Isolation and Characterization of Culturable Osmotolerant Microbiota in Hypersaline and Hypergypsic Soils as New Treatment for Osmotic Stress in Plants

IF 2.9 Q2 SOIL SCIENCE
Tatiana Gil, Raquel Teixeira, André Sousa, Maria Alice d’Oliveira Palmeiro, Alice Cruz Coimbra de Matos, Marla Niza Costa, María Victoria Ferrer, Ana Sofía Rodrígues dos Santos, Cristina Sequero López, Inês Rebelo Romão, Juan Ignacio Vílchez
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Abstract

Saline and gypsic soils impede or condition the establishment of farms in many regions worldwide. Stress caused by the accumulation of sodium or calcium ions in the soil drastically limits plant growth and is a limiting factor in the production of many crops. For this reason, saline and gypsic soils were preferentially exploited for mineral extraction. However, nowadays, they can be a source of new biotechnological tools to help in the osmotic stress to which some crops are exposed. In these environments, despite being traditionally characterized by their low biodiversity, we can find well-adapted microbiota that may be able to interact with plants to deal with different environmental stresses. These mechanisms may consist of a very important contribution to the development of new osmotic stress-dealing bioinoculants. The present study sought to elucidate the diversity of the cultivable population of such environments and use them as regulators of soil nutrients and stress-relieving symbionts in plants under osmotic stress. Among the candidate strains selected to cover more scenarios, we found that the strains Stutzerimonas stutzeri A38 and Bacillus pumilus A49 were able to increase root size under osmotic stress in Medicago sativa and Medicago polymorpha plants. Moreover, Peribacillus frigoritolerans A70 and Bacillus licheniformis A46 also enhanced the performance in M. polymorpha, showing interesting potential for a future use in wasteland use for production to livestock feeding or other relevant industries.
高盐和高塑性土壤中可培养的耐渗透微生物群的分离和特性研究——作为植物抗渗透胁迫的新处理手段
盐碱地和石膏土阻碍或制约了世界上许多地区农场的建立。土壤中钠离子或钙离子的积累引起的胁迫极大地限制了植物的生长,是许多作物生产的限制因素。因此,盐碱土和石膏土被优先用于矿物提取。然而,如今,它们可以成为新的生物技术工具的来源,以帮助某些作物遭受渗透胁迫。在这些环境中,尽管传统上以生物多样性低为特征,但我们可以找到适应良好的微生物群,它们可能能够与植物相互作用,以应对不同的环境压力。这些机制可能对开发新的处理渗透应力的生物接种剂有重要的贡献。本研究旨在阐明这种环境下可栽培种群的多样性,并利用它们作为渗透胁迫下植物土壤养分和抗逆性共生体的调节因子。在选择的候选菌株中,我们发现菌株Stutzerimonas stutzeri A38和杆状芽孢杆菌A49能够在渗透胁迫下增加苜蓿(Medicago sativa)和多花苜蓿(Medicago polymorpha)植株的根大小。此外,冻干芽孢杆菌A70和地衣芽孢杆菌A46对多形芽孢杆菌也有增强作用,在畜禽饲养或其他相关产业的荒地生产中具有潜在的应用前景。
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来源期刊
Soil Systems
Soil Systems Earth and Planetary Sciences-Earth-Surface Processes
CiteScore
5.30
自引率
5.70%
发文量
80
审稿时长
11 weeks
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