The Plant Growth-Promoting Potential of Halotolerant Bacteria Is Not Phylogenetically Determined: Evidence from Two Bacillus megaterium Strains Isolated from Saline Soils Used to Grow Wheat

(1) Background: Increasing salinity, further potentiated by climate change and soil degradation, will jeopardize food security even more. Therefore, there is an urgent need for sustainable agricultural practices capable of maintaining high crop yields despite adverse conditions. Here, we tested if w...

Full description

Saved in:
Bibliographic Details
Published in:Microorganisms (Basel) 2023-06, Vol.11 (7), p.1687
Main Authors: Ait Bessai, Sylia, Cruz, Joana, Carril, Pablo, Melo, Juliana, Santana, Margarida M, Mouazen, Abdul M, Cruz, Cristina, Yadav, Ajar Nath, Dias, Teresa, Nabti, El-Hafid
Format: Article
Language:English
Subjects:
Agricultural land
Agricultural practices
Agricultural production
Bacteria
biofertilizer
Biofertilizers
Cell division
Cereal crops
Climate change
Corn
Crop diseases
Crop yield
Crops
Enzymes
Flowers & plants
Food security
Germination
halotolerant bacterial strains
Hydroponics
Nitrogen
Nutrient availability
Nutrient cycles
Nutrients
Nutrition
Phylogeny
Physiology
Plant diseases
Plant growth
plant growth promoting traits
Plant resistance
Pseudomonas fluorescens
Reservoirs
Saline soils
Salinity
Salinity effects
Salinity tolerance
Salt
Seed germination
Seedlings
Seeds
Sodium chloride
Soil degradation
Soil microorganisms
Strains (organisms)
Sustainable agriculture
Sustainable practices
Wheat
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:(1) Background: Increasing salinity, further potentiated by climate change and soil degradation, will jeopardize food security even more. Therefore, there is an urgent need for sustainable agricultural practices capable of maintaining high crop yields despite adverse conditions. Here, we tested if wheat, a salt-sensitive crop, could be a good reservoir for halotolerant bacteria with plant growth-promoting (PGP) capabilities. (2) Methods: We used two agricultural soils from Algeria, which differ in salinity but are both used to grow wheat. Soil halotolerant bacterial strains were isolated and screened for 12 PGP traits related to phytohormone production, improved nitrogen and phosphorus availability, nutrient cycling, and plant defence. The four 'most promising' halotolerant PGPB strains were tested hydroponically on wheat by measuring their effect on germination, survival, and biomass along a salinity gradient. (3) Results: Two halotolerant bacterial strains with PGP traits were isolated from the non-saline soil and were identified as and , and another two halotolerant bacterial strains with PGP traits were isolated from the saline soil and identified as . When grown under 250 mM of NaCl, only the inoculated wheat seedlings survived. The halotolerant bacterial strain that displayed all 12 PGP traits and promoted seed germination and plant growth the most was one of the strains isolated from the saline soil. Although they both belonged to the clade and displayed a remarkable halotolerance, the two bacterial strains isolated from the saline soil differed in two PGP traits and had different effects on plant performance, which clearly shows that PGP potential is not phylogenetically determined. (4) Conclusions: Our data highlight that salt-sensitive plants and non-saline soils can be reservoirs for halotolerant microbes with the potential to become effective and sustainable strategies to improve plant tolerance to salinity. However, these strains need to be tested under field conditions and with more crops before being considered biofertilizer candidates.
ISSN:2076-2607
2076-2607
DOI:10.3390/microorganisms11071687