Effects of green manure intercropping on soil nutrient content and bacterial community structure in litchi orchards in China

Yuan, Bingchen; Dun, Yu; Hu, An; Wang, Yanru; Sun, Yuting; Li, Chengzhen

doi:10.3389/fenvs.2022.1059800

Cited by 10 publications

(8 citation statements)

References 46 publications

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“…Soil AP and NO 3 − -N showed a positive correlation with Bacillaceae, Streptomycetaceae, Paenibacillaceae, and Geodermatophilaceae, as previously observed by Li et al [62], Zhou et al [68], Ribeiro et al [59], and Panhwar et al [69]. This occurs because these plant-beneficial bacteria exhibit a significant potential in N fixation and phosphates solubilization in the soil [65,70]. However, competition with oat signifi-cantly decreased abundance of these beneficial bacteria, resulting in decreasing nutrient acquisition of E. crus-galli and D. sanguinalis.…”

Section: Effect Of Interspecific Competition On Bacterial Community D...supporting

confidence: 81%

“…Moreover, the beneficial species (i.e., Bacillaceae, Xanthobacteraceae, Streptomycetaceae, Paenibacillaceae, Planococcaceae, Micromonosporaceae) can favor plant growth and improve nutrient availability by stimulating plants to secrete auxin while simultaneously fixing nitrogen, solubilizing phosphate, and decomposing organic matter [59][60][61][62][63][64]. Apart from their ability to stimulate plant growth, Bacillaceae, Streptomycetaceae, and Geodermatophilaceae can prevent plants from soil-borne disease and abiotic stresses (e.g., drought) through the synthesis of substances akin to lipopeptides that make plants more resistant to external stresses [65,66]. These findings imply that neighboring A. sativa can competitively impair plant growth-promoting bacteria of E. crus-galli and D. sanguinalis, resulting in decreased rhizosphere competence on nutrient uptake, growth, and soil-borne pathogen suppression.…”

Section: Effect Of Interspecific Competition On Bacterial Community D...mentioning

confidence: 99%

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Annual Weeds Suppression and Oat Forage Yield Responses to Crop Density Management in an Oat-Cultivated Grassland: A Case Study in Eastern China

Tang,

Li,

Guo

et al. 2024

Agronomy

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Although weeds can be inhibited by high planting densities, canopy shading, elemental balance and soil microbial recruitment are not yet adequately considered when measuring competitive effects on weed control. The effects of oat (Avena sativa) planting density (60 to 600 plants m−2) on the biomass and shoot element balance of oat and weeds were evaluated in a field experiment. The shift in the microbial community of the dominant weed species was examined in a pot experiment by growing the weed alone and in competition with 360 oat plants m−2 (recommended planting density) under greenhouse conditions. Increasing oat planting density beyond 360 plants m−2 did not improve oat forage yield or weed suppression. Compared to 60 plants m−2, the biomass of broadleaf and grass weeds decreased by 1122% and 111%, respectively, at a density of 360 plants m−2, while oat forage biomass increased by 60% and leaf area index by 24%. The improved canopy properties suppressed competing weeds through increased shading. Typically, the C:N and C:P ratios of shoots of Echinochloa crus-galli and Digitaria sanguinalis were higher than those of Portulaca oleracea and Chenopodium album. At high planting densities, E. crus-galli and D. sanguinalis exhibited high P contents and low N:P ratios, suggesting a limited supply of N nutrients for growth. Soil bacterial community assay showed that the composition of microbial communities of the two grass weeds were shaped by the presence of oat competition, which also considerably depleted several important functional microbes associated with nutrient cycling in the weeds’ rhizosphere. These results highlight that increased crop density significantly improves the crop competitive advantage over weeds through increased shading, reduced elemental balance, and beneficial microorganisms of weeds, thereby reducing the need for herbicides or physical weed control in oat cropping system.

