植物对病原微生物的“化学防御”: 植保素的生物合成及其分子调控机制

doi:10.13287/j.1001-9332.202007.018

摘要/Abstract

摘要： 植物可以合成大量的次生代谢物来调控自身对环境的适应性。其中,有一大部分直接参与了植物对病原微生物的防御反应,包括植物在感病前就已经生成和积累的植物毒素,以及感病后才从头合成的抗病小分子次生代谢物—植保素。植保素在植物抵御病原菌,特别是腐生性病原菌的过程中起着非常重要的作用。自从80年前植保素的概念被提出后,大量的植保素从各种植物中被分离和鉴定出来,但它们之中大部分的生物合成和调控机制目前尚不清楚。本文综述了近几年来拟南芥和烟草中植保素的研究进展,特别是它们的生物合成及分子调控机制,并对植保素研究领域存在的问题和今后的研究方向进行了讨论和展望。

关键词: 次生代谢物, 植保素, 亚麻荠素, 东莨菪素, 东莨菪苷, 椒二醇, 烟草, 拟南芥

Abstract: Plants can produce diverse groups of secondary metabolites to adapt to environment. Many secondary metabolites are involved in the defense responses against pathogenic microbes, including phytoanticipins which are low molecular weight anti-microbial compounds presented in plants before infection, and phytoalexins produced by plants de novo in response to pathogen attack. Phytoalexins are an important part of plant defense repertoire to pathogenic microbes, especially to necrotrophs. Since the concept of phytoalexin was proposed 80 years ago, many kinds of phytoalexins were identified. In contrast, the biosynthesis of most phytoalexins and their regulatory networks are largely unknown. In this review, I summarized recent research progress of phytoalexins in Arabidopsis and Nicotiana species, with special focus on molecular regulations of their biosynthesis. The problems and future directions in phytoalexin research were also discussed.

Key words: secondary metabolite, phytoalexin, camalexin, scopoletin, scopolin, capsidiol, nicotiana, arabidopsis

吴劲松. 植物对病原微生物的“化学防御”: 植保素的生物合成及其分子调控机制[J]. 应用生态学报, 2020, 31(7): 2161-2167.

WU Jinsong. The “chemical defense” of plants against pathogenic microbes: Phytoalexins biosynthesis and molecular regulations[J]. Chinese Journal of Applied Ecology, 2020, 31(7): 2161-2167.

