Genotypic characterization of Azotobacteria isolated from Argentinean soils and plant - growth - promoting traits of selected strains with prospects for biofertilizer production

The genetic diversity among 31 putative Azotobacter isolates obtained from agricultural and non-agricultural soils was assessed using rep-PCR genomic fingerprinting and identified to species level by ARDRA and partial 16S rRNA gene sequence analysis. High diversity was found among the isolates, identified as A. chroococcum, A. salinestris, and A. armeniacus. Selected isolates were characterized on the basis of phytohormone biosynthesis, nitrogenase activity, siderophore production, and phosphate solubilization. Indole-3 acetic-acid [IAA], gibberellin [GA and zeatin [Z] biosynthesis, nitrogenase activity, and siderophore production were found in all evaluated strains, with variation among them, but no phosphate solubilization was detected. Phytohormones excreted to the culture medium ranged in the following concentrations: 2.2-18.2 g IAA mL-1, 0.3-0.7 g GAmL-1, and 0.5-1.2 g Z mL-1. Seed inoculations with further selected Azotobacter strains and treatments with their cell-free cultures increased the number of seminal roots and root hairs in wheat seedlings. This latter effect was mimicked by treatments with IAA-pure solutions, but it was not related to bacterial root colonization. Our survey constitutes a first approach to the knowledge of Azotobacter species inhabiting Argentinean soils in three contrasting geographical regions. Moreover, this phenotypic characterization constitutes an important contribution to the selection of Azotobacter strains for biofertilizer formulations.

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Bibliographic Details
Main Authors: Rubio, Esteban Julián, Montecchia, Marcela Susana, Tosi, Micaela, Cassán, Fabricio Darío, Perticari, Alejandro, Correa, Olga Susana
Format: Texto biblioteca
Language:eng
Subjects:BIOFERTILIZER, FERTILIZER, GIBBERELLIN, INDOLEACETIC ACID, NITROGENASE, ORGANIC MATTER, PHOSPHATE, PHYTOHORMONE, RNA 16S, SIDEROPHORE, UNCLASSIFIED DRUG, ZEATIN, AIR, AMPLIFIED RIBOSOMAL DNA RESTRICTION ANALYSIS, AZOTOBACTER ARMENIACUS, AZOTOBACTER CHROOCOCCUM, AZOTOBACTER GROUP, AZOTOBACTER SALINESTRIS, AZOTOBACTER VINELANDII, BACTERIAL COLONIZATION, BACTERIAL STRAIN, BACTERIUM ISOLATION, CHEMICAL PARAMETERS, CONTROLLED STUDY, CULTURE MEDIUM, ELECTRIC CONDUCTIVITY, GENE SEQUENCE, GENETIC VARIABILITY, GENOTYPE, HIGH PERFORMANCE LIQUID CHROMATOGRAPHY, HORMONE SYNTHESIS, IN VITRO STUDY, NONHUMAN, PH, PLANT-GROWTH PROMOTING BACTERIUM, POLYMERASE CHAIN REACTION, ROOT HAIR, ROOT MORPHOLOGY, SEED INOCULATION, SOIL ANALYSIS, SOLUBILIZATION, SPECIES IDENTIFICATION, SUSTAINABLE AGRICULTURE,
Online Access:http://ceiba.agro.uba.ar/cgi-bin/koha/opac-detail.pl?biblionumber=46877
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Summary:The genetic diversity among 31 putative Azotobacter isolates obtained from agricultural and non-agricultural soils was assessed using rep-PCR genomic fingerprinting and identified to species level by ARDRA and partial 16S rRNA gene sequence analysis. High diversity was found among the isolates, identified as A. chroococcum, A. salinestris, and A. armeniacus. Selected isolates were characterized on the basis of phytohormone biosynthesis, nitrogenase activity, siderophore production, and phosphate solubilization. Indole-3 acetic-acid [IAA], gibberellin [GA and zeatin [Z] biosynthesis, nitrogenase activity, and siderophore production were found in all evaluated strains, with variation among them, but no phosphate solubilization was detected. Phytohormones excreted to the culture medium ranged in the following concentrations: 2.2-18.2 g IAA mL-1, 0.3-0.7 g GAmL-1, and 0.5-1.2 g Z mL-1. Seed inoculations with further selected Azotobacter strains and treatments with their cell-free cultures increased the number of seminal roots and root hairs in wheat seedlings. This latter effect was mimicked by treatments with IAA-pure solutions, but it was not related to bacterial root colonization. Our survey constitutes a first approach to the knowledge of Azotobacter species inhabiting Argentinean soils in three contrasting geographical regions. Moreover, this phenotypic characterization constitutes an important contribution to the selection of Azotobacter strains for biofertilizer formulations.