西兰花残体还田对棉花黄萎病防治效果及其对不同生育时期土壤细菌群落的影响

doi:10.3864/j.issn.0578-1752.2019.24.006

摘要/Abstract

摘要：

【目的】研究土壤中添加西兰花残体（broccoli residues,BR）对棉花黄萎病及不同生育时期土壤细菌群落结构的影响,为棉花黄萎病的绿色生态防控和化学农药的减量施用提供新途径和思路。【方法】通过田间小区试验,分别以西兰花残体还田和不含有西兰花残体（CK）的耕层土壤中播种的棉花为试验对象,监测不同处理的棉花黄萎病的发生动态。采用实时荧光定量PCR（real-time PCR）和高通量测序（Illumina MiSeq）技术分别测定不同时期土壤中大丽轮枝菌（Verticillium dahliae）DNA拷贝数量和土壤细菌群落,进而分析西兰花残体还田对土壤中病原菌数量变化和土壤细菌群落的影响。采用主成分分析探索西兰花残体还田对不同生育时期土壤细菌群落在门和属水平的结构变化特征与规律。【结果】西兰花残体还田后棉花黄萎病的发病率和病情指数均呈现出下降趋势,且发病高峰时间推迟,在发病高峰期对黄萎病的防治效果达到70.77%,建立了整个生育期内病情指数-时间病程发展曲线,平均防治效果为57.21%。与空白对照相比,西兰花残体还田处理在棉花生长季和非生长季的4个阶段土壤中大丽轮枝菌DNA拷贝数量分别降低了10.96%、11.11%、25.95%和11.25%。高通量测序分析表明,不同生育时期西兰花残体还田处理显著提高了土壤细菌多样性,丰富度指数Chao1均显著上升,ACE指数在播种前期、花铃期和吐絮期显著上升。与空白对照相比,在不同生育时期内,西兰花残体还田后土壤中的放线菌门（Actinobacteria）菌群的相对丰度呈现显著上升。同时研究表明,西兰花残体还田后优势菌群组成在不同生育时期存在差别,在播种前期和苗期,厚壁菌门（Firmicutes）菌群上升为优势菌群;在蕾期和花铃期,蓝藻细菌门（Cyanobacteria）菌群成为优势菌群。主成分分析表明,西兰花残体还田改变了苗期、蕾期、花铃期和吐絮期的细菌群落结构。进一步分析表明,西兰花残体还田显著增加了链霉菌属（Streptomyces）和芽孢杆菌属（Bacillus）菌群的相对丰度。【结论】西兰花残体还田能够有效抑制棉花黄萎病的发生,降低土壤中大丽轮枝菌DNA拷贝的数量,改变土壤细菌群落结构,增加有益微生物的相对丰度,是一种有效控制棉花黄萎病的绿色措施。

关键词: 西兰花残体, 大丽轮枝菌, 棉花黄萎病, 细菌群落结构, 高通量测序, 生育时期

Abstract:

