浙江苍南番茄-水稻轮作对连作土壤理化性质和微生物群落的影响

doi:10.3864/j.issn.0578-1752.2025.04.006

中国农业科学 ›› 2025, Vol. 58 ›› Issue (4): 692-703.doi: 10.3864/j.issn.0578-1752.2025.04.006

浙江苍南番茄-水稻轮作对连作土壤理化性质和微生物群落的影响

王少骅¹(), 沈年桥²(), 储天然¹, 吴永汉³, 李康宁², 石延霞¹, 谢学文¹, 李磊¹, 范腾飞¹, 李宝聚¹(), 柴阿丽¹()

¹ 中国农业科学院蔬菜花卉研究所/蔬菜生物育种全国重点实验室，北京 100081
² 苍南县农业技术推广站，浙江温州 325800
³ 温州科技职业学院，浙江温州 325006

收稿日期:2024-10-21 接受日期:2024-12-04 出版日期:2025-02-16 发布日期:2025-02-24
通信作者:
柴阿丽，E-mail：chaiali@caas.cn。
李宝聚，E-mail：libaojuivf@163.com。
联系方式: 王少骅，E-mail：3163758116@qq.com。沈年桥，E-mail：cnsnq@163.com。王少骅和沈年桥为同等贡献作者。
基金资助:
国家重点研发计划(2023YFD1401200); 苍南县现代农业产业提升项目(2023CNYJY01); 中国农业科学院科技创新工程(CAAS-ASTIP-IVFCAAS); 国家大宗蔬菜产业技术体系(CARS-23)

Effects of Tomato-Rice Rotation on Physicochemical Properties and Microbial Communities of Soil with Continuous Cropping Obstacles in Cangnan, Zhejiang

WANG ShaoHua¹(), SHEN NianQiao²(), CHU TianRan¹, WU YongHan³, LI KangNing², SHI YanXia¹, XIE XueWen¹, LI Lei¹, FAN TengFei¹, LI BaoJu¹(), CHAI ALi¹()

¹ Institute of Vegetables and Flowers, Chinese Academy of Agricultural Sciences/State Key Laboratory of Vegetable Biobreeding, Beijing 100081
² Cangnan County Agricultural Technology Extension Station, Wenzhou 325800, Zhejiang
³ Wenzhou Vocational College of Science & Technology, Wenzhou 325006, Zhejiang

Received:2024-10-21 Accepted:2024-12-04 Published:2025-02-16 Online:2025-02-24

摘要/Abstract

摘要：

【目的】浙江苍南番茄长期连作导致土壤酸化、次生盐渍化、土壤板结和土传病害严重等一系列土壤连作障碍问题。本论文通过分析番茄-水稻轮作对长期连作土壤理化性质、酶活性、微生物量和微生物群落结构等的影响，旨在提供一种减轻土壤连作障碍、改善土壤环境的方法。【方法】设置番茄连续单作18年（T1）、番茄连作17年后番茄-水稻轮作1年（T2）、番茄连作15年后番茄-水稻轮作3年（T3）3组试验处理，采集土壤样本。采用pH计和电导率仪测定土壤pH和EC值，高温燃烧法、凯氏定氮法、氯化钾溶液浸提法等方法测定土壤总碳、总氮、铵态氮等土壤理化性质。使用酶活性试剂盒测定土壤酶活性，qPCR技术检测微生物总量和有害微生物浓度，选择性培养基平板涂布计数法对土壤可培养微生物进行计数。采用MiSeq PE3000高通量测序平台进行土壤宏基因组测序、拼接组装、序列比对和功能注释。【结果】不同处理土壤理化性质差异显著，番茄-水稻轮作1年和3年分别将土壤pH从单作的5.20提高至6.04和6.73，将EC值从单作的558 μS·cm^-1降至417和445 μS·cm^-1，碳氮比从9.16提高至10.45和10.74。轮作后土壤酶活性提高，过氧化氢酶、脲酶、多酚氧化酶活性分别由11.72 μmol·d^-1·g^-1、10.76 μg·d^-1·g^-1和22.67 mg·d^-1·g^-1提高至58.58 μmol·d^-1·g^-1、142.48 μg·d^-1·g^-1和37.10 mg·d^-1·g^-1。轮作后微生物数量和群落结构发生变化，有害微生物减少，土壤可培养放线菌含量增加，真菌/细菌比值降低，绿弯菌门（Chloroflexi）、酸杆菌门（Acidobacteria）、变形菌门（Proteobacteria）等显著增加，放线菌门（Actinobacteria）显著减少；轮作3年土壤中青枯、软腐、枯萎病菌的含量分别降至1.76×10³、7.28×10²和3.07×10³copies/g。轮作后土壤微生物潜在功能发生变化，碳水化合物代谢、能量代谢等相关基因丰度增加，新陈代谢中碳水化合物代谢相关基因上调。【结论】番茄-水稻轮作可改善长期单作导致的土壤酸化、盐碱化和土壤元素不平衡，提高土壤碳氮比和酶活性，减轻土传病害的发生，使得土壤由真菌型向细菌型转化，并改变了土壤微生物群落结构，促进土壤微生物碳水化合物代谢，对改善土壤连作障碍具有重要作用。

