Nitrogen Assimilation and Transport by Ex Planta Nitrogen-Fixing Bradyrhizobium diazoefficiens Bacteroids Is Modulated by Oxygen, Bacteroid Density and l-Malate

Symbiotic nitrogen fixation requires the transfer of fixed organic nitrogen compounds from the symbiotic bacteria to a host plant, yet the chemical nature of the compounds is in question. bacteroids were isolated anaerobically from soybean nodules and assayed at varying densities, varying partial pr...

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Bibliographic Details
Published in:International journal of molecular sciences 2020-10, Vol.21 (20), p.7542
Main Authors: Waters, James K, Mawhinney, Thomas P, Emerich, David W
Format: Article
Language:English
Subjects:
Alanine
Alanine - metabolism
Amino acids
ammonia/ammonium
Ammonium
Ammonium Compounds - metabolism
Bacteria
Bacterial Proteins - metabolism
Bacteroids
Biological assimilation
Bradyrhizobium - metabolism
Bradyrhizobium - pathogenicity
Bradyrhizobium diazoefficiens
Chain branching
Chemical compounds
Dehydrogenases
Enzymes
Excretion
Glycine max - microbiology
Host plants
Kinetics
Labeling
Malate
Malates - metabolism
Membrane Transport Proteins - metabolism
Metabolism
Metabolites
Nitrogen
Nitrogen Fixation
Nitrogenation
Nodules
Oxygen - metabolism
Partial pressure
Root Nodules, Plant - metabolism
Root Nodules, Plant - microbiology
Soybeans
Symbiosis
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Summary:Symbiotic nitrogen fixation requires the transfer of fixed organic nitrogen compounds from the symbiotic bacteria to a host plant, yet the chemical nature of the compounds is in question. bacteroids were isolated anaerobically from soybean nodules and assayed at varying densities, varying partial pressures of oxygen, and varying levels of l-malate. Ammonium was released at low bacteroid densities and high partial pressures of oxygen, but was apparently taken up at high bacteroid densities and low partial pressures of oxygen in the presence of l-malate; these later conditions were optimal for amino acid excretion. The ratio of partial pressure of oxygen/bacteroid density of apparent ammonium uptake and of alanine excretion displayed an inverse relationship. Ammonium uptake, alanine and branch chain amino acid release were all dependent on the concentration of l-malate displaying similar K values of 0.5 mM demonstrating concerted regulation. The hyperbolic kinetics of ammonium uptake and amino acid excretion suggests transport via a membrane carrier and also suggested that transport was rate limiting. Glutamate uptake displayed exponential kinetics implying transport via a channel. The chemical nature of the compounds released were dependent upon bacteroid density, partial pressure of oxygen and concentration of l-malate demonstrating an integrated metabolism.
ISSN:1422-0067
1661-6596
1422-0067
DOI:10.3390/ijms21207542