Forms of nitrogen inputs regulate the intensity of soil acidification

Wang, Ze; Tao, Tingting; Wang, Hu; Chen, Ji; Small, Gaston E.; Johnson, David; Chen, Jihui; Zhang, Yingjun; Zhu, Qichao; Zhang, Shengmin; Song, Yufeng; Kattge, Jens; Guo, Peng; Sun, Xiao

doi:10.1111/gcb.16746

Cited by 18 publications

(3 citation statements)

References 62 publications

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“…For instance, soil nutrients like NH 4 + and NO 3 − (the main forms of nitrogen in the rhizosphere) can impact pH and therefore iron availability. Long-term application of NH 4 + decreases rhizosphere pH, while NO 3 − increases rhizosphere pH 37 , 38 . However, in our intercropping system, the pH remained stable across nutrient stages (Supplementary Fig.…”

Section: Discussionmentioning

confidence: 98%

Microbiome convergence enables siderophore-secreting-rhizobacteria to improve iron nutrition and yield of peanut intercropped with maize

Wang,

Chen

et al. 2024

Nat Commun

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Intercropping has the potential to improve plant nutrition as well as crop yield. However, the exact mechanism promoting improved nutrient acquisition and the role the rhizosphere microbiome may play in this process remains poorly understood. Here, we use a peanut/maize intercropping system to investigate the role of root-associated microbiota in iron nutrition in these crops, combining microbiome profiling, strain and substance isolation and functional validation. We find that intercropping increases iron nutrition in peanut but not in maize plants and that the microbiota composition changes and converges between the two plants tested in intercropping experiments. We identify a Pseudomonas secreted siderophore, pyoverdine, that improves iron nutrition in glasshouse and field experiments. Our results suggest that the presence of siderophore-secreting Pseudomonas in peanut and maize intercropped plays an important role in iron nutrition. These findings could be used to envision future intercropping practices aiming to improve plant nutrition.

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Section: Discussionmentioning

confidence: 98%

Microbiome convergence enables siderophore-secreting-rhizobacteria to improve iron nutrition and yield of peanut intercropped with maize

Wang,

Chen

et al. 2024

Nat Commun

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“…Many studies have analyzed the influence of straw incorporation on crop yields and considered that sustainable crop production is supported by the balance of mineralizationrelated carbon loss in agricultural soil and improves a range of biological and physicochemical soil properties [22]. In addition, soil acidification is induced by reactive nitrogen inputs, and different nitrogen transformation processes contribute to different levels of acidification [23]. Our study found that the straw addition treatments reduced the content of available phosphorus and available potassium in soil, but the content of soil organic matter was less variable.…”

Section: Effects Of Straw Addition On Soil Chemical Propertiesmentioning

confidence: 99%

Application of Rice Straw Inhibits Clubroot Disease by Regulating the Microbial Community in Soil

Han,

Zhang,

et al. 2024

Microorganisms

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Straw return is an effective agricultural management practice for alleviating soil sickness, but only a few studies have focused on the incorporation of straw with deep plowing and rotary tillage practices in vegetable production. To determine the effects of rice straw return on Chinese cabbage clubroot, a field experiment for three consecutive years in the same area was performed. Soil microbial high-throughput sequencing, quantitative real-time polymerase chain reaction (PCR) and other methods were used to detect Chinese cabbage plant growth, clubroot occurrence, soil chemical properties and soil microbial diversity and abundance. The results showed that straw addition could significantly reduce the clubroot disease incidence. Through Illumina Miseq sequencing, the diversity of the fungi decreased obviously. The relative abundance of the phyla Proteobacteria and Firmicutes was strikingly reduced, while that of Chloroflexi was significantly increased. Redundancy analysis suggests that soil properties may also affect the soil microbial composition; changes in the microbial structure of bacteria and fungi were associated with the available phosphorus. In conclusion, the continuous addition of rice straw can promote the growth and control the occurrence of clubroot, which is closely related to the microbial composition, and the inhibition effect is proportional to the age of addition.

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“…Studies have shown that global N inputs are projected to increase by almost 57.0% between 1995 and 2050 (Galloway et al, 2008;Jian et al, 2016). However, excessive and continuous application of N fertilizers has led to various negative consequences, including biodiversity losses (Kimmel et al, 2020;Yang et al, 2022), deterioration of soil properties (Guo et al, 2022;Wang et al, 2023) and environmental degradation (Jiang et al, 2022). China is particularly vulnerable to these issues, because it is the world's largest consumer of N fertilizer, accounting for 25.1% of the world's total N fertilizer consumption in 2020 (FAOSTAT, 2023).…”

Section: Introductionmentioning

confidence: 99%

Linking microbial carbon‐degrading potential to organic carbon sequestration in fertilized soils: Insights from metagenomics

Ma,

Niu,

et al. 2023

Land Degrad Dev

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The capacity of soils to store organic carbon (SOC) is vital for agricultural productivity. Soil microorganisms exert a critical role in carbon (C) flow and potentially influence C balance through the decomposition of plant and microbial dead biomass. However, the connection between the microbial degradation potential of plant‐derived and microbial‐derived C and soil organic carbon sequestration (SOCSR) under organic and inorganic nitrogen (N) fertilization treatments remains largely unexplored using metagenomics. In this study, metagenomics was used to investigate the effects of 4 years inorganic (N1: 250 kg N ha−1 yr−1 and N3: 450 kg N ha−1 yr−1) and organic N (O1: N1 + 11,250 kg ha−1 yr−1 sheep manure and O3: N1 + 18,750 kg ha−1 yr−1 sheep manure) fertilizer application on plant biomass decomposition genes, microbial biomass decomposition genes, and microbial properties related to different sources of C decomposition (species composition and diversity). Furthermore, the study explored the relationship between organic matter decomposition genes, microorganisms, and SOCSR. The results revealed that compared with N1 treatment, the increased application of inorganic N fertilizer (N3) significantly enhanced the abundance of genes related to plant and microbial biomass decomposition and microbial diversity involved in SOC decomposition, resulting in reduced SOC content. Conversely, the increased application of organic N fertilizer (O1 and O3) had a minor effect on the abundance of genes related to different sources of C decomposition and C decomposing microbial diversity, but reduced microbial entropy (the ratio of microbial biomass carbon to SOC) and increased SOC content. The random forest model highlighted that plant biomass decomposition genes and bacterial community composition were important factors affecting SOCSR. The Mantel test also indicated that the genes involved in the decomposition of lignin, cellulose, and hemicellulose were closely related to SOCSR. These findings highlighted that increased inorganic N fertilizers greatly enhanced the microbial capacity for SOC decomposition, resulting in reduced SOC accumulation. While the increased application of organic N fertilizer increased SOC stability and reduced the mineralization potential of SOC, contributing to SOCSR. Overall, these findings provide a greater understanding of the relationship between soil C turnover and microbial C‐degrading potential under short‐term fertilization. And in a long time, they may have important implications for global strategies aimed at increasing SOCSR to restore fertility and facilitate sustainable agricultural development.

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Forms of nitrogen inputs regulate the intensity of soil acidification

Cited by 18 publications

References 62 publications

Microbiome convergence enables siderophore-secreting-rhizobacteria to improve iron nutrition and yield of peanut intercropped with maize

Microbiome convergence enables siderophore-secreting-rhizobacteria to improve iron nutrition and yield of peanut intercropped with maize

Application of Rice Straw Inhibits Clubroot Disease by Regulating the Microbial Community in Soil

Linking microbial carbon‐degrading potential to organic carbon sequestration in fertilized soils: Insights from metagenomics

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