美国白蛾幼虫取食对低适合度寄主植物山槐诱导防御的影响

doi:10.16380/j.kcxb.2025.08.011

摘要/Abstract

摘要： 【目的】山槐Albizia kalkora是美国白蛾Hyphantria cunea幼虫的低适合度寄主植物。本研究旨在探究美国白蛾幼虫取食对山槐诱导防御的影响以及山槐诱导防御对第2批美国白蛾幼虫适合度的影响。【方法】美国白蛾4龄幼虫分别以低密度(low-density, LD)(30头/株)和高密度(high-density, HD)(50头/株)取食山槐后第7和21天时，测定山槐受损叶片和健康叶片中营养物质(氨基酸、可溶性糖和总蛋白质)及次生物质(单宁、总酚、总黄酮、木质素和总生物碱)的含量；利用RT-qPCR检测山槐受损叶片和健康叶片中类黄酮生物合成通路关键基因(PGT1, CHS7和ANR)及α亚麻酸代谢通路关键基因(AOC2, OPCL1和LOX2S)的表达量；第2批美国白蛾3龄幼虫取食已受损山槐叶片第3和7天时测定幼虫死亡率、体重、体长和头壳宽，利用RTqPCR测定其生长发育相关基因(GADD45和MYC)、能量代谢相关基因(HK1和OGDH)、消化酶基因(TRY7, AMY2和LIP10)和解毒酶基因(GST18, CARE14和CYPAE178)的表达量。【结果】美国白蛾4龄幼虫取食山槐叶片后，各处理组在不同时间点山槐叶片中可溶性糖和总蛋白质含量与未取食的对照(CK)组比均显著下降。美国白蛾4龄幼虫取食山槐叶片后第7天时， LD和HD取食胁迫组山槐受损叶片中的总酚、总黄酮和木质素含量与CK组比显著升高， LD取食胁迫组受损山槐叶片中单宁含量与CK组比显著升高, HD取食胁迫组健康山槐叶片中总酚和总黄酮含量与CK组比显著升高。美国白蛾4龄幼虫取食山槐叶片后第21天时， LD和HD取食胁迫组受损山槐叶片中单宁和总黄酮含量与CK组比显著升高, LD取食胁迫组健康山槐叶片中总生物碱含量与CK组比显著升高，且HD取食胁迫组健康山槐叶片中单宁、总酚和总生物碱含量与CK组比显著升高。美国白蛾4龄幼虫取食后第7天时山槐受损叶片和健康叶片中ANR和CHS7的表达量与CK组比均显著上调，取食后第21天时山槐受损叶片和健康叶片中PGT1和CHS7的表达量与CK组比均显著上调,取食后第7和21天时山槐受损叶片和健康叶片中OPCL1和LOX2S的表达量与CK组比均显著上调，取食后第21天时山槐受损叶片和健康叶片中AOC2的表达量与CK组比显著上调。取食经LD和HD幼虫取食而激活诱导防御山槐的叶片后第3和7天，第2批美国白蛾幼虫的体重、体长和头壳宽与CK组比均显著降低，且伴随着幼虫死亡率在一定程度上的上升。取食后第3和7天LD取食胁迫组第2批美国白蛾幼虫中GADD45的表达量与CK组比显著上调，取食后第7天时LD和HD取食胁迫组第2批美国白蛾幼虫中MYC的表达量与CK组比均显著上调。取食后第3和7天LD和HD取食胁迫组第2批美国白蛾幼虫中TRY7, AMY2, LIP10, HK1, OGDH, GST18, CARE14和CYPAE178的表达量与CK组比均显著下调。【结论】美国白蛾幼虫取食激活了山槐的诱导防御，而第2批美国白蛾幼虫无法对山槐的诱导防御形成有效的反防御策略，这可能是山槐属于美国白蛾幼虫低适合度寄主植物的重要原因。

