温室黄瓜连作对土壤真菌数量和群落结构的影响

doi:10.7668/hbnxb.20190712

摘要/Abstract

摘要： 长期集约化种植带来的连作障碍问题已成为限制设施蔬菜行业可持续发展的重要瓶颈，阐明设施蔬菜长期连作条件下的土壤障碍因子（类型）是发展形成高效连作障碍克服技术的前提。以豫北地区设施黄瓜连作生产系统为研究对象，通过采集具有不同黄瓜连作年限的土壤样品（1，5，10，15，20 a），应用Real-time PCR和高通量测序的手段，探讨了温室黄瓜连作对土壤真菌数量和群落结构的影响。结果表明，温室黄瓜连作显著改变了土壤真菌数量，随着连作年限延长真菌数量呈先增加后降低的趋势，且在连作10 a土壤中达到峰值。土壤真细比变化趋势与真菌数量一致。高通量测序分析进一步表明，黄瓜连作显著影响了真菌群落的β多样性而非α多样性。随着连作年限延长，真菌群落中独有的OTU数量逐渐减少。子囊菌门（Ascomycota）是门水平下连作土壤真菌群落的优势成员，但其平均相对丰度对黄瓜连作响应不敏感。在目水平，小囊菌目（Microascales）、盘菌目（Pezizales）、未分类子囊菌（Norank_p_Ascomycota）和粪壳菌目（Sordariales）是真菌群落优势成员；在属水平，假埃希氏菌属（Pseudallescheria）、Lasiobolidium、赭霉属（Ochroconis）和毛壳菌属（Chaetomium）是真菌群落优势成员。这些优势真菌目和属的平均相对丰度受温室黄瓜连作影响显著，且多数与土壤理化因子存在显著的线性相关关系。冗余分析证明，土壤硝态氮、速效钾和有机质含量是驱动温室黄瓜连作土壤真菌群落结构变化的主要因子。总的来看，温室黄瓜长期连作显著影响了土壤真菌数量和群落结构。

关键词: 黄瓜, 连作, 真菌数量, 群落结构

Abstract: Continuous cropping obstacles caused by long-term intensive cultivation has become an important bottleneck restricting the sustainable development of greenhouse vegetable industry. Increasing the knowledge available regarding the soil mechanisms behind continuous cropping obstacles is beneficial to develop the effective approaches to overcome this difficult problem present in intensive greenhouse vegetable production. Here,based on a continuous greenhouse cucumber cropping system located at North Henan Province of China,we evaluated the changes in soil fungal abundance and community structure with increasing cucumber cultivation history(the duration from 1 to 20 years with the interval of 5 years per treatment)through Real-time PCR and high-throughput sequencing. Continuous cropping of greenhouse cucumber significantly altered soil fungal abundance. In brief,fungal abundance initially increased and then decreased as increasing greenhouse cultivation history,and the peak occurred at the tenth year after continuous cropping of greenhouse cucumber. The tendency of the ratio of soil fungal to bacterial abundance with increasing greenhouse cultivation history was in line with soil fungal abundance. High-throughput sequencing revealed that the β diversity rather than α diversity of soil fungal community was obviously altered by continuous cropping of greenhouse cucumber. Increasing greenhouse cucumber cultivation history lowered the numbers of unique OTU in fungal community. At phylum level,Ascomycota dominated soil fungal community,and its average relative abundance was insensitive to continuous cropping of greenhouse cucumber. At order level,Microascales,Pezizales,Norank_p_Ascomycota and Sordariales together dominated fungal community. At genus level, Pseudallescheria, Lasiobolidium, Ochroconis and Chaetomium were the predominant members in fungal community. Continuous cropping of greenhouse cucumber significantly changed average relative abundances of these dominant community members. Meanwhile,most of these dominant community members significantly correlated to soil physicochemical variables. RDA analysis indicated that soil nitrate and available potassium and organic mater contents were the most important contributors to the alteration of soil fungal community structure. In conclusion,the results demonstrated soil fungal abundance and community structure as affected by continuous cropping of greenhouse cucumber.

Key words: Cucumber, Continuous cropping, Fungi abundance, Community structure

中图分类号:

李玉娇, 刘星, 吴大付, 陈碧华, 任秀娟, 唐蛟. 温室黄瓜连作对土壤真菌数量和群落结构的影响[J]. 华北农学报, 2020, 35(1): 194-204. doi: 10.7668/hbnxb.20190712.

