硫苷介导的白菜抵御甜菜夜蛾幼虫取食胁迫的分子机制

郝娇娇; 马永华; 陆彦池; 许丽爱; 朱祝军; 郁有健

doi:10.11833/j.issn.2095-0756.20220172

硫苷介导的白菜抵御甜菜夜蛾幼虫取食胁迫的分子机制

doi: 10.11833/j.issn.2095-0756.20220172

浙江农林大学园艺科学学院浙江省山区农业高效绿色协同生产创新中心/农业农村部亚热带果品蔬菜质量安全控制重点实验室，浙江杭州 311300

基金项目: 国家自然科学基金面上资助项目(32072557，31572115)；浙江省自然科学基金重点资助项目(LZ14C150001)

详细信息

作者简介: 郝娇娇(ORCID: 0000-0001-5049-799x)，从事园艺作物栽培生理与品质调控研究。E-mail: 2407605896@qq.com

通信作者: 朱祝军(ORCID: 0000-0001-8551-7751 )，教授，从事园艺作物栽培生理与品质调控研究。E-mail: zhuzj@zafu.edu.cn

中图分类号: S603

Molecular mechanism of glucosinolate-mediated Brassica campestris ssp. chinensis against feeding stress of Spodoptera exigua larvae

Innovation Center of Agricultural Effcient and Green Collaborative Production of Zhejiang Province/Key Laboratory of Quality and Safety Control for Subtropical Fruit and Vegetable, Ministry of Agriculture and Rural Affairs, College of Horticulture Science, Zhejiang A&F University, Hangzhou 311300, Zhejiang, China

摘要: 目的探究甜菜夜蛾Spodoptera exigua幼虫取食对白菜Brassica campestris ssp. chinensis硫代葡萄糖苷质量摩尔浓度及组分的影响，初步明确硫苷介导的白菜抵御甜菜夜蛾幼虫取食胁迫的分子机制。方法使用高效液相色谱法检测甜菜夜蛾幼虫取食对白菜硫苷质量摩尔浓度和组分的影响，实时荧光定量聚合酶链式反应(RT-qPCR)分析硫苷代谢关键基因表达模式的变化，谷胱甘肽硫转移酶试剂盒检测取食白菜后甜菜夜蛾幼虫体内谷胱甘肽硫转移酶活性的变化。结果白菜中8种硫苷组分在甜菜夜蛾幼虫取食后显著增加(P＜0.05)，其中吲哚族的4-羟基吲哚-3-甲基硫苷(4OH)、1-甲氧基-3-吲哚基甲基硫苷(NEO)、3-吲哚基甲基(GBC)和脂肪族的4-戊烯基硫苷(GBN)对甜菜夜蛾幼虫取食反应最为强烈；RT-qPCR结果显示：甜菜夜蛾幼虫取食后，白菜脂肪族硫苷合成相关基因BcBCAT4、BcMAM1的显著上调可能与脂肪族硫苷的增加有关(P＜0.05)，而BcSOT16的上调与4OH、NEO、GBC呈正相关；取食后，甜菜夜蛾幼虫体内谷胱甘肽硫转移酶活性显著增强(P＜0.05)，并呈现与总硫苷和吲哚族硫苷质量摩尔浓度变化规律的一致性。结论甜菜夜蛾幼虫的取食能诱导白菜硫苷的合成，而硫苷质量摩尔浓度的升高会诱导幼虫体内谷胱甘肽硫转移酶活性的增强。甜菜夜蛾幼虫取食胁迫下，白菜BcSOT16、BcBCAT4、BcMAM1等硫苷合成关键基因被激活，4OH、NEO、GBC和GBN显著增加，从而更好地抵御甜菜夜蛾幼虫取食胁迫。图2表3参43
- 硫代葡萄糖苷 /
- 白菜 /
- 甜菜夜蛾 /
- 基因表达 /
- 谷胱甘肽硫转移酶
Abstract: Objective With an investigation of the effects of Spodoptera exigua larvae feeding on the content and components of glucosinolates (GSLs) in Brassica campestris ssp. chinensis, this study is aimed to figure out the initial molecular mechanism of GSL-mediated resistance to the feeding stress of S. exigua larvae in B. campestris ssp. chinensis. Method The effect of larvae feeding on the content and components of GSLs in B. campestris ssp. chinensis ‘Meiduheiyoutong’was determined with the application of high performance liquid chromatography before an analysis was conducted of the expression patterns of key genes related to GSLs metabolism using real-time fluorescence quantitative polymerase chain reaction (RT-qPCR), after which the activity of glutathione S-transferase (GSTs) in larvae after eating B. campestris ssp. chinensis was detected by GSTs kit. Result (1) Of the eight GSLs that enjoyed a significant increase in B. campestris ssp. chinensis after S. exigua larvae’ s feeding, 4-hydroxy-glucobrassicin (4OH), 1-methoxy-glucobrassici (NEO), glucobrassicin (GBC) and glucobrassicanapin (GBN) were the four important GSLs responsive to the feeding; (2) The significant up-regulation of aliphatic GSL synthesis-related genes BcBCAT4 and BcMAM1 in B. campestris ssp. chinensis might be related to the increase of aliphatic GSLs, and the up-regulation of BcSOT16 was positively correlated with 4OH, NEO and GBC after feeding by S. exigua larvae; (3) After feeding, the activity of GSTs in the larvae of S. exigua was significantly enhanced (P＜0.05), and showed a consistency with the changes of the total GSLs and indole GSLs. Conclusion Feeding by S. exigua larvae can induce the synthesis of GSLs in B. campestris ssp. chinensis, and the increase of GSLs can induce the enhancement of GSTs activity in larvae. Under the feeding stress of S. exigua larvae, the activation of key GSLs synthesis genes such as BcSOT16, BcBCAT4 and BcMAM1in B. campestris ssp. chinensis may promote the increase of 4OH, NEO, GBC and GBN which will help better resist S. exigua larvae feeding stress. [Ch, 2 fig. 3 tab. 43 ref.]
- glucosinolates /
- Brassica campestris ssp. chinensis /
- Spodoptera exigua /
- gene expression /
- glutathione S-transferase

