工程化土壤改良结合生物肥对再植苹果根际土壤微生物群落的影响

doi:10.3969/j.issn.1674-7968.2023.06.014

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摘要苹果(Malus domestica)连作障碍是苹果产业面临的一大难题,连作苹果幼苗成活率低,严重制约苹果产量和品质。为探究工程化土壤改良结合生物肥对再植苹果根际微生物群落的影响及其对苹果再植疾病的防治机理,本研究采集山东省栖霞市官道镇(种植20年)壤土果园中健康的苹果根际土壤以及工程化土壤改良1年和2年后的苹果根际土壤样本 ,通过 16S rRNA 和基因间隔序列(intergenic transcribed spacer, ITS)基因的高通量测序及数据分析,从微生物群落组成及网络稳定性角度探究工程化土壤改良措施对苹果连作障碍土壤的改良修复效果。结果发现,工程化土壤改良后苹果根际细菌 α 多样性显著增加且群落结构发生改变 ,门水平上变形菌门(Proteobacteria)和放线菌门(Actinobacteria)的相对丰度显著增加 ,Acidobacteria 的丰度显著降低 ;属水平上假单胞菌属(Pseudomonas)和马赛菌属(Massilia)的丰度持续增加,节杆菌属(Arthrobacter)、链霉菌属(Streptomyces)、不动杆菌属(Acinetobacter)、Sphingobium 及 Williamsia 显著富集。土壤改良后真菌的 α 多样性无显著变化但群落结构发生显著变化 ,门水平上子囊菌门 (Ascomycota)、担子菌门(Basidiomycota)及被孢霉门(Mortierellomycota)的相对丰度增加,属水平上镰刀菌属 (Fusarium)、青霉菌属 (Penicillium) 及枝孢菌属 (Cladosporium) 的丰度降低 ,被孢霉属 (Mortierella) 和 Paraphaeosphaeria 显著富集。细菌的共现性网络(co-occurrence network)比真菌的更加紧密,复杂度更高, 同时土壤改良后真菌网络的鲁棒性极显著降低(P<0.001),表明该土壤改良技术主要通过强化根际细菌网络结构,破坏真菌的群落结构,促使苹果连作土壤中根际微生物向“细菌型”转变,改善苹果连作土壤环境。本研究为苹果连作障碍的防治提供依据,促进苹果产业的可持续发展。

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	姜婷婷
	任忠秀
	刘亮
	于家伊
	袁红莉

关键词 ：苹果, 连作障碍, 工程化土壤改良, 微生物群落结构, 共现性网络

Abstract：Apple (Malus domestica) continuous cropping obstacle hinders the development of apple industry significantly, which inhibits the survival rate of apple seedlings, and lowers the yield and quality of apple seriously. In order to explore the effect of engineering soil improvement combined with biological fertilizer technology improvement on rhizosphere microbial community of replanted apple and the controlling and the apple rhizosphere soil samples after 1 and 2 years of engineered soil improvement from loam orchards were collected in Guandao Town, Qixia, Shandong Province. The effects of engineering soil modification on apple continuous cropping obstacle soil were investigated from the perspectives of microbial community composition and network stability by high-throughput sequencing of 16S rRNA and intergenic transcribed spacer (ITS) genes. The results showed that the α diversity of bacteria community was increased and community structure was changed significantly after soil improvement. At phylum level, the relative abundance of Proteobacteria and Actinobacteria were increased, while the abundance of Acidobacteria was decreased. At genus level, the abundance of Pseudomonas and Massilia were increased continuously. Arthrobacter, Streptomyces, Acinetobacter, Sphingobium and Williamsia were enriched significantly during the process of soil improvement. The α diversity of fungi was not affected obviously, however, the community structure of fungi was changed. At phylum level, the relative abundance of Ascomycota, Basidiomycota and Mortierellomycota were increased. At genus level, the abundance of Fusarium, Penicillium and Cladosporium were decreased, while Mortierella and Paraphaeosphaeria were enriched significantly. Meanwhile, the co-

