Crystal Structure of Plant Ferritin Reveals a Novel Metal Binding Site That Functions as a Transit Site for Metal Transfer in Ferritin
about
Moving Metal Ions through Ferritin−Protein Nanocages from Three-Fold Pores to Catalytic SitesFerritin Structure from Mycobacterium tuberculosis: Comparative Study with Homologues Identifies Extended C-Terminus Involved in Ferroxidase ActivityThe extension peptide of plant ferritin from sea lettuce contributes to shell stability and surface hydrophobicityIron Binding at Specific Sites within the Octameric HbpS Protects Streptomycetes from Iron-Mediated Oxidative StressRole of H-1 and H-2 subunits of soybean seed ferritin in oxidative deposition of iron in protein.Moving Fe2+ from ferritin ion channels to catalytic OH centers depends on conserved protein cage carboxylates.Ferritin protein nanocage ion channels: gating by N-terminal extensions.The catalytic center of ferritin regulates iron storage via Fe(II)-Fe(III) displacement.The B-type channel is a major route for iron entry into the ferroxidase center and central cavity of bacterioferritin.Overexpression of wheat ferritin gene TaFER-5B enhances tolerance to heat stress and other abiotic stresses associated with the ROS scavenging.Functionality of the three-site ferroxidase center of Escherichia coli bacterial ferritin (EcFtnA).Structure, function, and nutrition of phytoferritin: a newly functional factor for iron supplement.Mechanisms of iron mineralization in ferritins: one size does not fit all.Interactions between plant proteins/enzymes and other food components, and their effects on food quality.Ferritin cage for encapsulation and delivery of bioactive nutrients: From structure, property to applications.H-Ferritin Is Preferentially Incorporated by Human Erythroid Cells through Transferrin Receptor 1 in a Threshold-Dependent Manner.The Ferritin Superfamily.Electron Paramagnetic Resonance (EPR) Spectroscopy in Studies of the Protective Effects of 24-Epibrasinoide and Selenium against Zearalenone-Stimulation of the Oxidative Stress in Germinating Grains of Wheat.Protein association and dissociation regulated by extension peptide: a mode for iron control by phytoferritin in seeds.A novel EP-involved pathway for iron release from soya bean seed ferritin.The C-terminal regions have an important role in the activity of the ferroxidase center and the stability of Chlorobium tepidum ferritin.First biochemical and crystallographic characterization of a fast-performing ferritin from a marine invertebrate.Designing non-native iron-binding site on a protein cage for biological synthesis of nanoparticles.The Size Flexibility of Ferritin Nanocage Opens a New Way to Prepare Nanomaterials.Identification and characterization of a ferritin gene and its product from the multicellular green alga Ulva pertusa.The iron content and ferritin contribution in fresh, dried, and toasted nori, Pyropia yezoensis.Flexible aspartates propel iron to the ferroxidation sites along pathways stabilized by a conserved arginine in Dps proteins from Mycobacterium smegmatis.Self-assembly of ferritin nanocages into linear chains induced by poly(α, L-lysine).2D square arrays of protein nanocages through channel-directed electrostatic interactions with poly(α, l-lysine).The stage of seed development influences iron bioavailability in pea (Pisum sativum L.).
P2860
Q27664657-669EE64D-220E-4A2B-804A-65D0222C634DQ27667518-AA9458AF-1257-45C0-8763-AEA650121832Q27678054-39593514-B5F6-4733-A0BF-EC81AC4172D4Q27679887-1310CACC-4B1F-42CA-9880-F53ACA8A6C21Q33655000-A9E84DBB-D64A-45CE-8DC7-F317531EE36FQ33730552-90A1E867-5F6D-46CD-822D-E63CBA140BB8Q34256694-ED7ECB44-6AF2-49D4-9100-FDA2AA770A7CQ34301305-63F3AAA9-3054-42D0-B4DE-D02DB6862A7DQ35055616-311A6FCA-256F-423F-B65C-584D03EC6495Q36249794-F435300F-52BB-42F9-8C43-39C7C341249EQ37633306-EC882460-BF65-42DC-B168-6BE529BEE4C0Q38190600-33200009-2AAF-4190-834A-DEF6E5E9D2D9Q38205711-50327FB1-EB1F-4624-9B4A-5C9147E0AC11Q38550663-E8A4FFCC-85D9-4ECA-A791-ABF45DF32E3FQ38776237-38E6C8A4-C12A-4E33-8C28-2F0ACECF3441Q38829940-F1F8D8CA-2AD1-4538-82FA-B529CCD38C2AQ39167574-550E3C39-65C1-4B05-BBAA-655D409C695DQ41020852-470F8469-EE6F-458C-9B0F-03CD2E60F527Q42907375-0635CC70-0701-4FAB-9492-A4BC5D0107E5Q43166286-8B8A2F06-A41B-4218-9E3A-09181C8CA609Q44507191-80E6834B-7A2D-4B5F-9304-C37C1AADFF51Q46045515-E48826B7-8CF6-43EE-88AD-79946A59BCE5Q46285009-C1F5A1C5-A083-45B8-9B31-A3FDCC2EF509Q47195471-454611FA-9D38-430E-A6DD-681F1623CFA8Q48045537-2B4FA83D-DAA8-4FE4-B795-1E58BD7D4C3AQ50458476-55950287-E81A-433A-950A-79648C32A7ACQ51052235-C6085584-D7F2-4405-9FB6-D0C9FEA79890Q51771081-2E0FC9EE-C5CF-4424-B3B7-07F8BD11A88CQ53627818-CB509640-69C0-4C0E-B091-4C7A37A8F9C5Q55005413-9BED2FDB-4B38-4C5C-BE55-4DBDC26E46B4
P2860
Crystal Structure of Plant Ferritin Reveals a Novel Metal Binding Site That Functions as a Transit Site for Metal Transfer in Ferritin
description
2010 nî lūn-bûn
@nan
2010 թուականի Փետրուարին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի փետրվարին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
name
Crystal Structure of Plant Fer ...... for Metal Transfer in Ferritin
@ast
Crystal Structure of Plant Fer ...... for Metal Transfer in Ferritin
@en
Crystal Structure of Plant Fer ...... for Metal Transfer in Ferritin
@nl
type
label
Crystal Structure of Plant Fer ...... for Metal Transfer in Ferritin
@ast
Crystal Structure of Plant Fer ...... for Metal Transfer in Ferritin
@en
Crystal Structure of Plant Fer ...... for Metal Transfer in Ferritin
@nl
prefLabel
Crystal Structure of Plant Fer ...... for Metal Transfer in Ferritin
@ast
Crystal Structure of Plant Fer ...... for Metal Transfer in Ferritin
@en
Crystal Structure of Plant Fer ...... for Metal Transfer in Ferritin
@nl
P2093
P2860
P356
P1476
Crystal Structure of Plant Fer ...... for Metal Transfer in Ferritin
@en
P2093
Fumiyuki Goto
Taro Masuda
Toshihiro Yoshihara
P2860
P304
P356
10.1074/JBC.M109.059790
P407
P50
P577
2010-02-05T00:00:00Z