【Objective】The objective of this study is to research the effects of broccoli residues (BR) on cotton verticillium wilt and soil bacterial community structure at different growth stages, and to provide new ways and ideas for green ecological control of cotton verticillium wilt and reduction of chemical pesticides.【Method】In the field plot experiment, the soil planted with cotton was treated with broccoli residues and no broccoli residues (CK). The incidence dynamics of cotton verticillium wilt in different treatments were monitored at different growth stages. The number of DNA copies of Verticillium dahliae was determined by real-time quantitative PCR, and the structure of soil bacterial communities was measured by high-throughput sequencing (Illumina MiSeq). The effects of broccoli residues returning to soil on the quantity of pathogen and the community of soil bacteria were analyzed. Principal component analysis (PCA) was used to explore the characteristics and rules of structural changes of soil bacterial community at the level of phylum and genus in different growth stages.【Result】The incidence and disease index of cotton verticillium wilt showed a downward trend after the return of broccoli residues to soil, respectively. Moreover, the peak period of verticillium wilt was delayed, and 70.77% control efficacy was achieved at the peak period. The development curve of disease index and time course of disease in the whole growth period was established, and the average control efficacy was 57.21%. Compared to the blank control, the number of DNA copies of V. dahliae was decreased by 10.96%, 11.11%, 25.95% and 11.25% at the 4 stages of cotton growing and non-growing season, respectively, after the return of broccoli residues to soil. Illumina MiSeq analysis showed that broccoli residues treatment significantly increased soil bacterial diversity. The richness index Chao1 was increased significantly at all growth stages, and the ACE index was significantly increased at the pre-sowing stage, flowering and boll stage and boll-opening stage. Compared to the blank control, the relative abundance of Actinobacteria was increased significantly at different growth stages after the return of broccoli residues to soil. Meanwhile, the results showed that there were differences in the composition of dominant microorganisms at different growth stages after the return of broccoli residues to soil. For example, Firmicutes increased to the dominant microflora at the pre-sowing stage and seedling stage, and Cyanobacteria became the dominant microflora at the bud stage and flowering and boll stage. Principal component analysis showed that broccoli residues to soil changed the structure of bacterial community at seedling stage, bud stage, flowering and boll stage and boll-opening stage. Further analysis showed that the relative abundance of Streptomyces and Bacillus was significantly increased after the return of broccoli residues to soil.【Conclusion】Broccoli residues returning to soil can effectively inhibit the occurrence of cotton verticillium wilt, reduce the number of DNA copies of V. dahliae in soil, change the structure of soil bacterial community, and increase the relative abundance of beneficial microorganisms, which is an effective green measure to control cotton verticillium wilt.

Key words: broccoli residues, Verticillium dahliae, cotton verticillium wilt, bacterial community structure, Illumina MiSeq, growth stage

赵卫松,郭庆港,李社增,王亚娇,鹿秀云,王培培,苏振贺,张晓云,马平. 西兰花残体还田对棉花黄萎病防治效果及其对不同生育时期土壤细菌群落的影响[J]. 中国农业科学, 2019, 52(24): 4505-4517.

WeiSong ZHAO,QingGang GUO,SheZeng LI,YaJiao WANG,XiuYun LU,PeiPei WANG,ZhenHe SU,XiaoYun ZHANG,Ping MA. Control Efficacy of Broccoli Residues on Cotton Verticillium Wilt and Its Effect on Soil Bacterial Community at Different Growth Stages[J]. Scientia Agricultura Sinica, 2019, 52(24): 4505-4517.