图 1 甜菜夜蛾幼虫取食对白菜硫苷代谢关键基因表达模式的影响

Figure 1 Effects of S. exigua larvae feeding on expression patterns of key genes related to glucosinolates metabolism in B. campestris ssp. chinensis

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图 2 取食白菜后甜菜夜蛾幼虫GSTs活性的变化　　　　　

Figure 2 Changes of GSTs activity in S. exigua larve after feeding on B. campestris ssp. chinensis

下载: 全尺寸图片幻灯片

表 1 实时荧光定量PCR(RT-qPCR)表达分析引物序列

Table 1. Primer sequences for RT-qPCR analysis

基因名称	上游引物(5 ＇→3 ＇)	下游引物(5 ＇→3 ＇)
BcMAM1	CCAGAGTACATACCGCACAA	AGAGGACACCGGAAAACCAA
BcCYP83A1	AGTTCTCCTCTTCTTCCTCT	CCATTGTTTGACTTCCTATC
BcCYP83B1	ACACTTCCTCTTTCGTCTCT	CATCGTTTGTTGCCCCTTCA
BcMYB28	GAGAATTTGCATTCCCTTGC	TGGTGTCCCATCTTTGTTGG
BcSOT16	GGGTTATGGGTTTAGTGCTG	CTCCAACCTTCCCTTTCCTA
BcUBC10	GGGTCCTACAGACAGTCCTTAC	ATGGAACACCTTCGTCCTAAA
BcAPK2	CAACACCGTCTGGGATCTGC	AACCGACATCGACACCTGGA
BcSUR1	GGCGTTATCTACATGCTGTTCG	CAGGTGCGGAAGCAAGGGTA
BcAOP2	TGGATTTGCACCAAAGGAAA	AGATAGATCACTGGAAGTTG
BcBCAT4	AAGCAACTCGACTCAAACACT	CGATAAAACCCGAATCCTAAT

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表 2 白菜硫苷组分

Table 2. Components of glucosinolate in B. campestris ssp. chinensis

化合物名称	缩写	所属类别	分子量	保留时间/min
2-羟基-3-丁烯基硫苷progoitrin	PRO	脂肪族	388	7.790
3-丁烯基硫苷gluconapin	GNA	脂肪族	372	14.480
4-羟基吲哚-3-甲基硫苷4-OH-glucobrassicin	4OH	吲哚族	463	17.067
4-戊烯基硫苷glucobrassicanapin	GBN	脂肪族	386	22.087
3-吲哚基甲基硫苷glucobrassicin	GBC	吲哚族	447	26.753
2-苯乙基硫苷gluconasturtiin	NAS	芳香族	422	31.497
4-甲氧基-3-吲哚基甲基硫苷4-methoxy-glucobrassicin	4ME	吲哚族	477	32.433
1-甲氧基-3-吲哚基甲基硫苷1-methoxy-glucobrassicin	NEO	吲哚族	477	40.793

