The Bradyrhizobium japonicum Ferrous Iron Transporter FeoAB Is Required for Ferric Iron Utilization in Free Living Aerobic Cells and for Symbiosis

The Bradyrhizobium japonicum Ferrous Iron Transporter FeoAB Is Required for Ferric Iron Utilization in Free Living Aerobic Cells and for Symbiosis

The bacterium Bradyrhizobium japonicum USDA110 does not synthesize siderophores for iron utilization in aerobic environments, and the mechanism of iron uptake within symbiotic soybean root nodules is unknown. An mbfA bfr double mutant defective in iron export and storage activities cannot grow aerob...

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Published in:The Journal of biological chemistry Vol. 291; no. 30; pp. 15653 - 15662
Main Authors: Sankari, Siva, O'Brian, Mark R.
Format: Journal Article
Language:English
Published: United States Elsevier Inc 22-07-2016
American Society for Biochemistry and Molecular Biology
Subjects:
Aerobiosis - physiology
bacteria
Bacterial Proteins - genetics
Bacterial Proteins - metabolism
BRADYRHIZOBIUM
Bradyrhizobium - genetics
Bradyrhizobium - metabolism
Glycine max - microbiology
iron
Iron - metabolism
Membrane Transport Proteins - genetics
Membrane Transport Proteins - metabolism
Microbiology
nitrogen fixation
Root Nodules, Plant - metabolism
Root Nodules, Plant - microbiology
symbiosis
Symbiosis - physiology
transport metal
iron
bacteria
nitrogen fixation
BRADYRHIZOBIUM
symbiosis
transport metal
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Summary:The bacterium Bradyrhizobium japonicum USDA110 does not synthesize siderophores for iron utilization in aerobic environments, and the mechanism of iron uptake within symbiotic soybean root nodules is unknown. An mbfA bfr double mutant defective in iron export and storage activities cannot grow aerobically in very high iron medium. Here, we found that this phenotype was suppressed by loss of function mutations in the feoAB operon encoding ferrous (Fe2+) iron uptake proteins. Expression of the feoAB operon genes was elevated under iron limitation, but mutants defective in either gene were unable to grow aerobically over a wide external ferric (Fe3+) iron (FeCl3) concentration range. Thus, FeoAB accommodates iron acquisition under iron limited and iron replete conditions. Incorporation of radiolabel from either 55Fe2+ or 59Fe3+ into cells was severely defective in the feoA and feoB strains, suggesting Fe3+ reduction to Fe2+ prior to traversal across the cytoplasmic membrane by FeoAB. The feoA or feoB deletion strains elicited small, ineffective nodules on soybean roots, containing few bacteria and lacking nitrogen fixation activity. A feoA(E40K) mutant contained partial iron uptake activity in culture that supported normal growth and established an effective symbiosis. The feoA(E40K) strain had partial iron uptake activity in situ within nodules and in isolated cells, indicating that FeoAB is the iron transporter in symbiosis. We conclude that FeoAB supports iron acquisition under limited conditions of soil and in the iron-rich environment of a symbiotic nodule.
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ISSN:0021-9258
1083-351X
DOI:10.1074/jbc.M116.734129