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参考文献 42

[1]	王娜, 陶伟, 陈双林, 闫淑珍 . 植物内生细菌在棉花体内的定殖动态及对棉花黄萎病的生物防治效果. 植物保护学报, 2016,43(2):207-214.
	WANG N, TAO W, CHEN S L, YAN S Z . Colonization trends of endophytic bacteria in cotton and their biological control effect on cotton Verticillium wilt. Journal of Plant Protection, 2016,43(2):207-214. (in Chinese)
[2]	FRADIN E F, THOMMA B P . Physiology and molecular aspects of Verticillium wilt diseases caused by V. dahliae and V. albo-atrum. Molecular Plant Pathology, 2006,7(2):71-86.
[3]	ERDOGAN O, BENLIOGLU K . Biological control of Verticillium wilt on cotton by the use of fluorescent Pseudomonas spp. under field conditions. Biological Control, 2010,53(1):39-45.
[4]	KURT S, DERVIS S, SAHINLER S . Sensitivity of Verticillium dahliae to prochloraz and prochloraz-manganese complex and control of Verticillium wilt of cotton in the field. Crop Protection, 2003,22(1):51-55.
[5]	ZHENG Y, XUE Q Y, XU L L, XU Q, LU S, GU C, GUO J H . A screening strategy of fungal biocontrol agents towards Verticillium wilt of cotton. Biological Control, 2011,56(3):209-216.
[6]	周兆华, 张天真, 潘家驹, 陈兆夏, 蒋伟民 . 大丽轮枝菌在棉花品种上的致病力分化研究. 中国农业科学, 2000,33(2):51-57.
	ZHOU Z H, ZHANG T Z, PAN J J, CHEN Z X, JIANG W M . Pathogenicity differentiation of Verticillium dahliae on cotton varieties. Scientia Agricultura Sinica, 2000,33(2):51-57. (in Chinese)
[7]	朱荷琴, 简桂良, 宋晓轩 . 棉田黄萎病菌致病型群落结构研究. 棉花学报, 2004,16(3):147-151.
	ZHU H Q, JIAN G L, SONG X X . Community structure of pathogenic type of Verticillium dahliae Kleb. in cotton field. Cotton Science, 2004,16(3):147-151. (in Chinese)
[8]	简桂良, 卢美光, 朱荷琴 . 棉田黄萎病菌致病型结构初步研究. 植物保护学报, 2005,32(1):109-110.
	JIAN G L, LU M G, ZHU H Q . A preliminary study on the pathogenic structure of Verticillium dahliae in cotton field. Journal of Plant Protection, 2005,32(1):109-110. (in Chinese)
[9]	巩彪, 张丽丽, 隋申利, 王秀峰, 魏珉, 史庆华, 杨凤娟, 李岩 . 大蒜秸秆对番茄根结线虫病及根际微生态的影响. 中国农业科学, 2016,49(5):933-941.
	GONG B, ZHANG L L, SUI S L, WANG X F, WEI M, SHI Q H, YANG F J, LI Y . Effects of garlic straw application on controlling tomato root-knot nematode disease and rhizospheric microecology. Scientia Agricultura Sinica, 2016,49(5):933-941. (in Chinese)
[10]	连宾, 王进军, 陆玲 . 植物与微生物的化感作用. 南京师大学报 (自然科学版), 2007,30(1):88-94.
	LIAN B, WANG J J, LU L . Research progress of allelopathy on microorganism to plant. Journal of Nanjing Normal University (Natural Science Edition), 2007,30(1):88-94. (in Chinese)
[11]	SHETTY K G, SUBBARAO K V, HUISMAN O C, HUBBARD J C . Mechanism of broccoli-mediated Verticillium wilt reduction in cauliflower. Phytopathology, 2000,90(3):305-310.
[12]	SUBBARAO K V, HUBBARD J C, KOIKE S T . Evaluation of broccoli residue incorporation into field soil for Verticillium wilt control in cauliflower. Plant Disease, 1999,83(2):124-129.
[13]	INDERBITZIN P, WARD J, BARBELLA A, SOLARES N, IZYUMIN D, BURMAN P, CHELLEMI D O, SUBBARAO K V . Soil microbiomes associated with Verticillium wilt-suppressive broccoli and chitin amendments are enriched with potential biocontrol agents. Phytopathology, 2018,108(1):31-43.
[14]	IKEDA K, BANNO S, FURUSAWA A, SHIBATA S, NAKAHO K, FUJIMURA M . Crop rotation with broccoli suppresses verticillium wilt of eggplant. Journal of General Plant Pathology, 2015,81(1):77-82.
[15]	DAVIS J R, HUISMAN O C, EVERSON D O, NOLTE P, SORENSON L H, SCHNEIDER A T . The suppression of Verticillium wilt of potato using corn as a green manure crop. American Journal of Potato Research, 2010,87(2):195-208.
[16]	LARKIN R P, HONEYCUTT C W, OLANYA M O . Management of Verticillium wilt of potato with disease-suppressive green manures and as affected by previous cropping history. Plant Disease, 2011,95(5):568-576.
