Regulatory mechanism of cinnamic acid on the pathogenicity of Lanzhou lily wilt pathogen

doi:10.7522/j.issn.1000-694X.2026.00044

Journal of Desert Research ›› 2026, Vol. 46 ›› Issue (3): 362-370.DOI: 10.7522/j.issn.1000-694X.2026.00044

Regulatory mechanism of cinnamic acid on the pathogenicity of Lanzhou lily wilt pathogen

Hui Li(), Li Wang, Jia Han, Wenke Du, Fengfeng Guan, Bo Yang, Hongyu Yang, Guiying Shi()

College of Horticulture，Gansu Agricultural University，Lanzhou 730070，China

Received:2025-08-06 Revised:2026-03-31 Online:2026-05-20 Published:2026-06-11
Contact: Guiying Shi

Abstract

Abstract:

This study aims to investigate the regulatory effects of exogenous cinnamic acid on the proliferation， growth， infectivity and key pathogenic factors of Fusarium oxysporum， in order to provide a theoretical foundation for understanding the mechanisms underlying cinnamic acid-mediated consecutive replant problems caused by F. oxysporum of Lanzhou lily wilt and for developing control strategies. The in vitro culture method was employed， with cinnamic acid concentration gradients set at 0 mg·L^-1， 0.24 mg·L^-1， 2.40 mg·L^-1， and 24.00 mg·L^-1， to analyze the physiological growth indicators related to the proliferation and infection of F. oxysporum， as well as the transcriptional expression levels of key pathogenic genes such as FochsV and FUBT. The results indicated that low concentrations （0.24 mg·L^-1， 2.40 mg·L^-1） of cinnamic acid promoted the growth and high concentrations （24.00 mg·L^-1） of cinnamic acid inhibited the growth of F. oxysporum： 0.24 mg·L^-1 cinnamic acid significantly promoted colony growth and increased sporulation and markedly enhanced the activities of four cell wall-degrading enzymes （chitinase， cellulase， xylanase and pectinase）. The expression of FochsV gene showed a trend of promotion at low concentrations and inhibition at high concentrations over time， while the expression of FUBT gene displayed difference on the 7th day， showing promotion at high concentrations and inhibition at low concentrations. The overall activity of antioxidant reductase in the fungal cells were promoted at low concentrations and inhibited at high concentrations. In contrast， at 24.00 mg·L^-1 cinnamic acid significantly inhibited fungal growth， enzyme activities， and the expression of key pathogenic genes. Based on the accumulation characteristics of cinnamic acid in the soil under long-term consecutive replant of Lanzhou lily （0-9 years）， it is inferred that the accumulation of cinnamic acid is a key soil chemical regulatory factor exacerbating the incidence of wilt in this vegetable crop.

Key words: Fusarium oxysporum, cinnamic acid, antioxidant enzyme, cell wall degrading enzyme, gene expression analysis

CLC Number:

Hui Li, Li Wang, Jia Han, Wenke Du, Fengfeng Guan, Bo Yang, Hongyu Yang, Guiying Shi. Regulatory mechanism of cinnamic acid on the pathogenicity of Lanzhou lily wilt pathogen[J]. Journal of Desert Research, 2026, 46(3): 362-370.

Figures/Tables 6

Table 1 Fusarium oxysporum q-PCR primer list

引物名称	引物序列（5’-3’）
Actin-F	CCGAGGCTCCCATCAACC
Actin-R	GGCGAAACCCTCGTAAATGG
SOD-F	GGTCCTCACTTCAACCCTCA
SOD-R	AGTCGGTGACAGAGCCCTTA
POD-F	TGAAACATCCCACCTTAC
POD-R	TATTACCGCAACATCCTC
FochsV-F	TCTTTTCCCCATCCAAGTGTCT
FochsV-R	GTGATGTTGGTGTTTCGGTTGT
FUBT-F	GGAGCCTGAAGACAGATTGC
FUBT-R	CCGATAATAGGGACGATCCA

