通过微生物潜力提高植物的锰可利用性:改善土壤健康和粮食安全的可持续途径

B. Khoshru, Debasis Mitra, A. F. Nosratabad, A. Reyhanitabar, Labani Mandal, Beatrice Farda, R. Djebaili, M. Pellegrini, B. Guerra-Sierra, A. Senapati, P. Panneerselvam, P. K. D. Mohapatra
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摘要

锰(Mn)对植物生长至关重要,因为它是参与光合作用、抗氧化剂合成和防御病原体的酶的辅助因子。它还在养分吸收、根系生长和土壤微生物群落中发挥作用。然而,由于土壤pH值、氧化还原电位、有机质含量和矿物学等因素,土壤中Mn的有效性可能受到限制。过量使用含锰化肥会对土壤和环境健康造成负面影响,例如土壤和水污染。最近的研究强调了微生物相互作用在促进植物吸收锰方面的重要性,为解决锰缺乏提供了一种更环保的方法。微生物采用各种策略,包括pH降低、有机酸生产和促进根生长,以提高锰的生物利用度。它们还产生铁载体、抗致病性化合物,并与植物形成共生关系,从而促进锰的吸收、运输和刺激植物生长,同时最大限度地减少对环境的负面影响。本文综述了影响土壤和植物中Mn流动性的因素,重点介绍了土壤中Mn缺乏和化肥使用造成的问题及其后果。此外,它还研究了不同土壤微生物在使用环保方法解决这些挑战方面的潜力。这一综述表明,微生物相互作用可能是一种有前途的策略,可以改善植物对锰的吸收,从而提高农业生产力和环境可持续性。然而,需要进一步的研究来充分了解这些相互作用的机制并优化它们在农业实践中的利用。
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Enhancing Manganese Availability for Plants through Microbial Potential: A Sustainable Approach for Improving Soil Health and Food Security
Manganese (Mn) is essential for plant growth, as it serves as a cofactor for enzymes involved in photosynthesis, antioxidant synthesis, and defense against pathogens. It also plays a role in nutrient uptake, root growth, and soil microbial communities. However, the availability of Mn in the soil can be limited due to factors like soil pH, redox potential, organic matter content, and mineralogy. The excessive use of chemical fertilizers containing Mn can lead to negative consequences for soil and environmental health, such as soil and water pollution. Recent research highlights the significance of microbial interactions in enhancing Mn uptake in plants, offering a more environmentally friendly approach to address Mn deficiencies. Microbes employ various strategies, including pH reduction, organic acid production, and the promotion of root growth, to increase Mn bioavailability. They also produce siderophores, anti-pathogenic compounds, and form symbiotic relationships with plants, thereby facilitating Mn uptake, transport, and stimulating plant growth, while minimizing negative environmental impacts. This review explores the factors impacting the mobility of Mn in soil and plants, and highlights the problems caused by the scarcity of Mn in the soil and the use of chemical fertilizers, including the consequences. Furthermore, it investigates the potential of different soil microbes in addressing these challenges using environmentally friendly methods. This review suggests that microbial interactions could be a promising strategy for improving Mn uptake in plants, resulting in enhanced agricultural productivity and environmental sustainability. However, further research is needed to fully understand these interactions’ mechanisms and optimize their use in agricultural practices.
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