4mku Citations

Time-lapse anomalous X-ray diffraction shows how Fe(2+) substrate ions move through ferritin protein nanocages to oxidoreductase sites.

Pozzi C, Di Pisa F, Lalli D, Rosa C, Theil E, Turano P, Mangani S
Acta Crystallogr D Biol Crystallogr 71 941-53 (2015)
Related entries: 4lpj, 4lqh, 4lqj, 4lqv, 4lyu, 4lyx, 4mjy, 4ml5, 4mn9, 4my7, 6i36

Cited: 20 times
EuropePMC logo PMID: 25849404

Abstract

Ferritin superfamily protein cages reversibly synthesize internal biominerals, Fe2O3·H2O. Fe(2+) and O2 (or H2O2) substrates bind at oxidoreductase sites in the cage, initiating biomineral synthesis to concentrate iron and prevent potentially toxic reactions products from Fe(2+)and O2 or H2O2 chemistry. By freezing ferritin crystals of Rana catesbeiana ferritin M (RcMf) at different time intervals after exposure to a ferrous salt, a series of high-resolution anomalous X-ray diffraction data sets were obtained that led to crystal structures that allowed the direct observation of ferrous ions entering, moving along and binding at enzyme sites in the protein cages. The ensemble of crystal structures from both aerobic and anaerobic conditions provides snapshots of the iron substrate bound at different cage locations that vary with time. The observed differential occupation of the two iron sites in the enzyme oxidoreductase centre (with Glu23 and Glu58, and with Glu58, His61 and Glu103 as ligands, respectively) and other iron-binding sites (with Glu53, His54, Glu57, Glu136 and Asp140 as ligands) reflects the approach of the Fe(2+) substrate and its progression before the enzymatic cycle 2Fe(2+) + O2 → Fe(3+)-O-O-Fe(3+) → Fe(3+)-O(H)-Fe(3+) and turnover. The crystal structures also revealed different Fe(2+) coordination compounds bound to the ion channels located at the threefold and fourfold symmetry axes of the cage.

Articles - 4mku mentioned but not cited (1)

  1. Time-lapse anomalous X-ray diffraction shows how Fe(2+) substrate ions move through ferritin protein nanocages to oxidoreductase sites. Pozzi C, Di Pisa F, Lalli D, Rosa C, Theil E, Turano P, Mangani S. Acta Crystallogr D Biol Crystallogr 71 941-953 (2015)


Reviews citing this publication (5)

  1. Dioxygen Activation by Nonheme Diiron Enzymes: Diverse Dioxygen Adducts, High-Valent Intermediates, and Related Model Complexes. Jasniewski AJ, Que L. Chem Rev 118 2554-2592 (2018)
  2. Iron, Ferritin, Hereditary Ferritinopathy, and Neurodegeneration. Muhoberac BB, Vidal R. Front Neurosci 13 1195 (2019)
  3. Diversity of Fe2+ entry and oxidation in ferritins. Bradley JM, Moore GR, Le Brun NE. Curr Opin Chem Biol 37 122-128 (2017)
  4. Iron/iron oxide nanoparticles: advances in microbial fabrication, mechanism study, biomedical, and environmental applications. Ashraf N, Ahmad F, Da-Wei L, Zhou RB, Feng-Li H, Yin DC. Crit Rev Microbiol 45 278-300 (2019)
  5. Ferritin: A Promising Nanoreactor and Nanocarrier for Bionanotechnology. Mohanty A, Parida A, Raut RK, Behera RK. ACS Bio Med Chem Au 2 258-281 (2022)

Articles citing this publication (14)

  1. Observation of gold sub-nanocluster nucleation within a crystalline protein cage. Maity B, Abe S, Ueno T. Nat Commun 8 14820 (2017)
  2. Chemistry at the protein-mineral interface in L-ferritin assists the assembly of a functional (μ3-oxo)Tris[(μ2-peroxo)] triiron(III) cluster. Pozzi C, Ciambellotti S, Bernacchioni C, Di Pisa F, Mangani S, Turano P. Proc Natl Acad Sci U S A 114 2580-2585 (2017)
  3. Solid-State NMR of PEGylated Proteins. Ravera E, Ciambellotti S, Cerofolini L, Martelli T, Kozyreva T, Bernacchioni C, Giuntini S, Fragai M, Turano P, Luchinat C. Angew Chem Int Ed Engl 55 2446-2449 (2016)
  4. Ferritin variants: inspirations for rationally designing protein nanocarriers. Jin Y, He J, Fan K, Yan X. Nanoscale 11 12449-12459 (2019)
  5. Electrostatic and Structural Bases of Fe2+ Translocation through Ferritin Channels. Chandramouli B, Bernacchioni C, Di Maio D, Turano P, Brancato G. J Biol Chem 291 25617-25628 (2016)
  6. Reaction of O2 with a diiron protein generates a mixed-valent Fe2+/Fe3+ center and peroxide. Bradley JM, Svistunenko DA, Pullin J, Hill N, Stuart RK, Palenik B, Wilson MT, Hemmings AM, Moore GR, Le Brun NE. Proc Natl Acad Sci U S A 116 2058-2067 (2019)
  7. Spectroscopic evidence for the role of a site of the di-iron catalytic center of ferritins in tuning the kinetics of Fe(ii) oxidation. Ebrahimi KH, Bill E, Hagedoorn PL, Hagen WR. Mol Biosyst 12 3576-3588 (2016)
  8. Self-assembly is prerequisite for catalysis of Fe(II) oxidation by catalytically active subunits of ferritin. Ebrahimi KH, Hagedoorn PL, Hagen WR. J Biol Chem 290 26801-26810 (2015)
  9. Structural comparison of two ferritins from the marine invertebrate Phascolosoma esculenta. Ming T, Huan H, Su C, Huo C, Wu Y, Jiang Q, Qiu X, Lu C, Zhou J, Li Y, Su X. FEBS Open Bio 11 793-803 (2021)
  10. Second Coordination Sphere Effects on the Mechanistic Pathways for Dioxygen Activation by a Ferritin: Involvement of a Tyr Radical and the Identification of a Cation Binding Site. Yeh CG, Mokkawes T, Bradley JM, Le Brun NE, de Visser SP. Chembiochem 23 e202200257 (2022)
  11. Structural Insights Into the Effects of Interactions With Iron and Copper Ions on Ferritin From the Blood Clam Tegillarca granosa. Ming T, Jiang Q, Huo C, Huan H, Wu Y, Su C, Qiu X, Lu C, Zhou J, Li Y, Han J, Zhang Z, Su X. Front Mol Biosci 9 800008 (2022)
  12. Key carboxylate residues for iron transit through the prokaryotic ferritin SynFtn. Bradley JM, Fair J, Hemmings AM, Le Brun NE. Microbiology (Reading) 167 (2021)
  13. Ferritin-Like Proteins: A Conserved Core for a Myriad of Enzyme Complexes. Banerjee R, Srinivas V, Lebrette H. Subcell Biochem 99 109-153 (2022)
  14. Optical Monitoring of In Situ Iron Loading into Single, Native Ferritin Proteins. Yousefi A, Ying C, Parmenter CDJ, Assadipapari M, Sanderson G, Zheng Z, Xu L, Zargarbashi S, Hickman GJ, Cousins RB, Mellor CJ, Mayer M, Rahmani M. Nano Lett 23 3251-3258 (2023)


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