LI Yujiao, LIU Xing, WU Dafu, CHEN Bihua, REN Xiujuan, TANG Jiao. Effects of Continuous Cropping of Greenhouse Cucumber on Soil Fungal Abundance and Community Structure Province[J]. ACTA AGRICULTURAE BOREALI-SINICA, 2020, 35(1): 194-204. doi: 10.7668/hbnxb.20190712.

http://www.hbnxb.net/CN/Y2020/V35/I1/194

参考文献

[1] 兰挚谦,郑文德,林薇,马嘉伟,张凯歌,张雪艳. 不同土壤改良剂对番茄生长和土壤肥力的影响[J]. 河南农业科学,2019,48(5):91-98.doi:10.15933/j.cnki.1004-3268.2019.05.014.
Lan Z Q,Zheng W D,Lin W,Ma J W,Zhang K G,Zhang X Y. Effect of different soil amendment on the tomato growth characteristic and soil fertility[J]. Journal of Henan Agricultural Sciences,2019,48(5):91-98.
[2] 张帆,李姝,肖达,赵静,王然,郭晓军,王甦.中国设施蔬菜害虫天敌昆虫应用研究进展[J].中国农业科学,2015,48(17):3463-3476.doi:10.3864/j.issn.0578-1752.2015.17.013.
Zhang F,Li S,Xiao D,Zhao J,Wang R,Guo X J,Wang S. Progress in pest management by natural enemies in greenhouse vegetables in China[J]. Scientia Agricultura Sinica,2015,48(17):3463-3476.
[3] 李天来,杨丽娟.作物连作障碍的克服-难解的问题[J].中国农业科学,2016,49(5):916-918.doi:10.3864/j.issn.0578-1752.2016.05.011.
Li T L,Yang L J. Overcoming continuous cropping obstacles-the different problem[J].Scientia Agricultura Sinica,2016,49(5):916-918.
[4] 刘星,邱慧珍,张文明,张春红,朱静,马兴,程万莉.甘肃中部沿黄灌区马铃薯连作对土壤化学和生物学性质的影响[J].中国生态农业学报,2017,25(4):581-593.doi:10.13930/j.cnki.cjea.160848.
Liu X,Qiu H Z,Zhang W M,Zhang C H,Zhu J,Ma X,Cheng W L. Effect of continuous potato monoculture on soil chemical and biological properties in Yellow River Irrigation Area in central Gansu Province[J]. Chinese Journal of Eco-Agriculture,2017,25(4):581-593.
[5] Huang L F,Song L X,Xia X J,Mao W H,Shi K,Zhou Y H,Yu J Q. Plant-soil feedbacks and soil sickness:from mechanisms to application in agriculture[J]. Journal of Chemical Ecology,2013,39(2):232-242.doi:10.1007/s10886-013-0244-9.
[6] Li X G,Ding C F,Hua K,Zhang T L,Zhang Y N,Zhao L,Yang Y R,Liu J G,Wang X X. Soil sickness of peanuts is attributable to modifications in soil microbes induced by peanut root exudates rather than to direct allelopathy[J]. Soil Biology and Biochemistry,2014,78(11):149-159.doi:10.1016/j.soilbio.2014.07.019.
[7] Chen T,Liu S,Wu L K,Lin W X,Sampietro D A. Soil sickness:current status and future perspectives[J]. Allelopathy Journal,2015,36(2):167-196.
[8] Huang H C,Chou C H,Erickson R S. Soil sickness and its control[J]. Allelopathy Journal,2006,18(1):1-21.
[9] Li W H,Liu Q Z,Chen P. Effect of long-term continuous cropping of strawberry on soil bacterial community structure and diversity[J]. Journal of Integrative Agriculture,2018,17(11):2570-2582.doi:10.1016/S2095-3119(18)61944-6.
[10] Xiao W L,Wang Z X,Wu F Z,Zhou X G. Effects of soil improvement technology on soil quality in solar greenhouse[J]. Environmental Science and Pollution Research,2018,25(24):24093-24100.doi:10.1007/s11356-018-2321-7.
[11] Zhou X G,Liu J,Wu F Z. Soil microbial communities in cucumber monoculture and rotation systems and their feedback effects on cucumber seedling growth[J]. Plant and Soil,2017,415(1-2):507-520.doi:10.1007/s11104-017-3181-5.
[12] Yao Z Y,Xing J J,Gu H P,Wang H Z,Wu J J,Xu J M,Brookes P C. Development of microbial community structure in vegetable-growing soils from open-field to plastic-greenhouse cultivation based on the PLFA analysis[J]. Journal of Soils and Sediments,2016,16(8):2041-2049.doi:10.1007/s11368-016-1397-2.
