2020
DOI: 10.1039/c9dt03570b
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Routes of iron entry into, and exit from, the catalytic ferroxidase sites of the prokaryotic ferritin SynFtn

Abstract: This work describes the identification of two residues, D137 and E62, that are critical for, respectively, the transport of Fe2+ into, and Fe3+ out of, the catalytic sites of a prokaryotic ferritin.

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Cited by 11 publications
(21 citation statements)
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“…Surprisingly, however, the rate at which the rapid iron oxidation phase of the apo protein was regenerated in variant D65A was also almost identical to that of the wild-type protein. Therefore, the impaired mineralization activity of variant D65A cannot be a consequence of increased stability of the di-Fe 3+ form of the FOC, as was reported for variant E62A [18], suggesting that the replacement of Asp65 has a less direct effect on the exit of Fe 3+ from the FOC.…”
Section: Resultsmentioning
confidence: 66%
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“…Surprisingly, however, the rate at which the rapid iron oxidation phase of the apo protein was regenerated in variant D65A was also almost identical to that of the wild-type protein. Therefore, the impaired mineralization activity of variant D65A cannot be a consequence of increased stability of the di-Fe 3+ form of the FOC, as was reported for variant E62A [18], suggesting that the replacement of Asp65 has a less direct effect on the exit of Fe 3+ from the FOC.…”
Section: Resultsmentioning
confidence: 66%
“…The data reported here demonstrates that transport of iron to the FOC is inhibited in Syn Ftn variant E141A. However, the effect is less severe than that caused by disruption of the threefold channel by the D137A substitution that led to loss of all rapid Fe 2+ oxidation activity [18]. This suggests that residue Glu141 is not essential for Fe 2+ to traverse the protein coat, and that its role is to direct incoming metal toward the catalytic FOCs.…”
Section: Discussionmentioning
confidence: 88%
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“…The proposal of dedicated routes for the transportation of Fe 2+ from bulk solution through the protein coat to the site of oxidation has faced resistance due to the existence of a channel directly linking the ferroxidase center to bulk solution (143). However, there is increasing evidence that networks of carboxylate residues with conformational flexibility play key roles in Fe 2+ transfer in all cage-forming ferritins (141,142,(144)(145)(146). All ferritins sequester Fe 2+ from solution and utilize an electron accepting co-substrate, such as O2 or H2O2, to drive its oxidation to the Fe 3+ state.…”
Section: Iron Storage In Bacteriamentioning
confidence: 99%