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表 3 甜菜夜蛾幼虫取食对白菜硫苷质量摩尔浓度的影响

Table 3. Effects of feeding on the content of glucosinolate in B. campestris ssp. chinensis by S. exigua larvae

类型	化合物缩写	硫苷质量摩尔浓度/(µmol·g⁻¹)
类型	化合物缩写	0 (ck)	1	24	48	72 h
脂肪族	GNA	0.154±0.010 b	0.174±0.005 b	0.220±0.003 c	0.132±0.003 a	0.132±0.002 a
	PRO	0.152±0.003 a	0.150±0.002 a	0.176±0.001 b	0.182±0.002 c	0.179±0.001 bc
	GBN	0.434±0.032 a	0.466±0.009 a	0.550±0.018 b	0.819±0.004 c	0.781±0.001 c
总脂肪族		0.724±0.009 a	0.792±0.001 b	0.959±0.008 c	1.132±0.002 e	1.116±0.004 d
吲哚族	4OH	0.157±0.012 a	0.177±0.003 b	0.222±0.004 c	0.257±0.006 d	0.234±0.004 c
	GBC	0.044±0.013 a	0.062±0.000 b	0.105±0.003 c	0.130±0.001 d	0.209±0.005 e
	4ME	0.089±0.026 a	0.69±0.000 a	0.140±0.003 b	0.154±0.002 b	0.135±0.000 b
	NEO	0.054±0.011 a	0.067±0.001 b	0.092±0.001 c	0.162±0.003 d	0.263±0.001 e
总吲哚族		0.351±0.001 a	0.375±0.001 b	0.565±0.005 c	0.703±0.010 d	0.840±0.008 e
芳香族	NAS	0.096±0.004 ab	0.109±0.002 c	0.142±0.001 d	0.086±0.001 a	0.101±0.002 bc
总硫苷		1.154±0.003 a	1.277±0.002 b	1.664±0.014 c	1.921±0.011 d	2.032±0.014 e
说明：同行不同小写字母表示同一指标不同时间差异显著(P＜0.05)

