李燕培, 林佳琦, 肖世祥, 冯斗, 邓英毅, 禤维言. 蕉园间作红薯对土壤微生物功能多样性的影响[J]. 中国生态农业学报(中英文), 2022, 30(6): 990−1001. DOI: 10.12357/cjea.20210665
引用本文: 李燕培, 林佳琦, 肖世祥, 冯斗, 邓英毅, 禤维言. 蕉园间作红薯对土壤微生物功能多样性的影响[J]. 中国生态农业学报(中英文), 2022, 30(6): 990−1001. DOI: 10.12357/cjea.20210665
LI Y P, LIN J Q, XIAO S X, FENG D, DENG Y Y, XUAN W Y. Effects of intercropping sweet potato in banana plantation on functional diversity of soil microorganisms[J]. Chinese Journal of Eco-Agriculture, 2022, 30(6): 990−1001. DOI: 10.12357/cjea.20210665
Citation: LI Y P, LIN J Q, XIAO S X, FENG D, DENG Y Y, XUAN W Y. Effects of intercropping sweet potato in banana plantation on functional diversity of soil microorganisms[J]. Chinese Journal of Eco-Agriculture, 2022, 30(6): 990−1001. DOI: 10.12357/cjea.20210665

蕉园间作红薯对土壤微生物功能多样性的影响

Effects of intercropping sweet potato in banana plantation on functional diversity of soil microorganisms

  • 摘要: 为探究香蕉与红薯间作模式下土壤微生物群落功能多样性的变化特征, 以及土壤微生物对土壤养分转化和碳源利用特征, 本研究以‘桂蕉1号’为材料, 采用Biolog方法和主成分分析对香蕉单作与香蕉和红薯间作下土壤微生物功能多样性的变化进行了比较分析。结果表明, 在营养生长期至抽蕾结实期, 蕉园间作红薯具有极显著提高土壤微生物代谢活性的作用(P<0.01), 与单作相比, 间作土壤微生物群落的吸光值平均颜色变化率(AWCD)提高0.77~14.36倍, 土壤微生物群落多样性、优势度和丰富度分别提高0.09~1.01倍、0.02~0.31倍和0.52~5.04倍, 但间作和单作蕉园土壤微生物群落均匀度差异不显著。此外, 蕉园间作红薯增加了土壤微生物利用碳源种类和代谢活性, 间作土壤微生物对碳水化合物类、氨基酸类、羧酸类、多聚类、酚酸类和胺类的代谢活性比单作提高13.81倍、9.22倍、5.38倍、9.93倍、6.08倍和3.46倍; 蕉园间作红薯和香蕉单作土壤微生物对不同碳源的利用效率有较大的差异, 间作土壤微生物以碳水化合物类和氨基酸类为主要代谢碳源, 利用率为20.29%~25.25%和18.58%~20.31%, 单作则以多聚类化合物和酚酸类为主要代谢碳源, 利用率为0.60%~52.71%和13.94%~26.56%; 间作土壤微生物群落利用的碳源化合物数量比单作增加9~28种, 且间作和单作的差异达到极显著(P<0.01)或显著水平(P<0.05), 间作的土壤微生物主要利用的碳源为D-甘露醇和N-乙酰-D-葡萄糖胺等, 单作主要利用吐温80和L-精氨酸等。主成分分析表明, 碳水化合物类和氨基酸类是促使蕉园间作红薯土壤微生物多样性发生改变的主要碳源。在蕉园间作红薯具有提高土壤微生物群落多样性和增加土壤微生物群落碳源利用种类与活性的作用, 起到明显改善土壤微生物群落功能多样性的效应。

     

    Abstract: Reasonable intercropping patterns of crops have positive regulatory effects on the metabolic functional diversity of soil microbial communities. To explore the functional diversity of the soil microbial community and the characteristics of soil microbial transformation in soil nutrients and carbon source utilization in intercropping of banana and sweet potato, the changes in soil microbial functional diversity under banana monoculture and banana-sweet potato intercropping in ‘Guijiao No. 1’ banana plantation were compared and analyzed by using the Biolog method and principal component analysis. The results showed that the soil microbial metabolic activity from the vegetative growth stage to the budding stage of banana could be significantly improved by intercropping sweet potato in a banana plantation (P<0.01). The average color change rate of the intercropping soil microbial community was increased by 0.77–14.36 times, and the diversity, dominance, and richness of the soil microbial community increased by 0.09–1.01, 0.02–0.31, and 0.52–5.04 times, respectively, compared with those of the single cropping. However, there was no significant difference in soil microbial community evenness between intercropping and monoculture in the banana orchards. In addition, the carbon source utilization and metabolic activity of soil microorganisms increased in banana plantations intercropped with sweet potato. The metabolic activities of soil microorganisms for carbohydrates, amino acids, carboxylic acids, polymers, phenolic acids, and amines in intercropping were 13.81, 9.22, 5.38, 9.93, 6.08, and 3.46 times higher than those in the monoculture, respectively. There were differences in the utilization efficiency of different carbon sources between monoculture and intercropping systems. Carbohydrates and amino acids were the main metabolic carbon sources for soil microorganisms in intercropping, and polymer compounds and phenolic acids were the main metabolic carbon sources in the monoculture. The number of carbon sources utilized by soil microbial communities in intercropping was increased by 9–28 times compared with that of the monoculture, and the difference between intercropping and monoculture reached a very significant or significant level (P<0.01 or P<0.05, respectively). For banana intercropping with sweet potato, the utilization rate of carbohydrates by soil microorganisms was the highest, reaching 20.29%–25.25%, followed by amino acids with a utilization rate of 18.58%–20.31%, whereas the utilization rate of carboxylic acids, multi-cluster compounds, phenolic acids, and amines was lower than 18.28%. For banana monoculture, the utilization rate of multi-cluster compounds by soil microorganisms was the highest, reaching 0.60%–52.71%, followed by phenolic acids with the utilization rate of 13.94%–26.56%, whereas the utilization rate of the other four carbon sources was lower than 17.82%. There were notable differences in the utilization efficiency of single carbon sources by soil microorganisms between banana intercropping with sweet potato and banana monoculture. The main carbon sources used by intercropping soil microorganisms were d-cellobiose, N-acetyl-d-glucosamine, d-mannitol, α-d-lactose, d-galacturonic acid, d-xylose, l-arginine, and l-asparagine, accounting for 24.53%–31.12% of the total carbon sources. The carbon sources utilized by monoculture microorganisms included Tween-80, L-arginine, N-acetyl-d-glucosamine, L-asparagine, γ-hydroxybutyric acid, and α-d-lactose, accounting for 32.02%–78.45% of the total carbon source. Principal component analysis showed that carbohydrates and amino acids were the main carbon sources that changed the soil microbial diversity of banana intercropping with sweet potato. The diversity of rhizosphere soil microbial communities in banana plantations could be improved, and the carbon sources utilization efficiency and activity of the soil microbial community were improved by intercropping sweet potato; thus, the functional diversity of the rhizosphere microbial community was significantly improved.

     

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