Root and hyphal interactions influence N transfer by arbuscular mycorrhizal fungi in soybean/maize intercropping systems

IF 1.9 3区环境科学与生态学 Q3 ECOLOGY

Fungal Ecology Pub Date : 2023-08-01 DOI:10.1016/j.funeco.2023.101240

Tantan Zhang , Lingling Yu , Yuting Shao , Jianwu Wang

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引用次数: 0

Abstract

In maize-soybean intercropping systems, the transfer of N from soybean to maize gives the intercropping system the advantage of improved N utilization and higher yields. Mycorrhiza acts as an important pathway for N transfer, providing a constant supply of N to sustain the growth and development of maize in its early stages. However, it is not clear how arbuscular mycorrhizal fungi (AMF) drive the transfer of N from soybean to maize in the intercropping system. Therefore, we quantified the amount of N transferred from soybean to maize under low and high N levels in the intercropping system, and the abundance and diversity of AMF involved in N transfer (¹⁵N-AMF) under different conditions by ¹⁵N leaf marker and DNA-SIP technology. We found that the interaction between roots and reducing the application of N fertilizer increased the amount of N transfer from soybean to maize. Compared with plastic plate separation (PS), no separation (NS) and mesh separation (MS) significantly increased the N fixation rate (from 14.33% to 39.09%), and the amount of N transfer under NS was 1.95–3.48 times that under MS. N transfer from soybean to maize ranged from 9.7 to 43.42 mg per pot in the no N treatment, while the addition of N fertilizer reduced N transfer by 14.12–66.28%. This is due to root interaction and reduced N fertilization increased the abundance and diversity of the ¹⁵N-AMF community, thereby promoting AMF colonization of maize and soybean roots. AMF colonization in soybean and maize roots under NS treatment was 6.47–17.24% higher than under MS treatment in all three levels of N addition. The increase of mycorrhiza in root system increased the N transfer from soybean to maize significantly. These results suggest that reduced N fertilizer in maize-soybean intercropping systems can increase N transfer by the mycorrhizal pathway, meeting maize N requirements and reducing chemical N fertilizer, which is important for sustainable agricultural development.

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根与菌丝互作对大豆/玉米间作丛枝菌根真菌氮转运的影响

在玉米-大豆间作系统中，氮从大豆向玉米的转移使间作系统具有提高氮利用率和提高产量的优势。菌根是氮转移的重要途径，为玉米早期的生长发育提供持续的氮供应。然而，目前尚不清楚丛枝菌根真菌（AMF）如何在间作系统中驱动氮从大豆向玉米的转移。因此，我们利用15N叶片标记和DNA-SIP技术定量了间作系统中低氮和高氮水平下大豆向玉米转移的氮量，以及不同条件下参与氮转移的AMF（15N-AMF）的丰度和多样性。我们发现，根系与减少氮肥施用之间的相互作用增加了氮从大豆向玉米的转移量。与塑料板分离（PS）相比，无分离（NS）和网孔分离（MS）显著提高了固氮率（从14.33%提高到39.09%），NS下的氮转移量是MS下的1.95–3.48倍，而氮肥的添加使氮转移减少了14.12–66.28%。这是由于根系相互作用和氮肥的减少增加了15N-AMF群落的丰度和多样性，从而促进了AMF在玉米和大豆根系的定殖。在所有三个氮添加水平下，NS处理下大豆和玉米根中AMF的定殖比MS处理高6.47–17.24%。根系菌根的增加显著增加了氮从大豆向玉米的转移。这些结果表明，玉米-大豆间作系统中减少氮肥可以通过菌根途径增加氮的转移，满足玉米对氮的需求，减少化学氮肥，这对农业可持续发展具有重要意义。

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来源期刊

Fungal Ecology 环境科学-生态学

CiteScore

5.80

自引率

3.40%

发文量

审稿时长

3 months

期刊介绍： Fungal Ecology publishes investigations into all aspects of fungal ecology, including the following (not exclusive): population dynamics; adaptation; evolution; role in ecosystem functioning, nutrient cycling, decomposition, carbon allocation; ecophysiology; intra- and inter-specific mycelial interactions, fungus-plant (pathogens, mycorrhizas, lichens, endophytes), fungus-invertebrate and fungus-microbe interaction; genomics and (evolutionary) genetics; conservation and biodiversity; remote sensing; bioremediation and biodegradation; quantitative and computational aspects - modelling, indicators, complexity, informatics. The usual prerequisites for publication will be originality, clarity, and significance as relevant to a better understanding of the ecology of fungi.