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[1]	徐园园, 李竹帛, 周贺芳, 等. 不结球白菜 BrABF1 基因的克隆与功能分析[J]. 核农学报, 2021, 35(10): 2241 − 2249. XU Yuanyuan, LI Zhubo, ZHOU Hefang, et al. Cloning and functional analysis of BrABF1 gene in non-heading Chinese cabbage [J]. Journal Nuclear Agricultural Science, 2021, 35(10): 2241 − 2249.
[2]	BLAZEV I, MONTAUT S, BURCUL F, et al. Glucosinolate structural diversity, identification, chemical synthesis and metabolism in plants[J/OL]. Phytochemistry, 2020, 169, 112100 [2022-01-20]. doi:10.1016/j.phytochem.2019.112100.
[3]	AGERBIRK N, OLSEN C E. Glucosinolate structures in evolution [J]. Phytochemistry, 2012, 77: 16 − 45.
[4]	SONDERBY I E, GEU-FLORES F, HALKIER B A. Biosynthesis of glucosinolates-gene discovery and beyond [J]. Trends in Plant Science, 2010, 15(5): 283 − 290.
[5]	KECK A S, FINLEY J W. Cruciferous vegetables: cancer protective mechanisms of glucosinolate hydrolysis products and selenium [J]. Integrative Cancer Therapies, 2004, 3(1): 5 − 12.
[6]	BONGONI R, VERKERK R, STEENBEKKERS B, et al. Evaluation of different cooking conditions on broccoli (Brassica oleracea var. italica) to improve the nutritional value and consumer acceptance [J]. Plant Foods for Human Nutrition, 2014, 69(3): 228 − 234.
[7]	NOVOTNY C, SCHULZOVA V, KRMELA A, et al. Ascorbic acid and glucosinolate levels in new czech cabbage cultivars: effect of production system and fungal infection[J/OL]. Molecules, 2018, 23(8): 1855[2022-02-03]. doi: 10.3390/molecules23081855.
[8]	MUGFORD S G, YOSHHIMOTO N, REICHELT M, et al. Disruption of adenosine-59-phosphosulfate kinase in arabidopsis reduces levels of sulfated secondary metabolites [J]. The Plant Cell, 2009, 21(3): 910 − 927.
[9]	RASK L, ANDREASSON E, EKBOM B, et al. Myrosinase: gene family evolution and herbivore defense in Brassicaceae [J]. Plant Molecular Biology, 2000, 42(1): 93 − 113.
[10]	KOS M, HOUSHYANI B, WIETSMA R, et al. Effects of glucosinolates on a generalist and specialist leaf-chewing herbivore and an associated parasitoid [J]. Phytochemistry, 2012, 77(1): 162 − 170.
[11]	张园园. 油菜和拟南芥中几个硫代葡萄糖苷合成及调控基因的功能分析[D]. 武汉: 华中农业大学, 2007. ZHANG Yuanyuan. Function Analyses of Several Genes Involved in Biosynthesis and Regulation of Glucosinolate in Brassica napus and Arabidopsis thaliana[D]. Wuhan: Huazhong Agricultural University, 2007.
[12]	CHHAJED S, MOSTAFA I, HE Y, et al. Glucosinolate biosynthesis and the glucosinolate-myrosinase system in plant defense[J/OL]. Agronomy, 2020, 10(11): 1786[2022-02-03] . doi: 10.3390/agronomy10111786.
[13]	HOPKINS R J, van DAM N M V, van LOON J J. Role of glucosinolates in insect-plant relationships and multitrophic interactions [J]. Annual Review Entomology, 2009, 54: 57 − 83.
[14]	SANTOLAMAZZA-CARBONE S, SOTELO T, VELASCO P, et al. Antibiotic properties of the glucosinolates of Brassica oleracea var. acephala similarly affect generalist and specialist larvae of two lepidopteran pests[J]. Journal of Pest Science, 89(1): 195 − 206.
[15]	BADENES-PEREZ F R, REICHELT M, GERSHENZON J, et al. Interaction of glucosinolate content of Arabidopsis thaliana mutant lines and feeding and oviposition by generalist and specialist lepidopterans [J]. Phytochemistry, 2013, 86: 36 − 43.
[16]	AUGUSTINE R, BISHT N C. Biotic elicitors and mechanical damage mod-ulate glucosinolate accumulation by co-ordinated interplay of glucosinolate biosynthesis regulators in polyploid Brassica juncea [J]. Phytochemistry, 2015, 117(1): 43 − 50.
[17]	BORGES A, ABREU A C, FERREIRA C, et al. Antibacterial activity and mode of action of selected glucosinolate hydrolysis products against bacterial pathogens [J]. Journal of Food Science &Technology, 2015, 52(8): 4737 − 4748.
[18]	LAMOTTE O, JEANDROZ S. Plant responses to biotic/abiotic stresses: lessons from cell signaling[J/OL]. Frontiers in Plant Science 2017, 8: 1772[2022-02-03]. doi:10.3389/fpls.2017.01772.
[19]	SONTOWSKI R, GORRINGE N J, PENCS S, et al. Same difference? low and high glucosinolate Brassica rapa varieties show similar responses upon feeding by two specialist root herbivores[J/OL]. Frontiers in Plant Science, 2019, 10: 1451[2022-02-03]. doi: 10.3389/fpls.2019.01451.
[20]	MEWIS I, TOKUHISA J G, SCHULTA J C, et al. Gene expression and glucosinolate accumulation in Arabidopsis thaliana in response to generalist and specialist herbivores of different feeding guilds and the role of defense signaling pathways [J]. Phytochemistry, 2006, 67(22): 2450 − 2462.
[21]	KOORNNEEF M, ALONSO-BLANCO C, VREUGDENHIL D. Naturally occurring genetic variation in Arabidopsis thaliana [J]. Annual Review of Plant Biology, 2004, 55(1): 141 − 172.
[22]	KUHLMANN F, MULLER C. Independent responses to ultraviolet radiation and herbivore attack in Broccoli [J]. Journl of Experimental Botany, 2009, 60(12): 3467 − 3475.