参考文献

[1] Dixon RA, Strack D. Phytochemistry meets genome analysis, and beyond. Phytochemistry, 2003, 62: 815-816
[2] Dixon RA. Natural products and plant disease resistance. Nature 2001, 411: 843-847
[3] Hartmann M, Zeier T, Bernsdorff F, et al. Flavin monooxygenase-generated N-hydroxypipecolic acid is a critical element of plant systemic immunity. Cell, 2018, 173: 456-469
[4] Müller KO, Borger H. Experimental studies on the Phytopthora resistance of potatoes. A contribution to the problem of acquired resistance in the plants. Arbeiten der Biologischen Reichsanstalt für Land- und Forstwirtschaft, 1940, 23: 189-231
[5] VanEtten HD, Mansfield JW, Bailey JA, et al. Two classes of plant antibiotics: Phytoalexins versus “phytoanticipins”. The PlantCell, 1994, 6: 1191-1192
[6] Ahuja I, Kissen R, Bones AM. Phytoalexins in defense against pathogens. Trends in Plant Science, 2012, 17: 73-90
[7] 彭友良, 郝小江, 范军, 等. N-酰基色胺植保素衍生物的抗菌活性、诱导、分离与合成. 中国, 200202103940.2 [Peng Y-L, Hao X-J, Fang J, et al. Anti-fungal activity, induction, purification and synthesis of N-acyltryptamine phytoalexins. China, 20020210-3940.2]
[8] Browne LM, Conn KL, Ayer WA, et al. The camale-xins: New phytoalexins produced in the leaves of Camelina sativa (Cruciferae). Tetrahedron, 1991, 47: 3909-3914
[9] Glawischnig E. The role of cytochrome P450 enzymes in the biosynthesis of camalexin. Biochemical Society Transa-ctions, 2006, 34: 1206-1208
[10] Glawischnig E, Hansen BG, Olsen CE, et al. Camale-xin is synthesized from indole-3-acetaldoxime, a key branching point between primary and secondary metabolism in Arabidopsis. Proceedings of the National Academy of Sciences of the United States of America 2004, 101: 8245-8250
[11] Nafisi M, Goregaoker S, Botanga CJ, et al. Arabidopsis cytochrome P450 monooxygenase 71A13 catalyzes the conversion of indole-3-acetaldoxime in camalexin synthesis. The Plant Cell, 2007, 19: 2039-2052
[12] Muller TM, Bottcher C, Morbitzer R, et al. Transcription Activator-Like Effector Nuclease-mediated generation and metabolic analysis of camalexin-deficient cyp71a12 cyp71a13 double knockout lines. Plant Physio-logy, 2015, 168: 849-858
[13] Schuhegger R, Nafisi M, Mansourova M, et al. CYP71B15 (PAD3) catalyzes the final step in camale-xin biosynthesis. Plant Physiology, 2006, 141: 1248-1254
[14] Bottcher C, Westphal L, Schmotz C, et al. The multifunctional enzyme CYP71B15 (Phytoalexin Deficient3) converts cysteine-indole-3-acetonitrile to camalexin in the indole-3-acetonitrile metabolic network of Arabidopsis thaliana. The Plant Cell, 2009, 21: 1830-1845
[15] Parisy V, Poinssot B, Owsianowski L, et al. Identification of PAD2 as a gamma-glutamylcysteine synthetase highlights the importance of glutathione in disease resis-tance of Arabidopsis. Plant Journal, 2007, 49: 159-172
[16] Mucha S, Heinzlmeir S, Kriechbaumer V, et al. The formation of a camalexin biosynthetic metabolon. The Plant Cell, 2019, 31: 2697-2710
[17] Tsuji J, Jackson EP, Gage DA, et al. Phytoalexin accumulation in Arabidopsis thaliana during the hypersensitive reaction to Pseudomonas syringae pv syringae. Plant Physiology, 1992, 98: 1304-1309.
[18] Thomma BPHJ, Nelissen I, Eggermont K, et al. Deficiency in phytoalexin production causes enhanced susceptibility of Arabidopsis thaliana to the fungus Alterna-ria brassicicola. Plant Journal, 1999, 19: 163-171
[19] Schlaeppi K, Abou-Mansour E, Buchala A, et al. Disease resistance of Arabidopsis to Phytophthora brassicae is established by the sequential action of indole glucosinolates and camalexin. Plant Journal, 2010, 62: 840-851,.
[20] Stotz HU, Sawada Y, Shimada Y, et al. Role of camalexin, indole glucosinolates, and side chain modification of glucosinolate-derived isothiocyanates in defense of Arabidopsis against Sclerotinia sclerotiorum. Plant Journal, 2011, 67: 81-93
[21] Mao G, Meng X, Liu Y, et al. Phosphorylation of a WRKY transcription factor by two pathogen-responsive MAPKs drives phytoalexin biosynthesis in Arabidopsis. The Plant Cell, 2011, 23: 1639-1653
[22] Qiu JL, Fiil BK, Petersen K, et al. Arabidopsis MAP kinase 4 regulates gene expression through transcription factor release in the nucleus. EMBO Journal, 2008, 27: 2214-2221
[23] He Y, Xu J, Wang X, et al. The Arabidopsis pleiotropic drug resistance transporters PEN3 and PDR12 mediate camalexin secretion for resistance to Botrytis cinerea. The Plant Cell, 2019, 31: 2206-2222.
[24] Kai K, Mizutani M, Kawamura N, et al. Scopoletin is biosynthesized via ortho-hydroxylation of feruloyl CoA by a 2-oxoglutarate-dependent dioxygenase in Arabidopsis thaliana. Plant Journal, 2008, 55: 989-999