[17]	NJOROGE S M C, KABIR Z, MARTIN F N, KOIKE S T, SUBBARAO K V . Comparison of crop rotation for Verticillium wilt management and effect on Pythium species in conventional and organic strawberry production. Plant Disease, 2009,93(5):519-527.
[18]	赵卫松, 李社增, 鹿秀云, 郭庆港, 王亚娇, 王培培, 张晓云, 董丽红, 苏振贺, 马平 . 西兰花植株残体还田对棉花黄萎病的防治效果及其安全性评价. 中国生物防治学报, 2019,35(3):449-455.
	ZHAO W S, LI S Z, LU X Y, GUO Q G, WANG Y J, WANG P P, ZHANG X Y, DONG L H, SU Z H, MA P . Safety evaluation of broccoli residues returning on cotton growth and its control effect on Verticillium wilt. Chinese Journal of Biological Control, 2019,35(3):449-455. (in Chinese)
[19]	李社增, 马平, 刘杏忠, HUANG H C, 陈新华 . 利用拮抗细菌防治棉花黄萎病. 华中农业大学学报, 2001,20(5):422-425.
	LI S Z, MA P, LIU X Z, HUANG H C, CHEN X H . Biological control of cotton Verticillium wilt by antagonistic bacteria. Journal of Huazhong Agricultural University, 2001,20(5):422-425. (in Chinese)
[20]	LU R, LI Y P, LI W X, XIE Z S, FAN C L, LIU P X, DENG S X . Bacterial community structure in atmospheric particulate matters of different sizes during the haze days in Xi’an,China. Science of the Total Environment, 2018,637/638:244-252.
[21]	肖蕊, 余真真, ELSHARAWY A A, 魏锋, 杨家荣 . 土壤中棉花黄萎病菌SYBR Green Ⅰ荧光RT-PCR定量检测技术研究. 菌物学报, 2011,30(4):598-603.
	XIAO R, YU Z Z, ELSHARAWY A A, WEI F, YANG J R . SYBR Green I real time RT-PCR assay for quantitatively detecting the occurrence of Verticillium dahliae of cotton in naturally infested soil. Mycosystema, 2011,30(4):598-603. (in Chinese)
[22]	李淑敏, 郑成彧, 张润芝, 杨自超, 曲红云, 刘彤彤, 袁睿, 姚小桐, 王雪蓉, 许宁, 张春怡 . 生物熏蒸对大棚连作茄子产量和黄萎病发病率影响. 东北农业大学学报, 2017,48(5):35-41.
	LI S M, ZHENG C Y, ZHANG R Z, YANG Z C, QU H Y, LIU T T, YUAN R, YAO X T, WANG X R, XU N, ZHANG C Y . Effect of biofumigation on yield and Verticillium wilt incidence of continuous eggplant in greenhouse. Journal of Northeast Agricultural University, 2017,48(5):35-41. (in Chinese)
[23]	乔俊卿, 刘邮洲, 余翔, 梁雪杰, 陈志谊, 刘永锋, 张英 . 集成生物防治和秸秆还田技术对设施番茄增产及土传病害防控效果研究. 中国生物防治学报, 2013,29(4):547-554.
	QIAO J Q, LIU Y Z, YU X, LIANG X J, CHEN Z Y, LIU Y F, ZHANG Y . Evaluation of yield increasing and control efficiency of tomato soil-borne diseases under the integrated application of straw returning and biocontrol agent. Chinese Journal of Biological Control, 2013,29(4):547-554. (in Chinese)
[24]	张政文, 孙秀娟, 胡乃娟, 黄卉, 朱利群, 卞新民 . 麦秸掩埋还田对赤霉菌(Fusarium graminearum Sehw.)存活率和水稻带菌的影响. 植物病理学报, 2014,44(4):443-448.
	ZHANG Z W, SUN X J, HU N J, HUANG H, ZHU L Q, BIAN X M . Effect of straw ditch-buried return depth on Fusarium graminearum survival rate and carrier rate of rice. Acta Phytopathologica Sinica, 2014,44(4):443-448. (in Chinese)
[25]	CHAWLA S, WOODWARD J E, WHEELER T A, . Influence of Verticillium dahliae infested peanut residue on wilt development in subsequent cotton. International Journal of Agronomy, 2012,2012: Article ID 212075.
[26]	李洪林, 刘凤艳, 龚振平, 靳学慧, 黄世文 . 稻秆还田对水稻主要病害发生的影响. 作物研究, 2012,26(1):7-10.
	LI H L, LIU F Y, GONG Z P, JIN X H, HUANG S W . Effect of straw return back to paddy field on occurrence of rice major diseases. Crop Research, 2012,26(1):7-10. (in Chinese)
[27]	ENWALL K, NYBERG K, BERTILSSON S, CEDERLUND H, STENSTRÖM J, HALLIN S . Long-term impact of fertilization on activity and composition of bacterial communities and metabolic guilds in agricultural soil. Soil Biology and Biochemistry, 2007,39(1):106-115.
[28]	SCHUTTER M E, SANDENO J M, DICK R P . Seasonal, soil type, and alternative management influences on microbial communities of vegetable cropping systems. Biology and Fertility of Soils, 2001,34(6):397-410.
[29]	GÓMEZ-SAGASTI M T, ALKORTA I, BECERRIL J M, EPELDE L, ANZA M, GARBISU C . Microbial monitoring of the recovery of soil quality during heavy metal phytoremediation. Water, Air, and Soil Pollution, 2012,223(6):3249-3262.
[30]	吴林坤, 林向民, 林文雄 . 根系分泌物介导下植物-土壤-微生物互作关系研究进展与展望. 植物生态学报, 2014,38(3):298-310.