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Section: Effect Of Interspecific Competition On Bacterial Community D...supporting

confidence: 81%

Section: Effect Of Interspecific Competition On Bacterial Community D...mentioning

confidence: 99%

Annual Weeds Suppression and Oat Forage Yield Responses to Crop Density Management in an Oat-Cultivated Grassland: A Case Study in Eastern China

Tang,

Li,

Guo

et al. 2024

Agronomy

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“…The community structure and diversity of soil bacteria are important biochemical indicators of soil health, which can be affected by agriculture management ( Li et al, 2022 ; Zhao et al, 2022 ). Intercropping can improve the quantity of orchard soil microorganisms which promote plant growth, enhance plant defenses, and inhibit soil-borne diseases ( Wang et al, 2020 ; Yuan et al, 2023 ). In this study, intercropping marigold improved soil moisture, nutrients and enzyme activities, which may affect rhizosphere organisms, and then influence the structure and diversity of the soil bacterial community ( Cui et al, 2018 ).…”

Section: Discussionmentioning

confidence: 99%

Apple-marigold intercropping improves soil properties by changing soil metabolomics and bacterial community structures

Xue

Chen

et al. 2023

Front. Microbiol.

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Marigold can protect crops against soil-borne diseases. However, the effects of intercropping with marigold on apple rhizosphere soils are not known. In this study, we investigated the metabolite profiles and bacterial community structures in rhizosphere soils of the apple-marigold intercropping system by high-throughput sequencing and soil metabolomics. The results show that intercropping marigold could significantly enhance soil moisture, nitrogen, and enzyme activities compared with clean tillage. The soil metabolite profiles and the soil bacterial community structures in the rhizosphere soils were different between the inter-and mono-cropping systems. Among nine metabolites, carbohydrates were more increased in the intercropping system than in the monocropping system. Pathway enrichment analysis revealed that the greatest differential, in terms of metabolic pathway, was starch and sucrose metabolism. Moreover, intercropping marigold significantly increased the relative abundance of plant growth promoting bacteria in rhizosphere soils, such as Rhizobiales, Pseudomonadales, and Bacillales. These results indicate that marigold intercropping positively affected the apple orchard’s soil quality and may provide a new intercropping technique to improve soil fertility in orchards and promote plant growth.

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“…Soil NH 4 + -N and NO 3 − -N are the principal forms of nitrogen utilized by microorganisms and plants, according to Yuan et al [34]. It was found that modifying the understory vegetation facilitated the accumulation of soil nitrogen pools.…”

Section: Effects Of Understory Vegetation Conversion On Soil C and N ...mentioning

confidence: 99%

Effects of Understory Vegetation Conversion on Soil Greenhouse Gas Emissions and Soil C and N Pools in Chinese Hickory Plantation Forests

Gao,

Shi,

Chen

et al. 2024

Forests

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Forest management, especially understory vegetation conversion, significantly affects soil greenhouse gas (GHG) emissions and soil C and N pools. However, it remains unclear what effect renovating understory vegetation has on GHG emissions and soil C and N pools in plantations. This study investigates the impact of renovating understory vegetation on these factors in Chinese hickory (Carya cathayensis Sarg) plantation forests. Different understory renovation modes were used in a 12-month field experiment: a safflower camellia (SC) (Camellia chekiangoleosa Hu) planting density of 600 plants ha−1 and wild rape (WR) (Brassica napus L.) strip sowing (UM1); SC 600 plants ha−1 and WR scatter sowing (UM2); SC 1200 plants ha−1 and WR strip sowing (UM3); SC 1200 plants ha−1 and WR scatter sowing (UM4); and removal of the understory vegetation layer (CK). The results showed that understory vegetation modification significantly increased soil CO2 and emission fluxes and decreased soil CH4 uptake fluxes (p < 0.01). The understory vegetation transformation significantly improved soil labile carbon and labile nitrogen pools (p < 0.01). This study proposes that understory vegetation conversion can bolster soil carbon sinks, preserve soil fertility, and advance sustainable development of Chinese hickory plantation forests.

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Effects of green manure intercropping on soil nutrient content and bacterial community structure in litchi orchards in China

Cited by 10 publications

References 46 publications

Annual Weeds Suppression and Oat Forage Yield Responses to Crop Density Management in an Oat-Cultivated Grassland: A Case Study in Eastern China

Annual Weeds Suppression and Oat Forage Yield Responses to Crop Density Management in an Oat-Cultivated Grassland: A Case Study in Eastern China

Apple-marigold intercropping improves soil properties by changing soil metabolomics and bacterial community structures

Effects of Understory Vegetation Conversion on Soil Greenhouse Gas Emissions and Soil C and N Pools in Chinese Hickory Plantation Forests

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