Key words： Apple Continuous cropping obstacle Engineering soil improvement Microbial community structure Co-occurrence network

收稿日期: 2022-08-22

通讯作者: *leonayu2000@126.com;hlyuan@cau.edu.cn

引用本文:

姜婷婷, 任忠秀,刘亮, 于家伊, 袁红莉. 工程化土壤改良结合生物肥对再植苹果根际土壤微生物群落的影响[J]. 农业生物技术学报, 2023, 31(6): 1262-1274.
JIANG Ting-Ting, REN Zhong-Xiu, LIU Liang, YU Jia-Yi, YUAN Hong-Li. Effects of Engineered Soil Improvement Combined with Biofertilizer on Rhizosphere Soil Microbial Community in Replanted Apple (Malus domestica). 农业生物技术学报, 2023, 31(6): 1262-1274.

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http://journal05.magtech.org.cn/Jwk_ny/CN/10.3969/j.issn.1674-7968.2023.06.014 或 http://journal05.magtech.org.cn/Jwk_ny/CN/Y2023/V31/I6/1262

[1] 白变霞. 2020. 潞党参连作障碍防治细菌的筛选及其作用机制[D]. 博士学位论文, 山西农业大学, 导师: 郝林, pp. 31-33.
(Bai B X. 2020. Screening and the mechanism of biocontrol bacteria in Codonopsis pillosula continuous cultivation obstacle[D]. Thesis for Ph. D. , Shanxi Agricultural University, Supervisor: Hao L, pp. 31-33. )
[2] 付风云, 相立, 徐少卓, 等. 2016. 多菌灵与微生物有机肥复合对连作平邑甜茶幼苗及土壤的影响[J]. 园艺学报, 43(08): 1452-1462.
(Fu F Y, Xiang L, Xu S Z, et al. 2016. Effects of carbendazim and bio-organic fertilizer on Malus hupehensis seedlings and soil under replant condition[J]. Acta Horticulturae Sinica, 43(08): 1452-1462. )
[3] 刘超, 相立, 王森, 等. 2016. 土壤熏蒸剂棉隆加海藻菌肥对苹果连作土微生物及平邑甜茶生长的影响[J]. 园艺学报 , 43(10): 1995-2002.
(Liu C, Xiang L, Wang S, et al. 2016. Effects of dazomet fumigation and seaweed biologic fertilizer on the Malus hupehensis seedlings and soil microbial quantity under replant conditions[J]. Acta Horticulturae Sinica. 43(10): 1995-2002. )
[4] 刘丽英, 许超, 刘珂欣, 等. 2019. 两株植物内生拮抗菌对连作土盆栽平邑甜茶幼苗生长及土壤酶活性的影响[J]. ria on growth of pot experiment Malus hupehensis seedlings and the soil enzymes activity under continuous cropping conditions[J]. Acta Horticulturae Sinica, 46(07): 1238-1248. )
[5] 刘涛, 朱迪, 吕婷, 等. 2021. 青海湖区芨芨草草原土壤养分对翻耕和补播措施的响应[J]. 植物研究, 41(02): 270-280.
(Liu T, Zhu D, Lu T, et al. 2021. Respond of soil nutrient to plowing and reseeding of Achnatherum splen- dens in the Qinghai Lake region[J]. Bulletin of Botanical Research, 41(02): 270-280. )
[6] 孙杨, 王璐, 赵璐, 等. 2022. 复合微生物菌肥对苹果再植病害调控及对根围土壤真菌群落结构的影响[J]. 植物病理学报 , 52(02): 256-268.
(Sun Y, Wang L, Zhao L, et al. 2022. Effects of compound microbial fertilizer on apple replanted diseases and fungal community structure in rhizosphere soil[J]. Acta Phytopathologica Sinica, 52(02): 256-268. )
[7] 王丹丹, 殷志秋, 孙丽, 等. 2021. 缓解花生连作障碍的根际促生菌分离及功能鉴定[J]. 微生物学报, 61(12): 4086-4096.
(Wang D D, Yin Z Q, Sun L, et al. 2021. Isolation and identification of peanut plant-growth promoting rhizobacteria with the potential to alleviate continuous cropping obstacle[J]. Acta Microbiologica Sinica, 61(12): 4086-4096. )
[8] 王功帅. 2018. 环渤海连作土壤真菌群落结构分析及混作葱减轻苹果连作障碍的研究[D]. 博士学位论文, 山东农业大学 , 导师 : 毛志泉 , pp. 44-49.