[25] El Oirdi M, Trapani A, Bouarab K. The nature of tobacco resistance against Botrytis cinerea depends on the infection structures of the pathogen. Environmental Microbiology, 2010, 12: 239-253
[26] Chong J, Baltz R, Schmitt C, et al. Downregulation of a pathogen-responsive tobacco UDP-Glc: Phenylpropanoid glucosyltransferase reduces scopoletin glucoside accumulation, enhances oxidative stress, and weakens virus resistance. The Plant Cell, 2002, 14: 1093-1107
[27] Wu J, Baldwin IT. New insights into plant responses to the attack from insect herbivores. Annual Review of Genetics, 2010, 44: 1-24
[28] LaMondia JA. Outbreak of brown spot of tobacco caused by Alternaria alternata in Connecticut and Massachusetts. Plant Disease, 2001, 85: 230, doi: 10.1094/pdis.2001.85.2.230b
[29] Song N, Ma L, Wang W, et al. An ERF2-like transcription factor regulates production of the defense sesquiterpene capsidiol upon Alternaria alternata infection. Journal of Experimental Botany, 2019, 70: 5895-5908
[30] Sun H, Song N, Ma L, et al. Ethylene signalling is essential for the resistance of Nicotiana attenuata against Alternaria alternata and phytoalexin scopoletin biosynthesis. Plant Pathology, 2017, 66: 277-284
[31] Li J, Wu J. Scopolin, a glycoside form of the phytoale-xin scopoletin, is likely involved in the resistance of Nicotiana attenuata against Alternaria alternata. Journal of Plant Pathology, 2016, 98: 641-644
[32] Sun H, Wang L, Zhang B, et al. Scopoletin is a phytoalexin against Alternaria alternata in wild tobacco depen-dent on jasmonate signalling. Journal of Experimental Botany, 2014, 65: 4305-4315
[33] Sun H, Hu X, Ma J, et al. Requirement of ABA signalling-mediated stomatal closure for resistance of wild tobacco to Alternaria alternata. Plant Pathology, 2014, 63: 1070-1077
[34] Wu J, Wang L, Baldwin IT. Methyl jasmonate-elicited herbivore resistance: Does MeJA function as a signal without being hydrolyzed to JA? Planta, 2008, 227: 1161-1168
[35] Ralston L, Kwon ST, Schoenbeck M, et al. Cloning, heterologous expression, and functional characterization of 5-epi-aristolochene-1,3-dihydroxylase from tobacco (Nicotiana tabacum). Archives of Biochemistry and Biophysics, 2001, 393: 222-235
[36] Facchini PJ, Chappell J. Gene family for an elicitor-induced sesquiterpene cyclase in tobacco. Proceedings of the National Academy of Sciences of the United States of America, 1992, 89: 11088-11092
[37] Stoessl A, Unwin CH, Ward EWB. Postinfectional inhibitors from plants I. Capsidiol, an antifungal compound from capsicum frutescens. Phytopathology, 1972, 74: 141-152
[38] Bailey JA, Burden RS, Vincent GG. Capsidiol: Antifungal compound produced in Nicotiana tabacum and Nicotiana clevelandii following infection with tobacco necrosis virus. Phytochemistry, 1975, 14: 597, doi: 10.1016/0031-9422(75)85148-X
[39] Milat ML, Ricci P, Bonnet P, et al. Capsidiol and ethy-lene production by tobacco cells in response to cryptogein, an elicitor from Phytophthora cryptogea. Phytochemistry, 1991, 30: 2171-2173
[40] Chappell J, Nable R. Induction of sesquiterpenoid biosynthesis in tobacco cell suspension cultures by fungal elicitor. Plant Physiology, 1987, 85: 469-473
[41] Shibata Y, Kawakita K, Takemoto D. Age-related resis-tance of Nicotiana benthamiana against hemibiotrophic pathogen Phytophthora infestans requires both ethylene- and salicylic acid-mediated signaling pathways. Molecular Plant-Microbe Interactions, 2010, 23: 1130-1142
[42] 石志琦. 蛇床子素作为杀菌剂的活性研究. 博士论文. 南京: 南京农业大学, 2008 [Shi Z-Q. A Study on Antifungal Activity of Osthol. PhD Thesis. Nanjing: Nanjing Agricultural University, 2008]
[43] 石志琦, 沈寿国, 徐朗莱, 等. 蛇床子素对植物病原真菌抑制机制的初步研究. 农药学学报, 2004, 6(4): 28-32 [Shi Z-Q, Shen S-G, Xu L-L, et al. Inhibition mechanism of osthol to plant fungus pathogens. Chinese Journal of Pesticide Science, 2004, 6(4): 28-32]
[44] 张紫佳, 张勉, 朱恩圆, 等. 丁公藤类药材及其混用品中总东莨菪内酯的含量测定. 中国药学杂志, 2004(12): 56-58 [Zhang Z-J, Zhang M, Zhu Y-Y, et al. Determination of total scopoletin in Caulis Erycibes and its adulterants. Chinese Pharmaceutical Journal, 2004(12): 56-58]
[45] 宋蔚, 刘锁兰, 李秀青, 等. HPLC测定4种丁公藤类生药中东莨菪素及东莨菪苷的含量.中国中药杂志, 2004(2): 94-95 [Song W, Liu S-L, Li X-Q, et al. Determination of scopoletin and scopolin in four Caulis Erycibes by HPLC. China Journal of Chinese Materia Medica, 2004(2): 94-95]
[46] Smoliga JM, Baur JA, Hausenblas HA. Resveratrol and health: A comprehensive review of human clinical trials. Molecular Nutrition & Food Research, 2011, 55: 1129-1141