Redox Properties of Human Transferrin Bound to Its Receptor

Dhungana, Suraj; Taboy, Céline H.; Zak, Olga; Larvie, Mykol; Crumbliss, and Alvin L.; Aisen, Philip

doi:10.1021/bi0353631

Cited by 74 publications

(83 citation statements)

References 23 publications

(39 reference statements)

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“…because the reduction potential of the iron is more within a range where intracellular reductants can drive the reaction when Fe 3? is associated with Tf-TfR1 [9]. Unless the sequence is as now suggested, there is a need to find a physiological reductant although proof that reduction occurs when the iron is still associated with Tf-TfR1 remains to be supplied.…”

Section: The Tf Cycle: Iron Trafficking Into Erythroid Cells As Well mentioning

confidence: 98%

Human iron transporters

Garrick

2010

Genes Nutr

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Human iron transporters manage iron carefully because tissues need iron for critical functions, but too much iron increases the risk of reactive oxygen species. Iron acquisition occurs in the duodenum via divalent metal transporter (DMT1) and ferroportin. Iron trafficking depends largely on the transferrin cycle. Nevertheless, nondigestive tissues have a variety of other iron transporters that may render DMT1 modestly redundant, and DMT1 levels exceed those needed for the just-mentioned tasks. This review begins to consider why and also describes advances after 2008 that begin to address this challenge.

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Section: The Tf Cycle: Iron Trafficking Into Erythroid Cells As Well mentioning

confidence: 98%

Human iron transporters

Garrick

2010

Genes Nutr

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“…The endosomal ferrireductase STEAP3 (six-transmembrane epithelial antigen of the prostate 3) reduces the liberated Fe 3ϩ to Fe 2ϩ (39), which is subsequently transported into the cytosol via DMT1 (9,40). Although it is generally accepted that endosomal Fe 3ϩ is reduced after it is released from transferrin, thermodynamic and kinetic considerations suggest that reduction occurs (via STEAP3 or otherwise) while Fe 3ϩ is still bound to transferrin (41). Interestingly, mice deficient in either STEAP3 or DMT1 (in the hematopoietic compartment) become anemic, but hemoglobin levels can be maintained at ϳ8 g/dl (10, 39), suggesting that erythrocyte precursors may have alternative, although less efficient, means of endosomal ferrireduction and iron transport.…”

Section: Iron Metabolism In Erythrocyte Precursorsmentioning

confidence: 99%

Iron transport proteins: Gateways of cellular and systemic iron homeostasis

Knutson

2017

Journal of Biological Chemistry

106

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Edited by F. Peter GuengerichCellular iron homeostasis is maintained by iron and heme transport proteins that work in concert with ferrireductases, ferroxidases, and chaperones to direct the movement of iron into, within, and out of cells. Systemic iron homeostasis is regulated by the liver-derived peptide hormone, hepcidin. The interface between cellular and systemic iron homeostasis is readily observed in the highly dynamic iron handling of four main cell types: duodenal enterocytes, erythrocyte precursors, macrophages, and hepatocytes. This review provides an overview of how these cell types handle iron, highlighting how iron and heme transporters mediate the exchange and distribution of body iron in health and disease.

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“…Abbreviations 6 , tetra-n-butylamonium hexafluorophosphate; ESI-MS, electrospray ionization mass spectrometry; CV, cyclic voltammetry; IR, infrared spectroscopy; EPR, electron paramagnetic resonance spectroscopy; SCE, standard calomel electrode; Fc, ferrocene; Fc + , ferrocenium ion; NHE, normal hydrogen electrode.…”

Section: Methodsmentioning

confidence: 99%

“…This then leaves the endosome via a membrane metal ion transporter (DMT). 6 In order to better understand this process, the full characterization of transferrins is of fundamental importance. The structures of human lactoferrin, 7 serum transferrin, 8,9 and duck ovotransferrin 10 have all been well studied using X-ray crystallography and are quite similar.…”

Section: Introductionmentioning

confidence: 99%

“…However, it has recently been demonstrated that the interaction of the Fe III -Tf complex with the membrane transferrin receptor (TfR) raises the potential by more than 200 mV, explaining the Fe III →Fe II reduction in physiological medium. 6 Based on these studies, several articles have been published reporting Fe III complexes with phenolate-and pyridine/imidazole-containing ligands as models for Fe- Figure 1. Graphic representation of the active site of human lactoferrin based on coordinates from the PDB file from reference 9 (1D3K).…”