关键词: 番茄-水稻轮作, 土壤, 理化性质, 有害微生物, 微生物群落

Abstract:

【Objective】Long-term continuous cropping of tomato in Cangnan, Zhejiang Province leads to a series of soil continuous cropping obstacles, such as soil acidification, secondary salinization, soil compaction and serious soil-borne diseases. In this paper, the effects of tomato-rice rotation on soil physicochemical properties, enzyme activity, microbial biomass and microbial community structure under long-term continuous cropping were analyzed, aiming to provide a method to alleviate soil continuous cropping obstacles and improve soil environment.【Method】Three treatments were set up and soil samples were collected. T1 was tomato continuous monoculture for 18 years, T2 was tomato continuous monoculture for 17 years followed by one year of tomato-rice rotation, and T3 was tomato continuous monoculture for 15 years followed by three years of tomato-rice rotation. Soil pH and EC values were measured by pH meter and conductivity meter. Soil physicochemical properties such as total carbon, total nitrogen and ammonium nitrogen were determined by high temperature combustion method, Kjeldahl nitrogen fixation method and potassium chloride solution leaching method. Soil enzyme activities were determined using enzyme activity kits. Total and harmful microorganism concentrations were detected using qPCR, and soil culturable microorganisms were counted using selective medium plate smear counting method. The MiSeq PE3000 high-throughput sequencing platform was used for sequencing, splicing and assembly, sequence comparison and functional annotation of the soil microgenome.【Result】There were significant differences in soil physicochemical properties among different treatments. One and three years of tomato-rice rotation treatments increased soil pH from 5.20 to 6.04 and 6.73, and reduced EC from 558 μS·cm^-1 to 417 and 445 μS·cm^-1, and increased C﹕N ratios from 9.16 to 10.45 and 10.74. Soil enzyme activities were increased in the rotations, with catalase, urease, polyphenol oxidase activities increased from 11.72 μmol·d^-1·g^-1, 10.76 μg·d^-1·g^-1, and 22.67 mg·d^-1·g^-1to 58.58 μmol·d^-1·g^-1, 142.48 μg·d^-1·g^-1, and 37.10 mg·d^-1·g^-1. After crop rotation, the microbial population and community structure changed, harmful microorganisms decreased. The content of soil culturable actinomycetes increased, the fungi/bacteria ratio decreased. Chloroflexi, Acidobacteria, and Proteobacteria increased significantly, and Actinobacteria decreased significantly. The contents of Ralstonia solanacearum, Pectobacterium carotovorum subsp. carotovorum, P. c. subsp. brasiliensis and Fusarium sp. decreased to 1.76×10³, 7.28×10², 3.94×10³ and 3.07×10³ copies/g in the three years of crop rotation. The potential functions of soil microorganisms changed after crop rotation, with an increase in the abundance of genes related to carbohydrate metabolism, energy metabolism, and other related pathways. Specifically, genes associated with carbohydrate metabolism in metabolism were up-regulated.【Conclusion】Tomato-rice rotation can improve soil acidification, salinization and soil element imbalance caused by long-term monoculture, increase soil C﹕N ratio and enzyme activity, reduce the occurrence of soil-borne diseases, transform the soil from fungal type to bacterial type, change the structure of soil microbial community, and promote soil microbial carbohydrate metabolism, which is important for improving soil continuous cropping obstacles.

