3k53 Citations

Structural fold, conservation and Fe(II) binding of the intracellular domain of prokaryote FeoB.

Hung KW, Chang YW, Eng ET, Chen JH, Chen YC, Sun YJ, Hsiao CD, Dong G, Spasov KA, Unger VM, Huang TH
J Struct Biol 170 501-12 (2010)
Related entries: 2wia, 2wib, 2wic

Cited: 20 times
EuropePMC logo PMID: 20123128

Abstract

FeoB is a G-protein coupled membrane protein essential for Fe(II) uptake in prokaryotes. Here, we report the crystal structures of the intracellular domain of FeoB (NFeoB) from Klebsiella pneumoniae (KpNFeoB) and Pyrococcus furiosus (PfNFeoB) with and without bound ligands. In the structures, a canonical G-protein domain (G domain) is followed by a helical bundle domain (S-domain), which despite its lack of sequence similarity between species is structurally conserved. In the nucleotide-free state, the G-domain's two switch regions point away from the binding site. This gives rise to an open binding pocket whose shallowness is likely to be responsible for the low nucleotide-binding affinity. Nucleotide binding induced significant conformational changes in the G5 motif which in the case of GMPPNP binding was accompanied by destabilization of the switch I region. In addition to the structural data, we demonstrate that Fe(II)-induced foot printing cleaves the protein close to a putative Fe(II)-binding site at the tip of switch I, and we identify functionally important regions within the S-domain. Moreover, we show that NFeoB exists as a monomer in solution, and that its two constituent domains can undergo large conformational changes. The data show that the S-domain plays important roles in FeoB function.

Reviews - 3k53 mentioned but not cited (1)

  1. Ins and Outs: Recent Advancements in Membrane Protein-Mediated Prokaryotic Ferrous Iron Transport. Brown JB, Lee MA, Smith AT. Biochemistry 60 3277-3291 (2021)


Reviews citing this publication (4)

  1. Bacterial ferrous iron transport: the Feo system. Lau CK, Krewulak KD, Vogel HJ. FEMS Microbiol. Rev. 40 273-298 (2016)
  2. Genetic and structural determinants on iron assimilation pathways in the plant pathogen Xanthomonas citri subsp. citri and Xanthomonas sp. Guerra GS, Balan A. Braz J Microbiol 51 1219-1231 (2020)
  3. Structures and coordination chemistry of transporters involved in manganese and iron homeostasis. Ray S, Gaudet R. Biochem Soc Trans 51 897-923 (2023)
  4. Toward a mechanistic understanding of Feo-mediated ferrous iron uptake. Sestok AE, Linkous RO, Smith AT. Metallomics 10 887-898 (2018)

Articles citing this publication (15)

  1. FeoA and FeoC are essential components of the Vibrio cholerae ferrous iron uptake system, and FeoC interacts with FeoB. Weaver EA, Wyckoff EE, Mey AR, Morrison R, Payne SM. J. Bacteriol. 195 4826-4835 (2013)
  2. The initiation of GTP hydrolysis by the G-domain of FeoB: insights from a transition-state complex structure. Ash MR, Maher MJ, Guss JM, Jormakka M. PLoS ONE 6 e23355 (2011)
  3. Crystal structure of the Klebsiella pneumoniae NFeoB/FeoC complex and roles of FeoC in regulation of Fe2+ transport by the bacterial Feo system. Hung KW, Tsai JY, Juan TH, Hsu YL, Hsiao CD, Huang TH. J. Bacteriol. 194 6518-6526 (2012)
  4. FeoC from Klebsiella pneumoniae contains a [4Fe-4S] cluster. Hsueh KL, Yu LK, Chen YH, Cheng YH, Hsieh YC, Ke SC, Hung KW, Chen CJ, Huang TH. J. Bacteriol. 195 4726-4734 (2013)
  5. NMR structure note: the ferrous iron transport protein C (FeoC) from Klebsiella pneumoniae. Hung KW, Juan TH, Hsu YL, Huang TH. J. Biomol. NMR 53 161-165 (2012)
  6. A suite of Switch I and Switch II mutant structures from the G-protein domain of FeoB. Ash MR, Maher MJ, Guss JM, Jormakka M. Acta Crystallogr. D Biol. Crystallogr. 67 973-980 (2011)
  7. Spectroscopic studies on peptides and proteins with cysteine-containing heme regulatory motifs (HRM). Schubert E, Florin N, Duthie F, Henning Brewitz H, Kühl T, Imhof D, Hagelueken G, Schiemann O. J. Inorg. Biochem. 148 49-56 (2015)
  8. Expression, purification and functional reconstitution of FeoB, the ferrous iron transporter from Pseudomonas aeruginosa. Seyedmohammad S, Born D, Venter H. Protein Expr. Purif. 101 138-145 (2014)
  9. Structural and functional analysis of a FeoB A143S G5 loop mutant explains the accelerated GDP release rate. Guilfoyle AP, Deshpande CN, Vincent K, Pedroso MM, Schenk G, Maher MJ, Jormakka M. FEBS J. 281 2254-2265 (2014)
  10. Structural model of FeoB, the iron transporter from Pseudomonas aeruginosa, predicts a cysteine lined, GTP-gated pore. Seyedmohammad S, Fuentealba NA, Marriott RA, Goetze TA, Edwardson JM, Barrera NP, Venter H. Biosci. Rep. 36 (2016)
  11. The structure of an N11A mutant of the G-protein domain of FeoB. Ash MR, Maher MJ, Guss JM, Jormakka M. Acta Crystallogr Sect F Struct Biol Cryst Commun 67 1511-1515 (2011)
  12. Vibrio cholerae FeoA, FeoB, and FeoC Interact To Form a Complex. Stevenson B, Wyckoff EE, Payne SM. J. Bacteriol. 198 1160-1170 (2016)
  13. A fusion of the Bacteroides fragilis ferrous iron import proteins reveals a role for FeoA in stabilizing GTP-bound FeoB. Sestok AE, Brown JB, Obi JO, O'Sullivan SM, Garcin ED, Deredge DJ, Smith AT. J Biol Chem 298 101808 (2022)
  14. Developing Colorimetric and Luminescence-Based High-Throughput Screening Platforms for Monitoring the GTPase Activity of Ferrous Iron Transport Protein B (FeoB). Veloria J, Shin M, Devkota AK, Payne SM, Cho EJ, Dalby KN. SLAS Discov 24 597-605 (2019)
  15. The crystal structure of Klebsiella pneumoniae FeoA reveals a site for protein-protein interactions. Linkous RO, Sestok AE, Smith AT. Proteins 87 897-903 (2019)


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