关键词: 美国白蛾, 取食胁迫, 寄主植物, 诱导防御, 防御逃避, 适合度

Abstract: 【Aim】 Albizia kalkora is a low-fitness host plant for Hyphantria cunea larvae. The purpose of this study is to explore the effect of H. cunea larval feeding on the induced defense of A. kalkora and the effects of induced defense of A. kalkora on the fitness of the 2nd batch of H. cunea larvae. 【Methods】 On the 7th and 21st days after feeding by the 4th instar larvae of H. cunea at low-density (LD) (30 individuals/plant) and high-density (HD) (50 individuals/plant), the contents of nutrients (amino acids, soluble sugar and total proteins) and secondary substances (tannin, total phenols, total flavones, lignin and total alkaloids) in the damaged and healthy leaves of A. kalkora were measured. The expression levels of the key genes PGT1, CHS7 and ANR in flavonoid biosynthesis pathway, and AOC2, OPCL1 and LOX2S in α-linolenic acid pathway in the damaged and healthy leaves of A. kalkora were measured by RT-qPCR. On the 3rd and 7th days after feeding the 3rd instar larvae of the 2nd batch of H. cunea with the damaged leaves of A. kalkora, the mortality, body weight, body length and head shell width of larvae were measured, and the expression levels of GADD45 and MYC related to growth and development, HK1 and OGDH related to energy metabolism, digestive enzyme genes TRY7, AMY2 and LIP10, and detoxification enzyme genes GST18, CARE14 and CYPAE178 in the 2nd batch of H. cunea larvae were measured by RT-qPCR. 【Results】 The contents of soluble sugar and total proteins in the leaves of A. kalkora in various treatment groups decreased significantly at different time points after feeding the 4th instar larvae of H. cunea with A. kalkora leaves as compared with those in the non-feeding control (CK) group. On the 7th day after feeding, the contents of total phenols, total flavones and lignin in the damaged leaves of A. kalkora in LD and HD feeding groups were significantly increased and the tannin content in the damaged leaves of A. kalkora in the LD feeding group was significantly increased, as compared with those in the CK group. The contents of total phenols and total flavonoids in the healthy leaves of A. kalkora in the HD feeding group were significantly increased as compared with those in the CK group. On the 21st day after feeding the 4th instar larvae of H. cunea with A. kalkora leaves, the contents of tannin and total flavonoids in the damaged A. kalkora leaves in LD and HD feeding groups were significantly increased, the content of total alkaloids in the healthy A. kalkora leaves in the LD feeding group was significantly increased, and the contents of tannin, total phenols and total alkaloids in healthy A. kalkora leaves in the HD feeding group were significantly increased, as compared with those in the CK group. On the 7th day after feeding by the 4th instar larvae of H. cunea, the expression levels of ANR and CHS7 in both the damaged and healthy A. kalkora leaves were significantly up-regulated as compared with those in the CK group. On the 21st day after feeding by the 4th instar larvae of H. cunea, the expression levels of PGT1 and CHS7 in both the damaged and healthy A. kalkora leaves were significantly up-regulated as compared with those in the CK group. On the 7th and 21st days after feeding by the 4th instar larvae of H. cunea, the expression levels of OPCL1 and LOX2S in both the damaged and healthy A. kalkora leaves were significantly up-regulated as compared with those in the CK group. On the 21st day after feeding by the 4th instar larvae of H. cunea, the expression levels of AOC2 in both the damaged and healthy A. kalkora leaves was significantly up-regulated as compared with those in the CK group. On the 3rd and 7th days after feeding on the A. kalkora leaves in which the induced defense had been activated in LD and HD feeding groups, the body weight, body length and head shell width of the 2nd batch of H. cunea larvae decreased significantly, and the larval mortality increased to a certain extent as compared with those in the CK group. The expression levels of GADD45 in the 2nd batch of H. cunea larvae in the LD feeding group on the 3rd and 7th days after feeding were significantly up-regulated and those of MYC in the 2nd batch of H. cunea larvae in LD and HD groups on the 7th day after feeding were significantly up-regulated, as compared with those in the CK group. On the 3rd and 7th days after feeding, the expression levels of TRY7, AMY2, LIP10, HK1, OGDH, GST18, CARE14 and CYPAE178 in the 2nd batch of H. cunea larvae in LD and HD feeding groups were significantly down-regulated as compared with those in the CK group. 【Conclusion】 H. cunea larval feeding activates the induced defense of A. ralkora, and the 2nd batch of H. cunea larvae can not form an effective counter-defense strategy to the induced defense of A. kalkora, which may be an important reason why A. kalkora is a low-fitness host plant for H. cunea larvae.

Key words: Hyphantria cunea; feeding stress, host plant, induced defense, defensive escape, fitness

王睿琦, 王莹, 张嶴颖, 谭明涛, 何昱斌, 姜礅, 严善春. 美国白蛾幼虫取食对低适合度寄主植物山槐诱导防御的影响[J]. 昆虫学报, 2025, 68(8): 1123-1135.

WANG Rui-Qi, WANG Ying, ZHANG Ao-Ying, TAN Ming-Tao, HE Yu-Bin, JIANG Dun, YAN Shan-Chun. Effects of feeding by Hyphantria cunea (Lepidoptera: Erebidae) larvae on the induced defense of low-fitness host plant Albizia kalkora[J]. Acta Entomologica Sinica, 2025, 68(8): 1123-1135.