[13] Zhou X G,Gao D M,Liu J,Qiao P L,Zhou X L,Lu H B,Wu X,Liu D,Jin X,Wu F Z. Changes in rhizosphere soil microbial communities in a continuously monocropped cucumber(Cucumis sativus L.)system[J]. European Journal of Soil Biology,2014,60:1-8.doi:10.1016/j.ejsobi.2013.10.005.
[14] Zhou X G,Wu F Z. Dynamics of the diversity of fungal and Fusarium communities during continuous cropping of cucumber in the greenhouse[J]. FEMS Microbiology Ecology,2012,80(2):469-478.doi:10.1111/j.1574-6941.2012.01312.
x.
[15] Yao H Y,Jiao X D,Wu F Z. Effects of continuous cucumber cropping and alternative rotations under protected cultivation on soil microbial community diversity[J]. Plant and Soil,2006,284(1-2):195-203.doi:10.1007/s11104-006-0023-2.
[16] Bonanomi G,Antignani V,Capodilupo M,Scala F. Identifying the characteristics of organic soil amendments that suppress soilborne plant diseases[J]. Soil Biology and Biochemistry,2010,42(2):136-144.doi:10.1016/j.soilbio.2009.10.012.
[17] Zhou D B,Jing T,Chen Y F,Wang F,Qi D F,Feng R J,Xie J H,Li H P. Deciphering microbial diversity associated with Fusarium wilt-diseased and disease-free banana rhizosphere soil[J]. BMC Microbiology,2019,19:161.doi:10.1186/s12866-019-1531-6.
[18] Xiong W,Li R,Ren Y,Liu C,Zhao Q Y,Wu H S,Jousset A,Shen Q R. Distinct roles for soil fungal and bacterial communities associated with the suppression of vanilla Fusarium wilt disease[J]. Soil Biology and Biochemistry,2017,107:198-207.doi:10.1016/j.soilbio.2017.01.010.
[19] Xiong W,Zhao Q Y,Zhao J,Xun W B,Li R,Zhang R F,Wu H S,Shen Q R. Different continuous cropping spans significantly affect microbial community membership and structure in a vanilla-grown soil as revealed by deep pyrosequencing[J]. Microbial Ecology,2015,70(1):209-218.doi:10.1007/s00248-014-0516-0.
[20] Li X G,Ding C F,Zhang T L,Wang X X. Fungal pathogen accumulation at the expense of plant-beneficial fungi as a consequence of consecutive peanut monoculturing[J]. Soil Biology and Biochemistry,2014,72:11-18.doi:10.1016/j.soilbio.2014.01.019.
[21] Li J G,Ren G D,Jia Z J,Dong Y H. Composition and activity of rhizosphere microbial communities associated with healthy and diseased greenhouse tomatoes[J]. Plant and Soil,2014,485(1-2):337-347.doi:10.1007/s11104-014-2097-6.
[22] Lu L H,Yin S X,Liu X,Zhang W M,Gu T Y,Shen Q R,Qiu H Z. Fungal networks in yield-invigorating and-debilitating soils induced by prolonged potato monoculture[J]. Soil Biology and Biochemistry,2013,65:186-194.doi:10.1016/j.soilbio.2013.05.025.
[23] Chen M N,Li X,Yang Q L,Chi X Y,Pan L J,Chen N,Yang Z,Wang T,Wang M,Yu S L. Soil eukaryotic microorganism succession as affected by continuous cropping of peanut-pathogenic and beneficial fungi were selected[J]. PLoS One,2012,7(7):e40659.doi:10.1371/journal.pone.0040659.
[24] 张瑞福,沈其荣.抑病型土壤的微生物区系特征及调控[J].南京农业大学学报,2012,35(5):125-132.doi:10.7685/j.issn.1000-2030.2012.05.014.
Zhang R F,Shen Q R. Characterization of the microbial flora and management to induce the disease suppressive soil[J]. Journal of Nanjing Agricultural University,2012,35(5):125-132.