Key words: tomato-rice rotation, soil, physicochemical property, harmful microorganism, microbial community

王少骅, 沈年桥, 储天然, 吴永汉, 李康宁, 石延霞, 谢学文, 李磊, 范腾飞, 李宝聚, 柴阿丽. 浙江苍南番茄-水稻轮作对连作土壤理化性质和微生物群落的影响[J]. 中国农业科学, 2025, 58(4): 692-703.

WANG ShaoHua, SHEN NianQiao, CHU TianRan, WU YongHan, LI KangNing, SHI YanXia, XIE XueWen, LI Lei, FAN TengFei, LI BaoJu, CHAI ALi. Effects of Tomato-Rice Rotation on Physicochemical Properties and Microbial Communities of Soil with Continuous Cropping Obstacles in Cangnan, Zhejiang[J]. Scientia Agricultura Sinica, 2025, 58(4): 692-703.

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参考文献 33

[1]	BONANOMI G, LORITO M, VINALE F, WOO S L. Organic amendments, beneficial microbes, and soil microbiota: Toward a unified framework for disease suppression. Annual Review of Phytopathology, 2018, 56: 1-20. doi: 10.1146/annurev-phyto-080615-100046 pmid: 29768137
[2]	VAN AGTMAAL M, STRAATHOF A, TERMORSHUIZEN A, TEURLINCX S, HUNDSCHEID M, RUYTERS S, BUSSCHAERT P, LIEVENS B, DE BOER W. Exploring the reservoir of potential fungal plant pathogens in agricultural soil. Applied Soil Ecology, 2017, 121: 152-160.
[3]	CHENG H Y, ZHANG D Q, HUANG B, SONG Z X, REN L R, HAO B Q, LIU J, ZHU J H, FANG W S, YAN D D, LI Y, WANG Q X, CAO A C. Organic fertilizer improves soil fertility and restores the bacterial community after 1,3-dichloropropene fumigation. Science of the Total Environment, 2020, 738: 140345.
[4]	FIERER N, LEFF J W, ADAMS B J, NIELSEN U N, BATES S T, LAUBER C L, OWENS S, GILBERT J A, WALL D H, CAPORASO J G. Cross-biome metagenomic analyses of soil microbial communities and their functional attributes. Proceedings of the National Academy of Sciences of the United States of America, 2012, 109(52): 21390-21395.
[5]	BAHRAM M, HILDEBRAND F, FORSLUND S K, ANDERSON J L, SOUDZILOVSKAIA N A, BODEGOM P M, BENGTSSON-PALME J, ANSLAN S, COELHO L P, HAREND H, et al. Structure and function of the global topsoil microbiome. Nature, 2018, 560(7717): 233-237.
[6]	BALLHAUSEN M B, DE BOER W. The sapro-rhizosphere: Carbon flow from saprotrophic fungi into fungus-feeding bacteria. Soil Biology and Biochemistry, 2016, 102: 14-17.
[7]	KUZYAKOV Y, DOMANSKI G. Carbon input by plants into the soil. Journal of Plant Nutrition and Soil Science, 2000, 163(4): 421-431.
[8]	HERRMANN M, SAUNDERS A, SCHRAMM A. Archaea dominate the ammonia-oxidizing community in the rhizosphere of the freshwater macrophyte Littorella uniflora. Applied and Environmental Microbiology, 2008, 74(10): 3279-3283.
[9]	DALIAKOPOULOS I N, TSANIS I K, KOUTROULIS A, KOURGIALAS N N, VAROUCHAKIS A E, KARATZAS G P, RITSEMA C J. The threat of soil salinity: A European scale review. Science of the Total Environment, 2016, 573: 727-739.
[10]	BROCKETT B F T, PRESCOTT C E, GRAYSTON S J. Soil moisture is the major factor influencing microbial community structure and enzyme activities across seven biogeoclimatic zones in western Canada. Soil Biology and Biochemistry, 2012, 44(1): 9-20.
[11]	鲁如坤. 土壤农业化学分析方法. 北京: 中国农业科技出版社, 2000.
	LU R K. Soil Agrochemical Analysis Method. Beijing: China Agricultural Science and Technology Press, 2000. (in Chinese)
[12]	CHEN Y, ZHANG W Z, LIU X, MA Z H, LI B, ALLEN C, GUO J H. A real-time PCR assay for the quantitative detection of Ralstonia solanacearum in the horticultural soil and plant tissues. Journal of Microbiology and Biotechnology, 2010, 20(1): 193-201.
[13]	吴兴海, 邵秀玲, 邓明俊, 陈长法, 厉艳, 梁成珠. 番茄溃疡病菌实时荧光PCR快速检测方法研究. 江西农业学报, 2007, 19(3): 34-36.
	WU X H, SHAO X L, DENG M J, CHEN C F, LI Y, LIANG C Z. Study on rapid detection of Clavibacterm ichiganensis subsp. michiganensis by real-time fluorescent PCR. Acta Agriculturae Jiangxi, 2007, 19(3): 34-36. (in Chinese)
[14]	KANG H W, KWON S W, GO S J. PCR-based specific and sensitive detection of Pectobacterium carotovorum ssp. carotovorum by primers generated from a URP-PCR fingerprinting-derived polymorphic band. Plant Pathology, 2003, 52(2): 127-133.
[15]	QU Y K, TANG J, LI Z Y, ZHOU Z H, WANG J J, WANG S N, CAO Y D. Soil enzyme activity and microbial metabolic function diversity in soda saline-alkali rice paddy fields of Northeast China. Sustainability, 2020, 12(23): 10095.