[23]	PFALZ M, VOGEL H, KROYMANN J. The gene controlling the indole glucosinolate modifier1 quantitative trait locus alters indole glucosinolate structures and aphid resistance in Arabidopsis [J]. The Plant Cell, 2009, 21(3): 985 − 999.
[24]	陈澄宇, 康志娇, 史雪岩, 等. 昆虫对植物次生物质的代谢适应机制及其对昆虫抗药性的意义[J]. 昆虫学报, 2015, 58(10): 1126 − 1139. CHEN Dengyu, KAMNG Zhijiao, SHI Xueyan, et al. Metabolic adaptation mechanisms of insects to plant secondary metabolites and their implications for insecticide resistance of insects [J]. Acta Entomologica Sinica, 2015, 58(10): 1126 − 1139.
[25]	KRUMBEIN A, SCHONHOF I, SCHREINER M. Composition and contents of phytochemicals (glucosinolates, carotenoids and chlorophylls) and ascorbic acid in selected Brassica species (B. juncea, B. rapa subsp. nipposinica var. chinoleifera, B. rapa subsp. chinensis and B. rapa subsp. rapa) [J]. Journal of Applied Botany &Food Quality, 2005, 79(3): 168 − 174.
[26]	ZHU Biao, YANG Jing, HE Yong, et al. Glucosinolate accumulation and related gene expression in pak choi (Brassica rapa L. ssp. chinensis var. communis [N. Tsen & S.H. Lee] Hanelt) in response to insecticide application [J]. Journal of Agricultural &Food Chemistry,, 2015, 63(44): 9683 − 9689.
[27]	BJÖRKMAN M, KLINGEN I, BIRCH A N, et al. Phytochemicals of Brassicaceae in plant protection and human health-Influences of climate, environment and agronomic practice [J]. Phytochemistry, 2011, 72(7): 538 − 556.
[28]	LIANG Ying, YU Youjian, SHEN X Piuping, et al. Dissecting the complex molecular evolution and expression of polygalacturonase gene family in Brassica rapa ssp. chinensis [J]. Plant Molecular Biology, 2015, 89(6): 629 − 646.
[29]	LIVAK K J, SCHMITTGEN T D. Analysis of relative gene expression data using real-time quantitative PCR and the \begin{document}$2^{- \Delta \Delta C_{t}} $\end{document} method [J]. Methods, 2001, 25: 402 − 408.
[30]	KIM J H, DURRETT T P, LAST R L, et al. Characterization of the Arabidopsis TU8 glucosinolate mutation, an allele of TERMINAL FLOWER2 [J]. Plant Molecular Biology, 2004, 54(5): 671 − 682.
[31]	MALITSKY S, BLUM E, LESS H, et al. The transcript and metabolite networks affected by the two clades of Arabidopsis glucosinolate biosynthesis regulators [J]. Plant Physiology, 2008, 148(4): 2021 − 2049.
[32]	MÜLLER R, de VOS M, SUN J Y, et al. Differential effects of indole and aliphatic glucosinolates on lepidopteran herbivores [J]. Journal of Chemical Ecology, 2010, 36(8): 905 − 913.
[33]	ZHUROV V, NAVARRO M, BRUINSMA K A, et al. Reciprocal responses in the interaction between Arabidopsis and the cell-content-feeding chelicerate herbivore spider mite [J]. Plant Physiology, 2014, 164(1): 384 − 399.
[34]	SANTOLAMAZZA-CARBONE S, SOTELO T, VELASCO P, et al. Antibiotic properties of the glucosinolates of Brassica oleracea var. acephala similarly affect generalist and specialist larvae of two lepidopteran pests [J]. Journal of Pest Science, 2016, 89(1): 195 − 206.
[35]	KLIEBENSTEIN D J, GERSHENZON J, MITCHELL-OLDS T. Comparative quantitative trait loci mapping of aliphatic, indolic and benzylic glucosinolate production in Arabidopsis thaliana leaves and seeds [J]. Genetics, 2001, 159(1): 359 − 370.
[36]	KLIEBENSTEIN D J, KROYMANN J, BROWN P, et al. Genetic control of natural variation in Arabidopsis glucosinolate accumulation [J]. Plant Physiology, 2001, 126(2): 811 − 825.
[37]	KLIEBENSTEIN D J, LAMBRIX V M, REICHELT M, et al. Gene duplication in the diversification of secondary metabolism: tandem 2-oxoglutarate-dependent dioxygenases control glucosinolate biosynthesis in Arabidopsis [J]. The Plant Cell, 2001, 13(3): 681 − 693.
[38]	ZÜST T, HEICHINGER C, GROSSNIKLAUS U, et al. Natural enemies drive geographic variation in plant defenses [J]. Science, 2012, 338(6103): 116 − 119.
[39]	KUMAR P, AUGUSTINE R, SINGH A K, et al. Feeding behaviour of generalist pests on Brassica juncea: implication for manipulation of glucosinolate biosynthesis pathway for enhanced resistance [J]. Plant,Cell and Environment, 2017, 40(10): 2109 − 2120.
[40]	LIU Z, WANG H, XIE J, et al. The roles of cruciferae glucosinolates in disease and pest resistance[J/OL]. Plants, 2021, 10(6): 1097[2022-02-03]. doi:10.3390/plants10061097.
[41]	HECKEL D G. Insect detoxification and sequestration strategies [J]. Annual Plant Reviews, 2014, 47: 77 − 114.
[42]	GIRAUDO M, HILLIOU F, FRICAUX T, et al. Cytochrome P450s from the fall armyworm(Spodoptera frugiperda): response to plant allelochemicals and pesticides [J]. Insect Molecular Biology, 2015, 24(1): 115 − 128.
[43]	VANHAELEN N, HAUBRUGE E, LOGNAY G, et al. Hoverfly glutathione S-transferases and effects of Brassicaceae secondary metabolites [J]. Pesticide Biochemestry Physiology, 2001, 71(3): 170 − 177.

