同处理中提取和定量叶片和根蛋白,然后进行蛋白质组学分析。在叶片中鉴定出约 8 种 DAP 和 38 种 EP,而在根中鉴定出 43 种 DAP 和 21 种 EP。一些在 Cd 存在下诱导的重要蛋白,在 Cd+Mn 存在下被抑制,或者反之亦然,这些蛋白包括 ATP 酶、异黄酮还原酶、蛋白酶体和伴侣蛋白。结论是,参与氧化还原和防御以及应激反应过程的蛋白,除了其他过程外,在 Cd 存在下被诱导,而在 Cd+Mn 存在下被抑制。这表明 Mn 能够减轻 Cd 对年轻可可 CCN 51 基因型植物的毒性影响。

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