Plant-microbe interactions in the rhizosphere for smarter and more sustainable crop fertilization: the case of PGPR-based biofertilizers

Mónica Yorlady Alzate Zuluaga, Roberto Fattorini, S. Cesco, Y. Pii
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Abstract

Biofertilizers based on plant growth promoting rhizobacteria (PGPR) are nowadays gaining increasingly attention as a modern tool for a more sustainable agriculture due to their ability in ameliorating root nutrient acquisition. For many years, most research was focused on the screening and characterization of PGPR functioning as nitrogen (N) or phosphorus (P) biofertilizers. However, with the increasing demand for food using far fewer chemical inputs, new investigations have been carried out to explore the potential use of such bacteria also as potassium (K), sulfur (S), zinc (Zn), or iron (Fe) biofertilizers. In this review, we update the use of PGPR as biofertilizers for a smarter and more sustainable crop production and deliberate the prospects of using microbiome engineering-based methods as potential tools to shed new light on the improvement of plant mineral nutrition. The current era of omics revolution has enabled the design of synthetic microbial communities (named SynComs), which are emerging as a promising tool that can allow the formulation of biofertilizers based on PGPR strains displaying multifarious and synergistic traits, thus leading to an increasingly efficient root acquisition of more than a single essential nutrient at the same time. Additionally, host-mediated microbiome engineering (HMME) leverages advanced omics techniques to reintroduce alleles coding for beneficial compounds, reinforcing positive plant-microbiome interactions and creating plants capable of producing their own biofertilizers. We also discusses the current use of PGPR-based biofertilizers and point out possible avenues of research for the future development of more efficient biofertilizers for a smarter and more precise crop fertilization. Furthermore, concerns have been raised about the effectiveness of PGPR-based biofertilizers in real field conditions, as their success in controlled experiments often contrasts with inconsistent field results. This discrepancy highlights the need for standardized protocols to ensure consistent application and reliable outcomes.
根圈中植物与微生物的相互作用,促进更智能、更可持续的作物施肥:基于 PGPR 的生物肥料案例
如今,基于植物生长促进根瘤菌(PGPR)的生物肥料因其改善根部养分吸收的能力而日益受到关注,成为一种促进农业可持续发展的现代工具。多年来,大多数研究都集中在筛选和鉴定可用作氮(N)或磷(P)生物肥料的 PGPR。然而,随着人们对使用更少化学投入的食品的需求不断增加,新的研究开始探索这类细菌作为钾(K)、硫(S)、锌(Zn)或铁(Fe)生物肥料的潜在用途。在这篇综述中,我们更新了将 PGPR 作为生物肥料用于更智能、更可持续的作物生产的情况,并探讨了将基于微生物组工程的方法作为潜在工具,为改善植物矿质营养提供新启示的前景。当前的全息技术革命使合成微生物群落(SynComs)的设计成为可能,它是一种前景广阔的工具,可以根据具有多种协同特性的 PGPR 菌株配制生物肥料,从而使根系在同一时间获取多种必需营养元素的效率越来越高。此外,宿主介导的微生物组工程(HMME)利用先进的组学技术重新引入编码有益化合物的等位基因,加强植物与微生物组之间的良性互动,创造出能够生产自身生物肥料的植物。我们还讨论了目前基于 PGPR 的生物肥料的使用情况,并指出了未来开发更高效生物肥料的可能研究途径,以实现更智能、更精确的作物施肥。此外,人们还对基于 PGPR 的生物肥料在实际田间条件下的效果表示担忧,因为它们在对照实验中的成功往往与不一致的田间结果形成鲜明对比。这种差异凸显了标准化方案的必要性,以确保一致的应用和可靠的结果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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