Rhizosphere Microorganisms with Different Strategies and Mechanisms to Enhance Plant Growth in the Occurrence of Different Environmental Stress Factors

IF 0.7 Q4 MICROBIOLOGY

Journal of Pure and Applied Microbiology Pub Date : 2023-09-03 DOI:10.22207/jpam.17.3.59

Mona Othman I. Albureikan

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引用次数: 0

Abstract

Every minute, the world’s population grows, and in order to feed them, crop output and agricultural productivity must be improved by adding crucial microorganisms that boost plant yields in various ways through nitrogen fixation, the secretion of both plant growth regulators and 1-aminocyclopropane 1-carboxylate deaminase, as well as some antimicrobial agents. Numerous endophytic bacteria have recently been used to increase plant yields, and agricultural production in addition to reducing salt stresses. Many scientists have made an effort to clarify and comprehend the processes by which bacteria promote plant growth and production. A vital substance known as 1-aminocyclopropane-1-carboxylate (ACC) deaminase is produced by several bacteria, plants, and fungi to decrease ethylene levels in a plant grown under different environmental stress. The gaseous hormone ethylene (C2H4) is synthesized in plant tissues from the precursor ACC, and it has numerous biochemical roles in plants, such as cells differentiation and tissue development, seedling, root hair, leaf, and flower growth and development in addition to fruit ripening and formation of anthocyanin and volatile compounds. Thus, this critical enzyme had influential roles in plants during their positive interaction with bacteria which increase plant growth due to auxin production and protect plants against different environmental stress like drought, high salts, wilting, high level of heavy metals, contaminants with pesticides, and microbial pathogen infections. Different bacterial genera are highly ACC deaminase-producer, and these bacteria support plant growth and agricultural process. In conclusion, bacteria can replace chemicals in a variety of environmentally benign methods to boost soil fertility and plant productivity. However, much research is required to determine the efficacy of these bacteria before suggesting their use on a broad scale in the field.

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不同环境胁迫条件下根际微生物促进植物生长的策略和机制

世界人口每分钟都在增长，为了养活他们，必须通过添加关键微生物来提高作物产量和农业生产力，这些微生物通过固氮、分泌植物生长调节剂和1-氨基环丙烷-1-羧酸脱氨酶，以及一些抗微生物剂，以各种方式提高植物产量。除了减少盐胁迫外，许多内生细菌最近还被用于提高植物产量和农业生产。许多科学家努力澄清和理解细菌促进植物生长和生产的过程。一种被称为1-氨基环丙烷-1-羧酸脱氨酶（ACC）的重要物质由几种细菌、植物和真菌产生，以降低在不同环境胁迫下生长的植物中的乙烯水平。气态激素乙烯（C2H4）是由ACC前体在植物组织中合成的，它在植物中具有许多生物化学作用，如细胞分化和组织发育、幼苗、根毛、叶片和花朵生长发育，以及果实成熟和花青素和挥发性化合物的形成。因此，在植物与细菌的积极相互作用过程中，这种关键酶在植物中发挥着重要作用，细菌由于生长素的产生而增加了植物的生长，并保护植物免受不同的环境胁迫，如干旱、高盐、枯萎、高水平重金属、杀虫剂污染物和微生物病原体感染。不同的细菌属是ACC脱氨酶的高度生产者，这些细菌支持植物生长和农业过程。总之，细菌可以通过各种无害环境的方法取代化学物质，提高土壤肥力和植物生产力。然而，在建议这些细菌在该领域广泛使用之前，还需要进行大量研究来确定它们的功效。

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来源期刊

Journal of Pure and Applied Microbiology BIOTECHNOLOGY & APPLIED MICROBIOLOGY-MICROBIOLOGY

CiteScore

2.00

自引率

0.00%

发文量

266

审稿时长

11 months

期刊介绍： Journal of Pure and Applied Microbiology (JPAM) is a peer-reviewed, open access international journal of microbiology aims to advance and disseminate research among scientists, academics, clinicians and microbiologists around the world. JPAM publishes high-quality research in all aspects of microbiology in both online and print form on quarterly basis.