	WU L K, LIN X M, LIN W X . Advances and perspective in research on plant-soil-microbe interactions mediated by root exudates. Chinese Journal of Plant Ecology, 2014,38(3):298-310. (in Chinese)
[31]	SRIVASTAVA R, KHALID A, SINGH U S, SHARMA A K . Evaluation of arbuscular mycorrhizal fungus, fluorescent Pseudomonas and Trichoderma harzianum formulation against Fusarium oxysporum f. sp. lycopersici for the management of tomato wilt. Biological Control, 2010,53(1):24-31.
[32]	袁英英, 李敏清, 胡伟, 张静, 赵兰凤, 李华兴 . 生物有机肥对番茄青枯病的防效及对土壤微生物的影响. 农业环境科学学报, 2011,30(7):1344-1350.
	YUAN Y Y, LI M Q, HU W, ZHANG J, ZHAO L F, LI H X . Effect of biological organic fertilizer on tomato bacterial wilt and soil microorganism. Journal of Agro-Environment Science, 2011,30(7):1344-1350. (in Chinese)
[33]	蒋岁寒, 刘艳霞, 孟琳, 朱春波, 李想, 沈标, 石俊雄, 杨兴明 . 生物有机肥对烟草青枯病的田间防效及根际土壤微生物的影响. 南京农业大学学报, 2016,39(5):784-790.
	JIANG S H, LIU Y X, MENG L, ZHU C B, LI X, SHEN B, SHI J X, YANG X M . Effects of biological organic fertilizer on field control efficiency of tobacco Ralstonia solanacearum wilt and soil microbial in rhizosphere soil. Journal of Nanjing Agricultural University, 2016,39(5):784-790. (in Chinese)
[34]	刘建国, 卞新民, 李彦斌, 张伟, 李崧 . 长期连作和秸秆还田对棉田土壤微生物活性的影响. 应用生态学报, 2008,19(5):1027-1032.
	LIU J G, BIAN X M, LI Y B, ZHANG W, LI S . Effects of long-term continuous cropping of cotton and returning cotton stalk into field on soil biological activities. Chinese Journal of Applied Ecology, 2008,19(5):1027-1032. (in Chinese)
[35]	ALAM M, DHARNI S, ABDUL-KHALIQ, SRIVASTAVA S K, SAMAD A, GUPTA M K . A promising strain of Streptomyces sp. with agricultural traits for growth promotion and disease management. Indian Journal of Experimental Biology, 2012,50(8):559-568.
[36]	GOUDJAL Y, ZAMOUM M, SABAOU N, MATHIEU F, ZITOUNI A . Potential of endophytic Streptomyces spp. for biocontrol of Fusarium root rot disease and growth promotion of tomato seedlings. Biocontrol Science and Technology, 2016,26(12):1691-1705.
[37]	李社增, 鹿秀云, 马平, 高胜国, 刘杏忠, 刘干 . 防治棉花黄萎病的生防细菌NCD-2的田间效果评价及其鉴定. 植物病理学报, 2005,35(5):451-455.
	LI S Z, LU X Y, MA P, GAO S G, LIU X Z, LIU G . Evaluation of biocontrol potential of a bacterial strain NCD-2 against cotton Verticillium wilt in field trials. Acta Phytopathologica Sinica, 2005,35(5):451-455. (in Chinese)
[38]	王光华, 金剑, 徐美娜, 刘晓冰 . 植物、土壤及土壤管理对土壤微生物群落结构的影响. 生态学杂志, 2006,25(5):550-556.
	WANG G H, JIN J, XU M N, LIU X B . Effects of plant, soil and soil management on soil microbial community diversity. Chinese Journal of Ecology, 2006,25(5):550-556. (in Chinese)
[39]	宋蒙亚, 李忠佩, 吴萌, 刘明, 江春玉 . 不同种植年限设施菜地土壤微生物量和群落结构的差异. 中国农业科学, 2015,48(18):3635-3644.
	SONG M Y, LI Z P, WU M, LIU M, JIANG C Y . Changes in soil microbial biomass and community structure with cultivation chronosequence of greenhouse vegetables. Scientia Agricultura Sinica, 2015,48(18):3635-3644. (in Chinese)
[40]	武爱莲, 丁玉川, 焦晓燕, 王劲松, 董二伟, 郭珺, 王浩 . 玉米秸秆生物炭对褐土微生物功能多样性及细菌群落的影响. 中国生态农业学报, 2016,24(6):736-743.
	WU A L, DING Y C, JIAO X Y, WANG J S, DONG E W, GUO J, WANG H . Effects of corn-stalk biochar on soil microbial functional diversity and bacterial community in cinnamon soils. Chinese Journal of Eco-Agriculture, 2016,24(6):736-743. (in Chinese)
[41]	侯建伟, 邢存芳, 卢志宏, 陈芬, 余高 . 不同秸秆生物炭对贵州黄壤细菌群落的影响. 中国农业科学, 2018,51(23):4485-4495.
	HOU J W, XING C F, LU Z H, CHEN F, YU G . Effects of the different crop straw biochars on soil bacterial community of yellow soil in Guizhou. Scientia Agricultura Sinica, 2018,51(23):4485-4495. (in Chinese)
[42]	SENESI N, PLAZA C, BRUNETTI G, POLO A . A comparative survey of recent results on humic-like fractions in organic amendments and effects on native soil humic substances. Soil Biology and Biochemistry, 2007,39(6):1244-1262.