(Wang G S. 2018. Studies on fungal community in replanted soil around Bohai Gulf and alleviation apple replanted disease by mixed cropping with Allium fistulosum L. [D]. Thesis for Ph. D. , Shandong Agricultural University, Supervisor: Mao Z Q, pp. 44-49. )
[9] 王晓琪, 姜伟涛, 姚媛媛, 等. 2020. 苹果连作障碍土壤微生物的研究进展[J]. 园艺学报 , 47(11): 2223-2237.
(Wang X Q, Jiang W T, Yao Y Y, et al. 2020. Research advance of apple replant disease based on soil microorganism[J]. Acta Horticulturae Sinica, 47(11): 2223-2237. )
[10] 相立. 2021. 老果园连作障碍关键因子及砧木响应其侵染机制的研究[D]. 博士学位论文, 山东农业大学, 导师: 毛志泉 , pp. 1-4.
(Xiang L. 2021. Apple replant disease key factor in old orchards and mechanism of rootstock response to its infection[D]. Thesis for Ph. D. , Shandong Agricultural University, Supervisor: Mao Z Q, pp. 1-4. )
[11] 徐文凤. 2011. 环渤海湾地区重茬苹果园土壤真菌群落多样analysis if soil fungi from Bohai bay apple replanted orchard and the screening of the antagonistic fungi[D]. Thesis for M. S. , Shandong Agricultural University, Supervisor: Yu J F, pp. 42-49. )
[12] 张艳杰, 杨淑, 陈英化, 等. 2014. 玫瑰黄链霉菌防治番茄连作障碍及对土壤微生物区系的影响[J]. 西北农业学报 , 23(08): 122-127.
(Zhang Y J, Yang S, Chen Y H, et al. 2014. Efficiency of Streptomyces roseoflavus against tomato continuous cropping obstacle and effects to soil microflora[J]. Acta Agriculturae Boreali-occidentalis Sinica, 23(08): 122-127. )
[13] 赵国玲, 姜兴印, 孙燕, 等. 2013. 三种杀菌剂对平邑甜茶生理指标的影响[J]. 果树学报, 30(05): 823-828.
(Zhao G L, Jiang X Y, Sun Y, et al. 2013. Effects of three fungicides on physiological characteristics of the growth of Malus hupehensis seedlings[J]. Journal of Fruit Science. 30(05): 823-828. )
[14] Balbin-Suarez A, Jacquiod S, Rohr A D, et al. 2021. Root exposure to apple replant disease soil triggers local defense response and rhizoplane microbiome dysbiosis[J]. FEMS Microbiology Ecology, 97(4): 1-14.
[15] Duan Y A, Zhou Y F, Li Z, et al. 2022. Effects of Bacillus amyloliquefaciens QSB-6 on the growth of replanted apple trees and the soil microbial environment[J]. Horticul turae, 8(1): 83.
[16] Edwards J, Johnson C, Santos-Medellin C, et al. 2015. Structure, variation, and assembly of the root-associated microbiomes of rice[J]. Proceedings of the National Academy of Sciences of the USA, 112(8): E911-920.
[17] Fan K K, Weisenhorn P, Gilbert Jack A, et al. 2018. Wheat rhizosphere harbors a less complex and more stable microbial co-occurrence pattern than bulk soil[J]. Soil Biology and Biochemistry, 125: 251-260.
[18] He H, Zhang S Y, Shen W Q, et al. 2021. Benzoic acid plays a part in rhizosphere microbial composition of peach seedlings grown in replanted soil[J]. Rhizosphere, 19:100364.
[19] Hu Y, Li Y, Yang X, et al. 2021. Effects of integrated biocontrol on bacterial wilt and rhizosphere bacterial community of tobacco[J]. Scientific Reports, 11(1): 2653.