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白菜Brassica campestris ssp. chinensis是十字花科Brassicaceae芸薹属Brassica 2年生草本植物，因成熟周期短、适应力强、营养价值高等特点，在中国农业生产中占据重要地位^[1]。硫代葡萄糖苷简称硫苷，是十字花科植物中的一类含硫、氮次生代谢产物，基于衍生氨基酸的差异可分为脂肪族、吲哚族和芳香族三大类^[2-3]。硫苷的生物合成可分为侧链延伸、核心结构形成和侧链修饰等3步，涉及大量的基因、酶和转录调节因子^[4]。已有研究表明：硫苷不仅在抗癌^[5]、十字花科植物特殊风味的产生^[6-7]及硫元素的调节^[8]中发挥着重要的作用，而且是十字花科植物抵御生物胁迫的主要防御物质^[9-10]。研究表明：硫苷可以有效影响害虫的生长发育及产卵^[11]，但不同类型的硫苷对不同种群植食性昆虫抗性不同^[12-13]。如甘蓝夜蛾Mamestra brassicae幼虫在取食脂肪族和吲哚族硫苷含量较高的植物后生长缓慢，取食吲哚族硫苷含量较高的植物后发育时间也会延长^[14]。作为一种防御相关植物次生代谢产物，硫苷存在于植物的整个生命周期中^[15-16]，植食性昆虫的取食会使其含量显著提高^[17-18]，硫苷含量的改变被证明与害虫胁迫下硫苷的合成、转运及降解相关基因的激活相关^[19]。MEWIS等^[20]发现拟南芥Arabidopsis thaliana受桃蚜Myzus persicae、甘蓝蚜Brevicoryne brassicae和甜菜夜蛾Spodoptera exigu幼虫取食后，脂肪族硫苷含量显著增加，AtMAM1和AtCYP79F1基因转录水平也显著上调。此前，KOORNNEEF等^[21]发现特定硫苷生物合成基因的存在或缺失可以赋予某些植物特殊的抗性，如拟南芥Ler生态型AtMAM2的存在，使得其对甜菜夜蛾幼虫的抗性高于缺乏AtMAM2的拟南芥Col生态型。同样，蚜虫侵袭会使拟南芥吲哚族硫苷含量增加3倍^[22]，PFALZ等^[23]通过数量性状基因位点(QTL)定位结合转录组分析，发现吲哚族硫苷合成相关基因AtCYP81F2的表达有助于拟南芥抵抗桃蚜，但不能抵御小菜蛾Plutella xylostella 、欧洲粉蝶Pieris brassicae、粉纹夜蛾Trichoplusia ni、甜菜夜蛾等鳞翅目Lepidopteran害虫。在进化过程中，昆虫为应对植物硫苷-黑介子酶防御系统的防御作用，也形成了以解毒酶——细胞色素P450s和谷胱甘肽硫转移酶(GSTs)等为基础的适应性机制^[24−25]。