时期 Stage	处理 Treatment	测序 Reads	丰富度Richness		均匀度Evenness
时期 Stage	处理 Treatment	测序 Reads	Chao1指数 Chao1 index	ACE指数 ACE index	辛普森指数 Simpson index	香浓指数 Shannon index
播种前期 Pre-sowing stage	对照CK	38251.50±293.50a	2814.33±14.34a	2813.33±69.14a	0.9986±0.0002a	10.67±0.13a
播种前期 Pre-sowing stage	西兰花残体BR	39434.67±2787.82a	3339.07±262.21b	3419.18±147.49b	0.9970±0.0007a	10.18±0.10a
苗期 Seedling stage	对照CK	38800.00±206.00a	2703.00±12.25a	2669.00±41.67a	0.9984±0.0001a	10.56±0.08a
苗期 Seedling stage	西兰花残体BR	42364.67±3689.72a	2795.04±64.96b	2691.80±68.21a	0.9984±0.0000a	10.56±0.06a
蕾期 Bud stage	对照CK	42593.50±495.50a	3039.57±46.12a	3143.00±80.87a	0.9985±0.0002a	10.67±0.21a
蕾期 Bud stage	西兰花残体BR	41670.00±2906.67a	3624.21±223.84b	3173.46±99.20a	0.9983±0.0000a	10.16±0.44a
花铃期 Flowering and boll stage	对照CK	36694.00±35.00a	2861.00±36.34a	2861.00±31.38a	0.9987±0.0000a	10.71±0.25a
花铃期 Flowering and boll stage	西兰花残体BR	41284.67±3638.72a	3763.18±167.23b	3946.36±97.67b	0.9982±0.0002a	10.49±0.11a
吐絮期 Boll-opening stage	对照CK	36369.50±75.50a	2543.33±57.97a	2558.00±60.21a	0.9965±0.0006a	10.33±0.33a
吐絮期 Boll-opening stage	西兰花残体BR	34275.33±2063.41a	2665.31±259.75b	2813.93±279.95b	0.9974±0.0001a	10.12±0.34a