Fig.1 Colony diagram colony diameter and allelopathic index of Fusarium oxysporum under cinnamic acid treatment

Fig.2 Spore number and allelopathic index of Fusarium oxysporum under cinnamic acid treatment Note： Select the hyphae on the PDA medium on the 8th day of the experiment for measurement

Fig.3 Effect of cinnamic acid on the activity of cell wall degrading enzymes of Fusarium oxysporum

Fig.4 Effect of cinnamic acid on oxidoreductase activities of Fusarium oxysporum

Fig.5 Effect of cinnamic acid on the transcription of key genes in Fusarium oxysporum

References 33

[1]	Louws J F， Rivard L C， Kubota C.Grafting fruiting vegetables to manage soilborne pathogens，foliar pathogens，arthropods and weeds［J］.Scientia Horticulturae，2010，127（2）：127-146.
[2]	严慧丽，杨利娟，裴毅，等.兰州百合枯萎病病原鉴定及防治药剂筛选［J/OL］.分子植物育种，1-16［2024-12-26］.
[3]	Shi G Y， Sun H Q， Alejandro C，et al.Soil fungal diversity loss and appearance of specific fungal pathogenic communities associated with the consecutive replant problem （CRP） in Lily［J］.Frontiers in Microbiology，2020，111649.
[4]	牟晓玲，李潇潇，师桂英，等.兰州百合枯萎病病原菌鉴定及罹病组织超微结构观察［J］.植物保护学报，2022，49（04）：1111-1118.
[5]	Ye S F， Yu J Q， Peng Y H，et al.Incidence of Fusarium wilt in Cucumis sativus L.is promoted by cinnamic acid，an autotoxin in root exudates［J］.Plant and Soil，2004，263（1/2）：143-150.
[6]	董艳，董坤，杨智仙，等.肉桂酸对蚕豆枯萎病发生的影响及间作缓解机制［J］.土壤学报，2017，54（2）：503-515.
[7]	李培栋，王兴祥，李奕林，等.连作花生土壤中酚酸类物质的检测及其对花生的化感作用［J］.生态学报，2010，30（8）：2128-2134.
[8]	陈金苗，保丽美，刘雨艳，等.三七根际酚酸自毒物质对两种根腐病致病真菌的化感效应［J］.昆明理工大学学报（自然科学版），2024，49（2）：91-103.
[9]	李丽，蒋景龙.西洋参化感自毒作用与连作障碍研究进展［J］.分子植物育种，2018，16（13）：4436-4443.
[10]	刘苹，赵海军，唐朝辉，等.连作对不同抗性花生品种根系分泌物和土壤中化感物质含量的影响［J］.中国油料作物学报，2015，37（04）：467-474.
[11]	孙鸿强.连作对兰州百合生理特性及土壤环境效应的影响［D］.兰州：甘肃农业大学，2017.
[12]	Han J， Li Y P， Li H，et al.Phenolic acids alleviated consecutive replant problems in lily by regulating its allelopathy on rhizosphere microorganism under chemical fertiliser reduction with microbial agents in conjunction with organic fertiliser application［J］.Applied Soil Ecology，2025，205105780-105780.
[13]	Eleonora G K， Alberto R H， Maria TA.Contribution of cell wall degrading enzymes to pathogenesis of Fusarium graminearum：a review［J］.Journal of Basic Microbiology，2009，49（3）：231-241.
[14]	Lemos P， Ruiz-Roldán C， Hera C.Role of the phosphatase Ptc1 in stress responses mediated by CWI and HOG pathways in Fusarium oxysporum ［J］.Fungal Genetics and Biology，2018，11810-20.
[15]	李英，杜春梅.致病性尖孢镰刀菌毒力因子的研究进展［J］.中国农学通报，2021，37（12）：92-97.