本研究以白菜为研究对象，通过高效液相色谱法(HPLC)和实时荧光定量聚合酶链式反应(RT-qPCR)，探究白菜硫苷质量摩尔浓度及组分在甜菜夜蛾幼虫取食胁迫下的变化与潜在的分子调控机制，并通过检测取食前后甜菜夜蛾幼虫体内解毒酶活性的变化，探究白菜硫苷质量摩尔浓度的提高对幼虫体内解毒酶活性的影响，以期为白菜等十字花科作物应对害虫胁迫抗性的提高、品质和产量的改良提供依据。

3. 讨论

已有研究发现：不同拟南芥群体硫苷的种类和含量有所差异，而这种差异影响着拟南芥对不同种群植食性昆虫的抗性^[30-33]，如甘蓝夜蛾和菜青虫Pieris rapae在取食脂肪族和吲哚族硫苷含量较高的植株时，生长缓慢，取食吲哚族硫苷含量较高的植株时，发育时间也会增加^[34]。随后，在研究拟南芥脂肪族硫苷的抗虫机制中，发现GS-Elong、GS-AOP、TGGs等位点与脂肪族硫苷的抗虫性相关^[35-38]。SONTOWSKI等^[19]发现：拟南芥被甜菜夜蛾幼虫取食后，GS-Elong位点硫苷合成相关基因AtMAM1、AtMAM2、AtMAM3转录水平显著增加，同时相关脂肪族硫苷含量也显著上升，说明脂肪族硫苷参与了拟南芥对甜菜夜蛾幼虫的防御反应。本研究发现：白菜被甜菜夜蛾幼虫取食后，脂肪族硫苷GS-Elong位点相关基因BcBCAT4、BcMAM1显著上调，脂肪族硫苷的合成也显著增加，GBN的响应尤为强烈，说明脂肪族硫苷尤其是GBN参与了白菜对甜菜夜蛾幼虫的防御反应。然而，BcBCAT4、BcMAM1的表达水平与相应脂肪族硫苷的质量摩尔浓度存在一定差异，说明除了硫苷生物合成基因的直接影响外，可能还涉及其他机制来参与十字花科芸薹属作物次级代谢产物硫苷的生物合成和积累。此外，吲哚族的4OH、NEO、GBC在甜菜夜蛾幼虫取食过程中显著增加，说明吲哚族硫苷可能在白菜抵御甜菜夜蛾幼虫取食过程中发挥着重要的作用。KUMAR等^[39]在研究害虫的质量与芥菜Brassica juncea中硫苷各组分的关系时，发现棉铃虫Helicoverpa armigera幼虫的增重与芥菜中GNA和GBN的含量呈负相关，而斜纹夜蛾Spodoptera litura幼虫的增重与GNA、GBN和黑介子硫苷酸钾(SIN)的含量呈负相关，进一步研究发现硫苷介导的芥菜对棉铃虫和斜纹夜蛾的抗性差异与BjuMYB28同源物在芥菜叶片中的差异表达相关。本研究中，甜菜夜蛾幼虫取食胁迫下，白菜4OH、NEO、GBC的增加与幼虫体内解毒酶GSTs活性及白菜硫苷合成相关基因BcSOT16呈正相关，说明BcSOT16活性的提高可能是甜菜夜蛾幼虫取食下白菜吲哚族硫苷合成增加的原因，进而提高了白菜对甜菜夜蛾的抗性。需进一步验证BcSOT16的生物学功能，以明确BcSOT16在白菜抵御甜菜夜蛾幼虫取食胁迫过程中所起到的重要作用。

在长期进化过程中，为抵御植食性昆虫的取食，植物形成了多种防御机制，如产生各种次级代谢物^[40]。硫苷及其降解产物对昆虫具有阻食、影响其生长发育及繁殖，甚至毒杀的作用^[11]，然而，硫苷也能诱导昆虫体内细胞色素P450s和GSTs等主要解毒酶系基因的表达，增强昆虫对硫苷等植物次生物质的代谢能力^{[23-24, 41]}。如草地贪夜蛾Spodoptera frugiperda幼虫的细胞色素P450s活性可以被吲哚族硫苷降解产物吲哚-3-甲醇所诱导^[42]；食用含硫苷、异硫氰酸酯的饲料或直接取食十字花科植物时，桃蚜体内GSTs活性会被诱导增加^[24]；与对照相比，取食含硫苷的桃蚜，食蚜蝇GSTs活性亦有所提高^[43]。本研究中甜菜夜蛾幼虫取食白菜后，其体内GSTs活性不断增强，与白菜中总硫苷及吲哚类硫苷质量摩尔浓度增加趋势的一致性，表明了硫苷对甜菜夜蛾幼虫GSTs活性的诱导作用，也说明吲哚族硫苷可能在白菜抵御杂食性害虫甜菜夜蛾幼虫取食过程中发挥更为重要的作用。

4. 结论

甜菜夜蛾幼虫取食能上调白菜BcSOT16、BcBCAT4、BcMAM1等硫苷合成关键基因的表达，从而促进白菜硫苷质量摩尔浓度的增加，提高白菜对甜菜夜蛾幼虫取食胁迫的抗性，吲哚族的4OH、NEO、GBC和脂肪族的GBN的反应尤为强烈，但硫苷质量摩尔浓度的升高又会诱导甜菜夜蛾幼虫体内GSTs活性的增强，提高甜菜夜蛾幼虫对硫苷的解毒能力。

参考文献 (43)

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硫苷介导的白菜抵御甜菜夜蛾幼虫取食胁迫的分子机制

doi: 10.11833/j.issn.2095-0756.20220172

作者简介: 郝娇娇(ORCID: 0000-0001-5049-799x)，从事园艺作物栽培生理与品质调控研究。E-mail: 2407605896@qq.com

