Dorokhov Yuri L, Sheshukova Ekaterina V, Komarova Tatiana V
N.I. Vavilov Institute of General Genetics, Russian Academy of Sciences, Moscow, Russia.
A.N. Belozersky Institute of Physico-Chemical Biology, Lomonosov Moscow State University, Moscow, Russia.
Front Plant Sci. 2018 Nov 9;9:1623. doi: 10.3389/fpls.2018.01623. eCollection 2018.
Until recently, plant-emitted methanol was considered a biochemical by-product, but studies in the last decade have revealed its role as a signal molecule in plant-plant and plant-animal communication. Moreover, methanol participates in metabolic biochemical processes during growth and development. The purpose of this review is to determine the impact of methanol on the growth and immunity of plants. Plants generate methanol in the reaction of the demethylation of macromolecules including DNA and proteins, but the main source of plant-derived methanol is cell wall pectins, which are demethylesterified by pectin methylesterases (PMEs). Methanol emissions increase in response to mechanical wounding or other stresses due to damage of the cell wall, which is the main source of methanol production. Gaseous methanol from the wounded plant induces defense reactions in intact leaves of the same and neighboring plants, activating so-called methanol-inducible genes (MIGs) that regulate plant resistance to biotic and abiotic factors. Since PMEs are the key enzymes in methanol production, their expression increases in response to wounding, but after elimination of the stress factor effects, the plant cell should return to the original state. The amount of functional PMEs in the cell is strictly regulated at both the gene and protein levels. There is negative feedback between one of the MIGs, aldose epimerase-like protein, and gene transcription; moreover, the enzymatic activity of PMEs is modulated and controlled by PME inhibitors (PMEIs), which are also induced in response to pathogenic attack.
直到最近,植物释放的甲醇还被认为是一种生化副产物,但过去十年的研究揭示了它在植物与植物、植物与动物交流中作为信号分子的作用。此外,甲醇在植物生长发育过程中参与代谢生化过程。本综述的目的是确定甲醇对植物生长和免疫的影响。植物在包括DNA和蛋白质在内的大分子去甲基化反应中产生甲醇,但植物源性甲醇的主要来源是细胞壁果胶,果胶被果胶甲酯酶(PMEs)去甲基酯化。由于细胞壁受损,机械损伤或其他胁迫会导致甲醇排放增加,而细胞壁是甲醇产生的主要来源。受伤植物释放的气态甲醇会在同一植株和相邻植株的完整叶片中诱导防御反应,激活所谓的甲醇诱导基因(MIGs),这些基因调节植物对生物和非生物因子的抗性。由于PMEs是甲醇产生的关键酶,它们的表达会因受伤而增加,但在消除胁迫因子影响后,植物细胞应恢复到原始状态。细胞中功能性PMEs的数量在基因和蛋白质水平上都受到严格调控。甲醇诱导基因之一醛糖表异构酶样蛋白与基因转录之间存在负反馈;此外,PMEs的酶活性由PME抑制剂(PMEIs)调节和控制,PMEIs也会在病原体攻击时被诱导产生。