属 Genus	时期Stage
	播种前期 Pre-sowing stage		苗期 Seedling stage		蕾期 Bud stage		花铃期 Flowering and boll stage		吐絮期 Boll-opening stage
	CKT0	BRT0	CKT1	BRT1	CKT2	BRT2	CKT3	BRT3	CKT4	BRT4
Haliangium	1.93b	0.96a	2.16b	1.58a	0.75b	0.54a	1.21b	1.07a	1.48b	0.87a
鞘脂单胞菌属Sphingomonas	2.18b	1.57a	2.73a	2.66a	2.13a	2.32b	2.51b	2.33a	1.24b	1.16a
Iamia	1.28a	1.16a	0.40a	0.65b	0.51a	0.90b	0.82a	1.01b	0.63a	1.66b
芽单胞菌属Gemmatimonas	0.98b	0.34a	1.08b	0.88a	1.49b	0.81a	2.27b	1.01a	0.57a	1.12b
硝化螺菌属Nitrospira	0.81a	1.03b	1.34a	1.32a	0.70b	0.51a	1.07a	0.93a	1.03b	0.61a
红色杆菌属Rubrobacter	0.72b	0.55a	1.11b	0.82a	1.20b	0.68a	0.93b	0.75a	0.85a	0.84a
Pontibacter	0.77b	0.22a	1.36b	0.61a	0.96b	0.56a	0.96b	0.47a	0.20a	0.13a
游动放线菌属Actinoplanes	0.40b	0.28a	0.48a	0.55b	0.67a	1.74b	1.81b	0.50a	0.76a	0.76b
Bryobacter	0.55b	0.45a	0.98b	0.73a	0.76b	0.50a	1.20b	0.61a	0.53a	0.58a
气微菌属Aeromicrobium	0.83b	0.48a	1.68b	1.16a	0.67a	0.82b	0.60b	0.47a	0.17a	0.58b
玫瑰弯菌属Roseiflexus	0.29a	0.43b	0.53a	0.65b	0.63b	0.30a	1.13b	0.67a	0.61a	0.87b
Solirubrobacter	0.46b	0.35a	0.60a	0.62a	0.50a	0.54a	1.01b	0.70a	0.54a	0.53a
类诺卡氏属Nocardioides	0.53a	0.69b	0.42a	0.40a	0.56a	0.68b	0.84a	1.03b	0.34a	0.63b
溶杆菌属Lysobacter	0.65a	0.67a	0.98b	0.55a	0.19a	0.50b	0.23a	0.57b	0.20a	0.75b
链霉菌属Streptomyces	0.29a	0.83b	0.23a	0.35b	0.48a	1.16b	0.39a	0.55b	0.27a	0.55b
芽孢杆菌属Bacillus	0.33a	1.29b	0.23a	0.62b	0.40a	0.53b	0.29a	0.61b	0.20a	0.19a
Nonomuraea	0.26a	2.58b	0.01a	0.07b	0.14a	0.30b	0.06a	0.07a	0.07a	0.74b
其他Others	86.75a	86.10a	83.66a	85.77b	87.25b	86.61a	82.67a	86.65b	90.64b	87.43a