Metagenomic assembled genomes indicated the potential application of hypersaline microbiome for plant growth promotion and stress alleviation in salinized soils

Climate change is causing unpredictable seasonal variations globally. Due to the continuously increasing earth's surface temperature, the rate of water evaporation is enhanced, conceiving a problem of soil salinization, especially in arid and semi-arid regions. The accumulation of salt degrades...

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Bibliographic Details
Published in:mSystems 2024-03, Vol.9 (3), p.e0105023-e0105023
Main Authors: Dindhoria, Kiran, Kumar, Raghawendra, Bhargava, Bhavya, Kumar, Rakshak
Format: Article
Language:English
Subjects:
Agricultural practices
Agriculture
Bacteria
Climate change
Ecosystem recovery
Ecosystems
Environmental Microbiology
Evaporation
Exopolysaccharides
Genetic resources
Genomes
Genomic analysis
heavy metal stress
Heavy metals
Hydration
hypersaline ecosystems
Indoleacetic acid
Metabolism
Metagenome
metagenomic assembled genomes
Metagenomics
Metals, Heavy
Microbiomes
Microbiota - genetics
Microflora
Microorganisms
Pest control
Plant growth
plant growth promotion
Proteins
Research Article
Salinity tolerance
salinized soil
Salt
salt stress
Seasonal variations
Soil
Soil fertility
Solubilization
Sustainable agriculture
Taxonomy
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Summary:Climate change is causing unpredictable seasonal variations globally. Due to the continuously increasing earth's surface temperature, the rate of water evaporation is enhanced, conceiving a problem of soil salinization, especially in arid and semi-arid regions. The accumulation of salt degrades soil quality, impairs plant growth, and reduces agricultural yields. Salt-tolerant, plant-growth-promoting microorganisms may offer a solution, enhancing crop productivity and soil fertility in salinized areas. In the current study, genome-resolved metagenomic analysis has been performed to investigate the salt-tolerating and plant growth-promoting potential of two hypersaline ecosystems, Sambhar Lake and Drang Mine. The samples were co-assembled independently by Megahit, MetaSpades, and IDBA-UD tools. A total of 67 metagenomic assembled genomes (MAGs) were reconstructed following the binning process, including 15 from Megahit, 26 from MetaSpades, and 26 from IDBA_UD assembly tools. As compared to other assemblers, the MAGs obtained by MetaSpades were of superior quality, with a completeness range of 12.95%-96.56% and a contamination range of 0%-8.65%. The medium and high-quality MAGs from MetaSpades, upon functional annotation, revealed properties such as salt tolerance (91.3%), heavy metal tolerance (95.6%), exopolysaccharide (95.6%), and antioxidant (60.86%) biosynthesis. Several plant growth-promoting attributes, including phosphate solubilization and indole-3-acetic acid (IAA) production, were consistently identified across all obtained MAGs. Conversely, characteristics such as iron acquisition and potassium solubilization were observed in a substantial majority, specifically 91.3%, of the MAGs. The present study indicates that hypersaline microflora can be used as bio-fertilizing agents for agricultural practices in salinized areas by alleviating prevalent stresses. The strategic implementation of metagenomic assembled genomes (MAGs) in exploring the properties and harnessing microorganisms from ecosystems like hypersaline niches has transformative potential in agriculture. This approach promises to redefine our comprehension of microbial diversity and its ecosystem roles. Recovery and decoding of MAGs unlock genetic resources, enabling the development of new solutions for agricultural challenges. Enhanced understanding of these microbial communities can lead to more efficient nutrient cycling, pest control, and soil health maintenance. Consequently, tradition
ISSN:2379-5077
2379-5077
DOI:10.1128/msystems.01050-23