[16]	HUANG Y, XIAO X, HUANG H Y, JING J Q, ZHAO H J, WANG L, LONG X E. Contrasting beneficial and pathogenic microbial communities across consecutive cropping fields of greenhouse strawberry. Applied Microbiology and Biotechnology, 2018, 102: 5717-5729. doi: 10.1007/s00253-018-9013-6 pmid: 29704041
[17]	程颖超, 康华军, 石延霞, 柴阿丽, 张红杰, 谢学文, 李宝聚. 辣椒疫霉菌RT-PCR检测技术的建立及应用. 园艺学报, 2018, 45(5): 997-1006. doi: 10.16420/j.issn.0513-353x.2017-0862
	CHENG Y C, KANG H J, SHI Y X, CHAI A L, ZHANG H J, XIE X W, LI B J. Development and application of real-time fluorescent quantitative PCR for detection of Phytophthora capsica. Acta Horticulturae Sinica, 2018, 45(5): 997-1006. (in Chinese)
[18]	CHEN L D, LI L, XIE X W, CHAI A L, SHI Y X, FAN T F, XIE J M, LI B J. An improved method for quantification of viable Fusarium cells in infected soil products by propidium monoazide coupled with real-time PCR. Microorganisms, 2022, 10(5): 1037.
[19]	ATALLAH Z K, BAE J, JANSKY S H, ROUSE D I, STEVENSON W R. Multiplex real-time quantitative PCR to detect and quantify Verticillium dahliae colonization in potato lines that differ in response to Verticillium wilt. Phytopathology, 2007, 97(7): 865-872.
[20]	MACDONALD C A, THOMAS N, ROBINSON L, TATE K R, ROSS D J, DANDO J, SINGH B K. Physiological, biochemical and molecular responses of the soil microbial community after afforestation of pastures with Pinus radiata. Soil Biology and Biochemistry, 2009, 41(8): 1642-1651.
[21]	BABIN D, DEUBEL A, JACQUIOD S, SØRENSEN S J, GEISTLINGER J, GROSCH R, SMALLA K. Impact of long-term agricultural management practices on soil prokaryotic communities. Soil Biology and Biochemistry, 2019, 129: 17-28.
[22]	VON LÜTZOW M, LEIFELD J, KAINZ M, KÖGEL-KNABNER I, MUNCH J C. Indications for soil organic matter quality in soils under different management. Geoderma, 2002, 105(3): 243-258.
[23]	ALLARD S M, WALSH C S, WALLIS A E, OTTESEN A R, BROWN E W, MICALLEF S A. Solanum lycopersicum (tomato) hosts robust phyllosphere and rhizosphere bacterial communities when grown in soil amended with various organic and synthetic fertilizers. Science of the Total Environment, 2016, 573: 555-563.
[24]	XIE X M, LIAO M, YANG J, CHAI J J, FANG S, WANG R H. Influence of root-exudates concentration on pyrene degradation and soil microbial characteristics in pyrene contaminated soil. Chemosphere, 2012, 88(10): 1190-1195.
[25]	LIU Y X, LI X, CAI K, CAI L T, LU N, SHI J X. Identification of benzoic acid and 3-phenylpropanoic acid in tobacco root exudates and their role in the growth of rhizosphere microorganisms. Applied Soil Ecology, 2015, 93: 78-87.
[26]	KUNITO T, AKAGI Y, PARK H D, TODA H. Influences of nitrogen and phosphorus addition on polyphenol oxidase activity in a forested andisol. European Journal of Forest Research, 2009, 128(4): 361-366.
[27]	DE BOER W, FOLMAN L B, SUMMERBELL R C, BODDY L. Living in a fungal world: Impact of fungi on soil bacterial niche development. FEMS Microbiology Reviews, 2005, 29(4): 795-811. pmid: 16102603
[28]	DE BOER W, HUNDSCHEID M P J, GUNNEWIEK P J A, DE RIDDER-DUINE A S, THION C, VEEN J A, WAL A. Antifungal rhizosphere bacteria can increase as response to the presence of saprotrophic fungi. PLoS ONE, 2015, 10(9): e0137988.
[29]	EDWARDS J, JOHNSON C, SANTOS-MEDELLÍN C, LURIE E, PODISHETTY N K, BHATNAGAR S, EISEN J A, SUNDARESAN V. Structure, variation, and assembly of the root-associated microbiomes of rice. Proceedings of the National Academy of Sciences of the United States of America, 2015, 112(8): E911-E920.
[30]	IBEKWE A M, POSS J A, GRATTAN S R, GRIEVE C M, SUAREZ D. Bacterial diversity in cucumber (Cucumis sativus) rhizosphere in response to salinity, soil pH, and boron. Soil Biology and Biochemistry, 2010, 42(4): 567-575.
[31]	LING N, ZHU C, XUE C, CHEN H, DUAN Y H, PENG C, GUO S W, SHEN Q R. Insight into how organic amendments can shape the soil microbiome in long-term field experiments as revealed by network analysis. Soil Biology and Biochemistry, 2016, 99: 137-149.
[32]	MAHERALI H, KLIRONOMOS J N. Influence of phylogeny on fungal community assembly and ecosystem functioning. Science, 2007, 316(5832): 1746-1748. doi: 10.1126/science.1143082 pmid: 17588930
[33]	LAUBER C L, HAMADY M, KNIGHT R, FIERER N. Pyrosequencing- based assessment of soil pH as a predictor of soil bacterial community structure at the continental scale. Applied and Environmental Microbiology, 2009, 75(15): 5111-5120.