[25] Liu X,Zhang Y,Ren X J,Chen B H,Shen C W,Wang F. Long-term greenhouse vegetable cultivation alters the community structures of soil ammonia oxidizers[J]. Journal of Soils and Sediments,2019,19(2):883-902.doi:10.1007/s11368-018-2089-x.
[26] Rousk J,Bååth E,Brookes P C,Lauber C L,Lozupone C,Caporaso J G,Knight R,Fierer N. Soil bacterial and fungal communities across a pH gradient in an arable soil[J]. The ISME Journal,2010,4:1340-1351.doi:10.1038/ismej.2010.58.
[27] 董艳辉,于宇凤,温鑫,王亦学,聂园军,侯丽媛,李亚莉,刘江,任元,王育川,曹秋芬,吴慎杰,王斌,秦永军. 基于高通量测序的藜麦连作根际土壤微生物多样性研究[J]. 华北农学报,2019,34(2):205-211.doi:10.7668/hbnxb.201751218.
Dong Y H,Yu Y F,Wen X,Wang Y X,Nie Y J,Hou L Y,Li Y L,Liu J,Ren Y,Wang Y C,Cao Q F,Wu S J,Wang B,Qin Y J. Studies on diversity of rhizosphere microorganism in quinoa continuous cropping soil by high throughput sequencing[J]. Acta Agriculturae Boreali-Sinica,2019,34(2):205-211.
[28] 杨珍,戴传超,王兴祥,李孝刚.作物土传真菌病害发生的根际微生物机制研究进展[J].土壤学报,2019,56(1):12-22.doi:10.11766/trxb2018032600578.
Yang Z,Dai C C,Wang X X,Li X G. Advance in research on rhizosphere microbial mechanisms of crop soil-borne fungal diseases[J]. Acta Pedologica Sinica,2019,56(1):12-22.
[29] Shipton P J. Monoculture and soilborne plant pathogens[J]. Annual Review of Phytopathology,1977,15:387-407.doi:10.1146/annurev.py.15.090177.002131.
[30] Larkin R P. Soil health paradigms and implications for disease management[J]. Annual Review of Phytopathology,2015,53:199-221.doi:10.1146/annurev-phyto-080614-120357.
[31] Doran J W,Zeiss M R. Soil health and sustainability:managing the biotic component of soil quality[J]. Applied Soil Ecology,2000, 15(1):3-11.doi:10.1016/s0929-1393(00)00067-6.
[32] Raaijmakers J M,Paulitz T C,Steinberg C,Alabouvette C,Moënne-Loccoz Y. The rhizosphere:a playground and battlefield for soilborne pathogens and beneficial microorganisms[J]. Plant and Soil,2009,321(1-2):341-361.doi:10.1007/s11104-008-9568-6.
[33] Omirou M,Rousidou C,Bekris F,Papadopoulou K K,Menkissoglou-Spiroudi U,Ehaliotis C,Karpouzas D G. The impact of biofumigation and chemical fumigation methods on the structure and function of the soil microbial community[J]. Microbial Ecology,2011,61(1):201-213.doi:10.1007/s00248-010-9740-4.
[34] van der Heijden M G A,Bardgett R D,van Straalen N M. The unseen majority:soil microbes as drivers of plant diversity and productivity in terrestrial ecosystems[J]. Ecology Letters,2008,11(3):296-310.doi:10.1111/j.1461-0248.2007.01139.
x.
[35] Kennedy A C,Smith K L. Soil microbial diversity and the sustainability of agricultural soils[J]. Plant and Soil,1995,170(1):75-86.doi:10.1007/BF02183056.
[36] Schnitzer S A,Klironomos J N,HillerisLambers J,Kinkel L L,Reich P B,Xiao K,Rillig M C,Sikes B A,Callaway R M,Mangan S A,van Nes E H,Scheffer M. Soil microbes drive the classic plant diversity-productivity pattern[J].Ecology,2011,92(2):296-303.doi:10.1890/10-0773.1.
[37] Chaparro J M,Sheflin A M,Manter D K,Vivanco J M. Manipulating the soil microbiome to increase soil health and plant fertility[J]. Biology and Fertility of Soils,2012,48(5):489-499.doi:10.1007/s00374-012-0691-4.
[38] Welbaum G E,Sturz A V,Dong Z M,Nowak J. Managing soil microorganisms to improve productivity of agro-ecosystems[J]. Critical Reviews in Plant Sciences,2004,23(2):175-193.doi:10.1080/07352680490433295.