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链接本文: http://www.insect.org.cn/CN/10.16380/j.kcxb.2025.08.011

http://www.insect.org.cn/CN/Y2025/V68/I8/1123

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美国白蛾幼虫取食对低适合度寄主植物山槐诱导防御的影响

Effects of feeding by Hyphantria cunea (Lepidoptera: Erebidae) larvae on the induced defense of low-fitness host plant Albizia kalkora

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[1]	谭玉珊, 李慧, 杨华磊, 赵培渊, 李长燕, 许丹雯仪, 郝德君. 热浪胁迫对松墨天牛繁殖特性的影响[J]. 昆虫学报, 2024, 67(7): 954-963.
[2]	韦红艳, 张承志, 孙丽丽, 曹传旺. 细胞色素P450基因CYP4S47和CYP332A29参与美国白蛾对氯虫苯甲酰胺耐受性[J]. 昆虫学报, 2024, 67(12): 1606-1616.
[3]	吴密, 黄灿, 杨祥燕, 李今朝, 覃旭, 黄显雅, 彭欣怡, 蒋越华, 崔明勇, 钟敬贤, 刘明. 新菠萝灰粉蚧取食对四种寄主植物挥发物组成的影响[J]. 昆虫学报, 2024, 67(10): 1352-1363.
[4]	蒋婷, 杨志强, 樊春丽, 蒋卓恩, 尹奇三, 徐冬英, 王晓宇, 谭德锦, 农君鑫, 卢艳春. 四种植物上黄翅绢野螟的生长发育和繁殖适合度[J]. 昆虫学报, 2024, 67(10): 1404-1415.
[5]	袁龙宇, 雷浩霖, 李燕芳, 肖汉祥, 魏洪义, 张振飞. 广东省稻水象甲生活史及越冬规律[J]. 昆虫学报, 2023, 66(9): 1192-1200.
[6]	李春沁, 张钰析, 徐世才, 李伯辽, 陈秀琳, 罗坤, 李广伟. 梨小食心虫GmolNPC2的基因克隆、表达谱及配体结合特征[J]. 昆虫学报, 2023, 66(7): 870-884.
[7]	张晶, 段至柔, 刘常权, 彭英传, 张万娜, 肖海军. 寄主植物与刺吸式昆虫互作防御的研究进展[J]. 昆虫学报, 2023, 66(4): 575-590.
[8]	赵文华, 杨光梅, 刘雨芳. 褐飞虱成虫不同密度和取食时长胁迫下水稻植株的生理生化响应[J]. 昆虫学报, 2023, 66(2): 150-157.
[9]	李广伟, 陈玉鑫, 闫瑞, 雷怡雪, 陈秀琳, 李伯辽. 苹褐带卷蛾成虫对主要寄主植物挥发物的触角电位反应和行为反应[J]. 昆虫学报, 2022, 65(8): 1026-1037.
[10]	贺静, 杜素洁, 程鑫斐, 王绮静, 郭建洋, 王作慰, 王福莲, 刘万学. 甘肃白银地区潜叶蝇及其寄生蜂的组成和发生调查[J]. 昆虫学报, 2022, 65(4): 533-540.
[11]	谷峻, 叶艳, 李时宇, 袁雅菲, 黄立华. 斜纹夜蛾蜕皮激素合成通路相关CYP450基因的鉴定及表达分析[J]. 昆虫学报, 2022, 65(12): 1606-1614.
[12]	杨孟可, 刘赛, 乔海莉, 郭昆, 徐荣, 徐常青, 陈君. 致瘿昆虫对寄主植物生理和代谢的影响[J]. 昆虫学报, 2021, 64(4): 536-548.
[13]	郑雅楠, 时勇, 李洋, 范立淳, 王珏, 王伟韬. 云杉花墨天牛成虫对四种寄主松树的取食偏好性[J]. 昆虫学报, 2021, 64(12): 1478-1482.
[14]	高源, 孙丽丽, 曹传旺. 昆虫口腔分泌物效应子及其在害虫防治中基于RNAi技术的应用展望[J]. 昆虫学报, 2021, 64(10): 1218-1234.
[15]	龚强, 宫亚军, 曹利军, 郑小钰, 蒲德强, 黄琼, 魏书军. 取食不同寄主植物的桃小食心虫飞行能力[J]. 昆虫学报, 2020, 63(9): 1153-1158.