病原菌 Pathogen	引物 Primer	序列 Sequence (5′-3′)	片段长度 Fragment size (bp)	参考文献 Reference
茄科雷尔氏菌 Ralstonia solanacearum	RSF RSR	GTGCCTGCCTCCAAAACGACT GACGCCACCCGCATCCCTC	159	[12]
密执安棍状杆菌密执安亚种 Clavibacter michiganensis subsp. michiganensis	Fan1 Fan2	GCATGTGCACCTCTCCTCTGTA CCCCACAAGGAGGCGTACTA	146	[13]
胡萝卜软腐果胶杆菌胡萝卜亚种 Pectobacterium carotovorum subsp. carotovorum	INPCCF INPCCR	TTCGATCACGCAACCTGCATTACT GGCCAAGCAGTGCCTGTATATCC	400	[14]
胡萝卜软腐果胶杆菌巴西亚种 Pectobacterium carotovorum subsp. brasiliensis	PMA1-F PMA1-R	GTGCCGGGTTTATGAC TGATAATG TCTTTCAC	142	[15]
瓜果腐霉 Pythium aphanidermatum	PA-4F PA-4R	CAATGGTCTGGGCAAAT TAAGTTCAGCGGGTAATC	166	[16]
辣椒疫霉 Phytophthora capsici	YM2F YM2R	ATTCCTCCTGATAGATAG CCCTCATCACAGAATGC	245	[17]
镰孢菌属 Fusarium sp.	F8-1 F8-2	GCTTCTCCCGAGTCCCA GCTCAGCGGCTTCCTAT	189	[18]
大丽轮枝菌 Verticillium dahliae	VertBt-F VertBt-R	AACAACAGTCCGATGGATAATTC GTACCGGGCTCGAGATCG	115	[19]