[16]	Caffall H K， Mohnen D.The structure，function，and biosynthesis of plant cell wall pectic polysaccharides［J］.Carbohydrate Research，2009，344（14）：1879-1900.
[17]	Glass L N， Schmoll M， Cate H D J，et al.Plant cell wall deconstruction by ascomycete fungi［J］.Annual Review of Microbiology，2013，67（1）：477-498.
[18]	Marie-Christine S， Claude P， Annie P，et al.Botrytis cinerea virulence is drastically reduced after disruption of chitin synthase class III gene （Bcchs3a）［J］.Cellular microbiology，2006，8（8）：1310-1321.
[19]	P M M， Antonio P D，G I M R.Class V chitin synthase determines pathogenesis in the vascular wilt fungus Fusarium oxysporum and mediates resistance to plant defence compounds［J］.Molecular microbiology，2003，47（1）：257-266.
[20]	Magdalena M U， P M M，G I M R.Role of chitin synthase genes in Fusarium oxysporum ［J］.Microbiology，2004，150（10）：3175-3187.
[21]	K F C， Liu J G， S L P，et al.FUBT，a putative MFS transporter，promotes secretion of fusaric acid in the cotton pathogen Fusarium oxysporum f.sp.vasinfectum［J］.Microbiology，2015，161（4）：875-883.
[22]	Wu Z J， Yang L， Wang R Y，et al.In vitro study of the growth，development and pathogenicity responses of Fusarium oxysporum to phthalic acid，an autotoxin from Lanzhou lily［J］.World journal of microbiology & biotechnology，2015，31（8）：12271234.
[23]	Wu Z J， Xie Z K， Yang L，et al.Identification of autotoxins from root exudates of Lanzhou lily （Lilium davidii var. unicolor）［J］.Allelopathy Journal，2015，35（1）：35-48.
[24]	王娜，马绍英，马蕾，等.肉桂酸和棕榈酸对豌豆种子萌发和幼苗生长的化感效应［J］.植物生理学报，2021，57（8）：1657-1667.
[25]	王文珠，师桂英，苏国礼，等.乌头酸对尖孢镰刀菌百合专化型抑制作用分析［J］.西北农业学报，2022，31（2）：224-232.
[26]	赵丽娜，谢燚谛，贺子康，等.荒漠生物土壤结皮碳降解菌株的筛选鉴定及特性分析［J］.中国沙漠，2025，45（3）：185-190.
[27]	周大梁，石薇，蒋紫薇，等.沟垄集雨下密度和施氮对黄土高原青贮玉米叶片酶活性及水氮利用的影响［J］.草业学报，2022，31（8）：126-143.
[28]	Farhangi-Abriz S， Torabian S.Antioxidant enzyme and osmotic adjustment changes in bean seedlings as affected by biochar under salt stress［J］.Ecotoxicology and Environmental Safety，2017，13764-13770.
[29]	Salwa J， Moez J， Férid L，et al.Changes in ascorbate peroxidase，catalase，guaiacol peroxidase and superoxide dismutase activities in common bean （Phaseolus vulgaris） nodules under salt stress［J］.Journal of plant physiology，2005，162（8）：929-936.
[30]	李庆凯，郭峰，唐朝辉，等.三种酚酸类物质在花生连作障碍中的生态效应分析［J］.中国油料作物学报，2019，41（1）：53-63.
[31]	孙会军.自毒物质对西瓜根系形态结构及细胞保护酶的影响［D］.北京：中国农业大学，2003.
[32]	吴凤芝，黄彩红，赵凤艳.酚酸类物质对黄瓜幼苗生长及保护酶活性的影响［J］.中国农业科学，2002（7）：821-825.
[33]	胡光玉，杨善武，周彬，等.对羟基苯甲酸对三七黑斑病致病性因素的影响研究［J］.安徽农业科学，2023，51（13）：163-165.