[39] Qin S H,Yeboah S,Cao L,Zhang J L,Shi S L,Liu Y H. Breaking continuous potato cropping with legumes improves soil microbial communities,enzyme activities and tuber yield[J]. PLoS One,2017,12(5):e0175934.doi:10.1371/journal.pone.0175934.
[40] Fu H D,Zhang G X,Zhang F,Sun Z P,Geng G M,Li T L. Effects of continuous tomato monoculture on soil microbial properties and enzyme activities in a solar greenhouse[J]. Sustainability,2017,9:317.doi:10.3390/su9020317.
[41] Kang Y L,Jing F,Sun W Q,Liu J G,Jiang G Y. Soil microbial communities changed with a continuously monocropped processing tomato system[J]. Acta Agriculturae Scandinavica,Section B-Soil and Plant Science,2017,68(2):149-160.doi:10.1080/09064710.2017.1370124.
[42] Li C,Li X M,Kong W D,Wu Y,Wang J G. Effect of monoculture soybean on soil microbial community in the Northeast China[J]. Plant and Soil,2010,330(1-2):423-433.doi:10.1007/s11104-009-0216-6.
[43] 魏巍.大豆长期连作土壤对根腐病病原微生物的抑制作用[D].长春:中国科学院研究生院,2012.
Wei W. The suppressiveness caused by long-term continuous cropping of soybean on the root rot and pathogens[D]. Changchun:Graduate University of Chinese Academy of Sciences,2012.
[44] Gong L,He G X,Liu W G. Long-term cropping effects on agricultural sustainability in Alar Oasis of Xinjiang,China[J]. Sustainability,2016,8(1):61.doi:10.3390/su8010061.
[45] Zhang W,Long X Q,Huo X D,Chen Y F,Lou K. 16S rRNA-based PCR-DGGE analysis of actinomycete communities in fields with continuous cotton cropping in Xinjiang,China[J]. Microbial Ecology,2013,66(2):385-393.doi:10.1007/s00248-012-0160-5.
[46] Jirout J,Šimek M,Elhottová D. Fungal contribution to nitrous oxide emissions from cattle impacted soils[J]. Chemosphere,2013,90(2):565-572.doi:10.1016/j.chemosphere.2012.08.031.
[47] Zhang J H,Yu H J,Ge X,Pan D D,Shen Y H,Qiao P L,Wu F Z,Zhou X G. Effects of vanillin on cucumber(Cucumis sativus L.)seedling rhizosphere fungal community composition[J]. Allelopathy Journal,2018,44(2):169-179.doi:10.26651/allelo.j/2018-44-2-1162.
[48] 马宁宁,李天来.设施番茄长期连作土壤微生物群落结构及多样性分析[J].园艺学报,2013,40(2):255-264.doi:10.16420/j.issn.0513-353x.2013.02.022.
Ma N N,Li T L. Effect of long-term continuous cropping of protected tomato on soil microbial community structure and diversity[J]. Acta Horticulturae Sinica,2013,40(2):255-264.
[49] Guo X F. Diversity and community structure of fungi in the roots of Machilus pauhio in different age groups[J]. Applied Ecology and Environmental Research,2019,17(2):2073-2083.doi:10.15666/aeer/1702_20732083.
[50] 孟品品,刘星,邱慧珍,张文明,张春红,王蒂,张俊莲,沈其荣.连作马铃薯根际土壤真菌种群结构及其生物效应[J].应用生态学报,2012,23(11):3079-3086.doi:10.13287/j.1001-9332.2012.0464.
Meng P P,Liu X,Qiu H Z,Zhang W M,Zhang C H,Wang D,Zhang J L,Shen Q R. Fungal population structure and its biological effect in rhizosphere soil of continuously cropped potato[J]. Chinese Journal of Applied Ecology,2012,23(11):3079-3086.
[51] 马云华,魏珉,王秀峰.日光温室连作黄瓜根区微生物区系及酶活性的变化[J].应用生态学报,2004,15(6):1005-1008.doi:10.13287/j.1001-9332.2004.0214.
Ma Y H,Wei M,Wang X F. Variation of microflora and enzyme activity in continuous cropping cucumber soil in solar greenhouse[J].Chinese Journal of Applied Ecology,2004,15(6):1005-1008.

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