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Efficiency of Combining Strains Ag87 ( Bacillus megaterium ) and Ag94 ( Lysinibacillus sp.) as Phosphate Solubilizers and Growth Promoters in Maize.

Luana Rainieri MassucatoSuelen Regina de Araújo AlmeidaMayara Barbosa SilvaMirela MoselaDouglas Mariani ZeffaAlison Fernando NogueiraRenato Barros de Lima FilhoSilas MianAllan Yukio HigashiGustavo Manoel TeixeiraGabriel Danilo ShimizuRenata Mussoi GiacominRicardo Cancio FendrichMarcos Ventura FariaCarlos Alberto ScapimLeandro Simões Azeredo Gonçalves
Published in: Microorganisms (2022)
Increasing phosphorus (P) use efficiency in agricultural systems is urgent and essential to significantly reduce the global demand for this nutrient. Applying phosphate-solubilizing and plant growth-promoting bacteria in the rhizosphere represents a strategy worthy of attention. In this context, the present work aimed to select and validate bacterial strains capable of solubilizing phosphorous and promoting maize growth, aiming to develop a microbial inoculant to be used in Brazilian agriculture. Bacterial strains from the maize rhizosphere were evaluated based on their ability to solubilize phosphate and produce indole acetic acid. Based on these characteristics, 24 strains were selected to be further evaluated under laboratory, greenhouse, and field conditions. Among the selected strains, four (I04, I12, I13, and I17) showed a high potential to increase maize root growth and shoot P content. Strains I13 (Ag87) and I17 (Ag94) were identified by genomic sequencing as Bacillus megaterium and Lysinibacillus sp., respectively. These strains presented superior yield increments relative to the control treatment with 30% P. In addition, combining Ag87 and Ag94 resulted in even higher yield gains, indicating a synergistic effect that could be harnessed in a commercial inoculant for Brazilian agriculture.
Keyphrases
  • escherichia coli
  • quantum dots
  • climate change
  • microbial community
  • plant growth
  • highly efficient
  • risk assessment
  • heavy metals
  • gene expression
  • human health
  • copy number
  • single cell