Regulatory mechanism of cinnamic acid on the pathogenicity of Lanzhou lily wilt pathogen

RichHTML

PDF

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 6

References 33

Related Articles 11

Recommended Articles

Metrics

Comments

[1]	Yanhang Zhang, Wenzhu Wang, Guiying Shi, Hongyu Yang, Guixiang Chang, Ying Wang, Hui Li. Allelopathic effect of aconitic acid on inhabiting wilt disease in Lanzhou lily [J]. Journal of Desert Research, 2024, 44(1): 122-129.
[2]	Kuizhong Xie, Huizhen Qiu, Xinyuan Hu, Aihua Luo. Identification of root exudates from continuous cropping potato in dry land and their allelopathy to Fusarium oxysporum [J]. Journal of Desert Research, 2021, 41(3): 7-15.
[3]	Shi Guiying, Sun Hongqiang, Yu Yanlin, Zhang Lina, Jia Xixia, Zhang Lipeng, Li Mouqiang. Effect of long-term consecutive cropping on leaf PSⅡ photochemical effecience and antioxidant enzyme activity of lanzhou lily [J]. Journal of Desert Research, 2020, 40(2): 206-213.
[4]	Chen Juanli, Zhao Xueyong, Liu Xinping, Zhang Yaqiu, Luo Yongqing, Zhang Rui, Zhang Runxia, Yu Hailun. Effects of Precipitation on Growth and Physiology of Three Psammophytes in the Horqin Sandy Land, China [J]. Journal of Desert Research, 2019, 39(5): 163-173.
[5]	Yan Xiaohua, Yu Jihua. Effects of Supplemental LED Light on Photosynthetic Pigment Contents and Antioxidant Enzyme Activities of Cucumber Seedling Leaves [J]. JOURNAL OF DESERT RESEARCH, 2016, 36(2): 392-398.
[6]	Li Jie, Feng Lidan, Wang Youke, He Jing, Chen Xiurong. Effects of Infection by Fusarium oxysporum on Photosynthetic and Chlorophyll Fluorescence Parameters of Lycium sp. [J]. JOURNAL OF DESERT RESEARCH, 2015, 35(6): 1565-1572.
[7]	Yang Shuqin, Zhou Ruilian, Liang Huimin, Zhao Halin, Zhao Xueyong. Relationship of Antioxidant Enzyme and Osmoregulation Substance to Photosynthese in Several Desert Plants [J]. JOURNAL OF DESERT RESEARCH, 2015, 35(6): 1557-1564.
[8]	Xie Weihai, Zhou Ruilian, Liang Huimin, Qu Hao, Dong Longwei, Qiang Shengbin. Physiological Difference in Messerschmidia sibirica Grown in Inland and Coastal Sand Land in Nature Environment and under Sand Burial [J]. JOURNAL OF DESERT RESEARCH, 2015, 35(6): 1538-1548.
[9]	Zhou Zijuan, Su Peixi, Xie Tingting, Zhang Haina, Li Shanjia. The Physiological and Biochemical Characteristics and Environmental Adaptability of Reaumuria soongorica in Different Habitats [J]. JOURNAL OF DESERT RESEARCH, 2014, 34(4): 1007-1014.
[10]	Liu Meiling, Cao Bo, Liu Yubing, Tan Huijuan, Chen Yongle, Zhang Yafeng. Responses of the Flavonoid Pathway and Antioxidant Ability to UV-B Radiation Stress in Reaumuria soongorica [J]. JOURNAL OF DESERT RESEARCH, 2014, 34(2): 426-432.
[11]	LI Wei, ZHAO Yu-sen, ZHOU Zhi-qiang, SUN Guang-yu, LIU Tong. Effects of Drought Stress and Rehydration on Chlorophyll Fluorescence Characteristics and Antioxidant Enzyme Activities in Leaves of Taxus cuspidata [J]. JOURNAL OF DESERT RESEARCH, 2012, 32(1): 112-116.