Section: Introductionmentioning

confidence: 99%

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EPR and semi-empirical studies as tools to assign the geometric structures of FeIII isomer models for transferrins

Scarpellini¹,

Casellato²,

Bortoluzzi³

et al. 2006

J. Braz. Chem. Soc.

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A reação entre Fe(ClO 4 ) 3 . nH 2 O e N,N'-bis[(2-hidroxibenzil)-N,N'-bis(1-metilimidazol-2-ilmetil)]etilenodiamina (H 2 bbimen) resulta na formação de dois isômeros geométricos, A e B, do cátion complexo [Fe(bbimen)] + , os quais foram isolados e caracterizados por espectroscopia na região do infravermelho e UV-visível, espectrometria de massas, medidas de condutividade molar, voltametria cíclica, espectroeletroquímica e espectroscopia de ressonância paramagnética eletrônica (RPE). A geometria de um desses isômeros foi claramente demonstrada por análise cristalográfica de raios X de monocristal. O composto cristaliza no sistema monoclínico, grupo espacial P2 1 /c, a = 14,104 (3), b = 15,626 (3), c = 13,291 (3) Å, β = 98,07 (3) o , Z = 4, R 1 = 6,35% e wR 2 = 20,57%. As propriedades eletroquímicas do cátion [Fe(bbimen)] + (-0,58 V versus NHE) são bastante similares às das transferrinas (-0,52 V versus NHE), indicando que o complexo é um bom modelo para as propriedades redox daquelas metaloenzimas. A espectroscopia de RPE foi a única técnica espectroscópica capaz de diferenciar os dois isômeros isolados (A e B). Os estudos de RPE revelaram que o isômero A trata-se de um complexo de Fe III spin alto distorcido rombicamente (E/D ≅ 0,33) e apresenta um espectro caracterizado por uma linha estreita em g 1 ≅ 4,1 e outra larga em g 2 ≅ 9,0. O espectro de RPE do isômero B apresenta, além das linhas em g 1 ≅ 4,2 e em g 2 ≅ 9,0, um conjunto de linhas em g 1 ≅ 3,0, g 2 ≅ 3,6 e g 3 ≅ 5,1, que têm sido atribuídas a complexos de Fe III com simetria tendendo à axial (E/ D ≅ 0,22). Estudos teóricos empregando cálculos semi-empíricos, combinados com os dados de RPE, foram essenciais para a atribuição das estruturas geométricas dos isômeros A e B.The reaction of Fe(ClO 4 ) 3 . nH 2 O with N,N'-bis[(2-hydroxybenzyl)-N,N'-bis(1-methylimidazole-2-yl-methyl)]ethylenediamine (H 2 bbimen) affords two geometric isomers, A and B, of the complex cation [Fe(bbimen)] + , which were fully characterized by IR and UV-visible spectroscopies, ESI mass spectrometry, molar conductivity measurements, cyclic voltammetry, spectroelectrochemistry and EPR spectroscopy. The geometry of one of these isomers has been clearly demonstrated through X-ray crystallographic analysis. It crystallizes in the monoclinic system, space group P2 1 /c, a = 14.104 (3), b = 15.626 (3), c = 13.291 (3) Å, β = 98.07 (3) o , Z = 4, R 1 = 6.35% and wR 2 = 20.57%. The electrochemical properties of [Fe(bbimen)] + are quite similar to those of transferrins (-0.52 V versus NHE) and indicate that it is a good model for the redox potential of these metalloenzymes. EPR spectroscopy was the only spectroscopic technique able to differentiate the isolated isomers A and B. EPR studies revealed that isomer A is better described as a rhombically distorted (E/D ≅ 0.33) highspin Fe III complex (g 1 ≅ 4.1 with a shoulder at g 2 ≅ 9.0), while the spectrum of B has a set of lines at g 1 ≅ 3.0, g 2 ≅ 3.6 and g 3 ≅ 5.1, in addition to the line at g 1 ≅ 4.2 and a shoulder at g 2 ≅ 9.0, which h...

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Redox Properties of Human Transferrin Bound to Its Receptor

Cited by 74 publications

References 23 publications

Human iron transporters

Human iron transporters

Iron transport proteins: Gateways of cellular and systemic iron homeostasis

EPR and semi-empirical studies as tools to assign the geometric structures of FeIII isomer models for transferrins

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