处理 Treatment	总碳 TC (g·kg^-1)	总氮 TN (g·kg^-1)	碳氮比 C/N	氨态氮 NH₄⁺-N (mg·kg^-1)	硝态氮 NO₃^--N (mg·kg^-1)	速效磷 AP (mg·kg^-1)	速效钾 AK (mg·kg^-1)	有机质 SOM (g·kg^-1)	电导率 EC (μS·cm^-1)	pH
T1	19.13±0.11a	2.08±0.05a	9.16c	5.03±0.04a	385.20±0.04a	59.50±1.98a	190.96±2.99c	31.35±1.30a	558±2a	5.21±0.08c
T2	16.53±0.28c	1.59±0.35b	10.45b	3.52±0.30c	246.69±0.30b	24.33±1.34b	332.85±4.41a	23.95±0.08c	417±3c	6.04±0.04b
T3	18.16±0.15b	1.69±0.03b	10.74a	4.32±0.12b	46.94±0.12c	22.31±1.32b	215.51±2.72b	27.78±0.68b	445±7b	6.73±0.11a

处理Treatment	铬Cr	铜Cu	锌Zn	砷As	镉Cd	铅Pb	汞Hg
T1	46.97±0.07b	56.68±1.55a	152.86±4.57a	5.95±0.02c	0.15±0.002a	29.65±0.08c	0.12±0.01a
T2	47.94±0.04a	26.73±0.17c	110.38±1.31c	8.50±0.06a	0.12±0.003c	31.51±0.17b	0.09±0.01c
T3	45.81±0.14c	29.69±0.12b	121.53±0.98b	6.83±0.09b	0.13±0.003b	33.50±0.10a	0.10±0.01b

处理 Treatment	过氧化氢酶 Catalase (μmol·d^-1·g^-1)	脲酶 Urease (μg·d^-1·g^-1)	多酚氧化酶 Polyphenol oxidase (mg·d^-1·g^-1)	酸性磷酸酶 Acid phosphatase (μmol·d^-1·g^-1)
T1	11.72±0.86c	10.76±0.06c	22.67±0.09c	20.49±0.85a
T2	58.58±0.11a	133.30±0.12b	37.10±0.26a	20.09±0.71a
T3	57.10±0.13b	142.48±0.10a	33.78±0.72b	10.63±0.10b

处理Treatment	细菌Bacterium		真菌Fungus		放线菌Actinomycete	真菌/细菌比值 Fungus/ bacterium ratio
处理Treatment	总量 Total concentration (pg·g^-1)	可培养细菌总量Concentration of culturable bacteria (cfu/g)	总量 Total concentration (pg·g^-1)	可培养真菌总量Concentration of culturable fungi (cfu/g)	可培养放线菌总量 Concentration of culturable actinomycetes (cfu/g)	真菌/细菌比值 Fungus/ bacterium ratio
T1	(2.24±0.07)×10⁵c	(1.10±0.06)×10⁷a	(5.39±0.11)×10³c	(2.50±0.06)×10⁴b	(4.40±0.08)×10⁵c	2.41×10^-2/1a
T2	(1.36±0.04)×10⁶a	(1.03±0.07)×10⁷a	(2.55±0.10)×10⁴a	(4.30±0.24)×10⁴a	(8.00±0.08)×10⁵b	1.88×10^-2/1b
T3	(7.82±0.03)×10⁵b	(4.10±0.12)×10⁶b	(1.21±0.39)×10⁴b	(2.80±0.07)×10⁴b	(2.04±0.06)×10⁶a	1.55×10^-2/1c

浙江苍南番茄-水稻轮作对连作土壤理化性质和微生物群落的影响

Effects of Tomato-Rice Rotation on Physicochemical Properties and Microbial Communities of Soil with Continuous Cropping Obstacles in Cangnan, Zhejiang

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处理Treatment	茄科雷尔氏菌 Rs	密执安棍状杆菌密执安亚种 Cmm	胡萝卜软腐果胶杆菌胡萝卜亚种 Pcc	胡萝卜软腐果胶杆菌巴西亚种 Pcb	瓜果腐霉 P. aphanidermatum	辣椒疫霉 P. capsici	镰孢菌属 F. sp.	大丽轮枝菌 V. dahliae
T1	(2.14±0.04)×10³b	-	(1.80±0.04)×10³a	(6.18±0.33)×10⁴a	-	-	(4.04±0.08)×10⁴a	-
T2	(2.37±0.04)×10³a	-	(1.24±0.06)×10³b	(1.59±0.11)×10⁴b	-	-	(3.39±0.08)×10⁴b	-
T3	(1.76±0.06)×10³c	-	(7.28±0.03)×10²c	(3.94±0.32)×10³c	-	-	(3.07±0.05)×10³c	-

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