[20] Jiang J, Song Z, Yang X, et al. 2017. Microbial community analysis of apple rhizosphere around Bohai Gulf[J]. Scientific Reports, 7(1): 8918.
[21] Kanfra X, Wrede A, Moll J, et al. 2022. Nematode-microbe complexes in soils replanted with apple[J]. Microorganisms, 10(1): 157.
[22] Li X G, Ding C F, Zhang T L, et al. 2014. Fungal pathogen accumulation at the expense of plant-beneficial fungi as a consequence of consecutive peanut monoculturing[J]. Soil Biology and Biochemistry, 72: 11-18.
[23] Ling N, Wang T, Kuzyakov Y. 2022. Rhizosphere bacteriome structure and functions[J]. Nature Communications, 13(1): 836.
[24] Liu Q, Wang S, Li K, et al. 2021. Responses of soil bacterial and fungal communities to the long-term monoculture of grapevine[J]. Applied Microbiology and Biotechnology, 105(18): 7035-7050.
[25] Radl V, Winkler J B, Kublik S, et al. 2019. Reduced microbial potential for the degradation of phenolic compounds in the rhizosphere of apple plantlets grown in soils affected by replant disease[J]. Environmental Microbiome, 14(1): 8.
[26] Shen Y, Nie J, Li Z, et al. 2018. Differentiated surface fungal communities at point of harvest on apple fruits from rural and peri-urban orchards[J]. Scientific Reports, 8(1):2165.
[27] Sheng Y F, Wang H Y, Wang M, et al. 2020. Effects of soil texture on the growth of young apple trees and soil microbial community structure under replanted conditions[J]. Horticultural Plant Journal, 6(3): 123-131.
[28] Tian G L, Bi Y M, Jiao X L, et al. 2021. Application of vermicompost and biochar suppresses Fusarium root rot of replanted American ginseng[J]. Applied Microbiology and Biotechnology, 105(18): 6977-6991.
[29] Van der Heijden M G, Hartmann M. 2016. Networking in the plant microbiome[J]. PLoS Biology, 14(2): e1002378.
[30] Wanees A E, Zaslow S J, Potter S J, et al. 2018. Draft genome sequence of the plant growth-promoting Sphingobium sp. strain AEW4, isolated from the rhizosphere of the beachgrass Ammophila breviligulata[J]. Genome Announcements, 6(21): e00410-00418.
[31] Wang H, Lou J, Gu H, et al. 2016. Efficient biodegradation of phenanthrene by a novel strain Massilia sp. WF1 isolated from a PAH-contaminated soil[J]. Environmental Science Pollution Research, 23(13): 13378-13388.
[32] Xiang L, Wang M, Jiang W, et al. 2021a. Key indicators for renewal and reconstruction of perennial trees soil: Microorganisms and phloridzin[J]. Ecotoxicology and Environmental Safety, 225: 112723.
[33] Xiang L, Zhao L, Wang M, et al. 2021b. Physiological responses of apple rootstock M. 9 to infection by Fusarium solani[J]. Hort Science, 56(9): 1104-1111.
[34] Yuan M M, Guo X, Wu L W, et al. 2021. Climate warming enhances microbial network complexity and stability[J]. Nature Climate Change, 11(4): 343-348.