通信作者: 朱祝军(ORCID: 0000-0001-8551-7751 )，教授，从事园艺作物栽培生理与品质调控研究。E-mail: zhuzj@zafu.edu.cn

Molecular mechanism of glucosinolate-mediated Brassica campestris ssp. chinensis against feeding stress of Spodoptera exigua larvae

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硫苷介导的白菜抵御甜菜夜蛾幼虫取食胁迫的分子机制

doi: 10.11833/j.issn.2095-0756.20220172

浙江农林大学园艺科学学院浙江省山区农业高效绿色协同生产创新中心/农业农村部亚热带果品蔬菜质量安全控制重点实验室，浙江杭州 311300

作者简介:
郝娇娇(ORCID: 0000-0001-5049-799x)，从事园艺作物栽培生理与品质调控研究。E-mail: 2407605896@qq.com

通信作者: 朱祝军(ORCID: 0000-0001-8551-7751 )，教授，从事园艺作物栽培生理与品质调控研究。E-mail: zhuzj@zafu.edu.cn

English Abstract

Molecular mechanism of glucosinolate-mediated Brassica campestris ssp. chinensis against feeding stress of Spodoptera exigua larvae

全文HTML

1.1. 材料

1.2. 取样方法

1.3. 硫苷的提取及HPLC检测

1.4. 硫苷合成相关基因的定量分析

1.4.1. 总RNA的提取及cDNA的获得

1.4.2. 实时荧光定量聚合酶链式反应(RT-qPCR)分析

1.5. GSTs活性测定

1.6. 数据处理

2.1. 甜菜夜蛾幼虫取食对白菜硫苷质量摩尔浓度的影响

2.2. 甜菜夜蛾幼虫取食对白菜硫苷合成相关基因表达的影响

2.3. 甜菜夜蛾幼虫体内GSTs活性的变化

目录

留言板

硫苷介导的白菜抵御甜菜夜蛾幼虫取食胁迫的分子机制

doi: 10.11833/j.issn.2095-0756.20220172

作者简介: 郝娇娇(ORCID: 0000-0001-5049-799x)，从事园艺作物栽培生理与品质调控研究。E-mail: 2407605896@qq.com

通信作者: 朱祝军(ORCID: 0000-0001-8551-7751 )，教授，从事园艺作物栽培生理与品质调控研究。E-mail: zhuzj@zafu.edu.cn

Molecular mechanism of glucosinolate-mediated Brassica campestris ssp. chinensis against feeding stress of Spodoptera exigua larvae

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出版历程

硫苷介导的白菜抵御甜菜夜蛾幼虫取食胁迫的分子机制

doi: 10.11833/j.issn.2095-0756.20220172

浙江农林大学 园艺科学学院 浙江省山区农业高效绿色协同生产创新中心/农业农村部亚热带果品蔬菜质量安全控制重点实验室，浙江 杭州 311300

作者简介: 郝娇娇(ORCID: 0000-0001-5049-799x)，从事园艺作物栽培生理与品质调控研究。E-mail: 2407605896@qq.com

通信作者: 朱祝军(ORCID: 0000-0001-8551-7751 )，教授，从事园艺作物栽培生理与品质调控研究。E-mail: zhuzj@zafu.edu.cn

English Abstract

Molecular mechanism of glucosinolate-mediated Brassica campestris ssp. chinensis against feeding stress of Spodoptera exigua larvae

全文HTML

1.1. 材料

1.2. 取样方法

1.3. 硫苷的提取及HPLC检测

1.4. 硫苷合成相关基因的定量分析

1.4.1. 总RNA的提取及cDNA的获得

1.4.2. 实时荧光定量聚合酶链式反应(RT-qPCR)分析

1.5. GSTs活性测定

1.6. 数据处理

2.1. 甜菜夜蛾幼虫取食对白菜硫苷质量摩尔浓度的影响

2.2. 甜菜夜蛾幼虫取食对白菜硫苷合成相关基因表达的影响

2.3. 甜菜夜蛾幼虫体内GSTs活性的变化

目录

浙江农林大学园艺科学学院浙江省山区农业高效绿色协同生产创新中心/农业农村部亚热带果品蔬菜质量安全控制重点实验室，浙江杭州 311300

作者简介:
郝娇娇(ORCID: 0000-0001-5049-799x)，从事园艺作物栽培生理与品质调控研究。E-mail: 2407605896@qq.com