The release of iron from horse spleen ferritin by reduced flavins

Sirivech, Somjai; Frieden, Earl; Osaki, Shigemasa

doi:10.1042/bj1430311

Cited by 170 publications

(98 citation statements)

References 13 publications

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“…The most effective mobilising agent is cysteine, followed by ascorbic acid; glutathione is a very poor reductant of ferritin iron. This is in agreement with earlier results of Mazur et al [7] and Sirivech et al [3]. Yet at concentrations of 5 mM mobilisation of only 12-I 5% of the iron content is obtained in 24 hr at room temperature.…”

Section: Resultssupporting

confidence: 94%

“…It does not seem likely that such reducing agents or complexants play a major role in ferritin mobilisation in vivo. By comparison, with FMNHz reduction of ferritin iron is extremely rapid (R. R. Crichton, M. Wauters and F. Roman unpublished work and [3]) 100% of the iron being reduced by 0.2 mM FMNHz in 10 min [3]. The effect of addition of chelating agents together with reducing agents did not increase the rate of iron release appreciably.…”

Section: Resultsmentioning

confidence: 95%

“…The iron can be released by reduction, for example with sodium dithionite [l] or with thioglycolate [ 21. In the cell ferritin iron seems likely to be mobilised by a reductive system, which may involve FMNHz [3]. It is of interest to establish the nature of the biological reductant which is involved in iron release from ferritin and to analyse the effect of the iron content of the molecule on the rate of iron release.…”

Section: Introductionmentioning

confidence: 99%

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Mobilisation of iron from ferritin fractions of defined iron content by biological reductants

Dognin

Crichton

1975

FEBS Letters

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Section: Resultssupporting

confidence: 94%

Section: Resultsmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

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Mobilisation of iron from ferritin fractions of defined iron content by biological reductants

Dognin

Crichton

1975

FEBS Letters

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“…100 mM [13]. We can observe a more rapid phase at the beginning followed by a phase of slower mobilisation rate (Fig.…”

Section: Reducedjlavin Mononucleotidrmentioning

confidence: 72%

“…However, the effectiveness strongly varies with the reagent used. Cysteine and glutathione, for example, give poor mobilisation rates [13], while a faster mobilisation is observed with thioglycollic acid as used for the formation of apoferritin from ferritin [35]. This order of reactivities is not compatible with a predominant dependence of reduction rates on the redox potential since the thiol-disulfide couples involving cysteine and glutathione have lower potentials (Eb = -0.34 V) than thioglycollic acid (Eb = -0.14 V) [36].…”

Section: Iron Release By Fmnh2mentioning

confidence: 99%

Reductive mobilisation of ferritin iron

et al. 1985

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The reductive mobilisation of iron from ferritin, the principal protein of iron storage, was studied. The kinetic characteristics of iron release by dithionite, thioglycollate, and dihydroriboflavin 5'-phosphate (FMNH,) were found to differ widely. The dependence on pH is most pronounced for the dithionite reduction which proceeds 100 times faster at pH 4 than at pH 7. The experimental data can be consistently explained in terms of specific interactions of products or educts with interfacial iron(II1) hydroxide of the ferritin core. Surface complexes with the product sulfite are postulated in the dithionite reaction, and with the educt in the thioglycollate reaction. Iron(I1) complexes with the radical anion FMN' are suggested to be involved in the iron release by FMNH?. The mobilisation of iron by a series of thiols of different size and coordinative properties confirmed the importance of surface complex formation. N o evidence was found for predominant effects of hindered shell penetration.Ferritin, as an iron storage protein, is a key molecule in iron metabolism. It maintains iron in a form from which it can easily be mobilised as and where it is required. Although the amino acid sequences of many ferritins are known [ I -51 and the three-dimensional structure of horse spleen ferritin has bccn solved at 0.28-nm resolution [6], the mechanisms of ferritin iron deposition and mobilisation are not yet really understood.

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Intracellular free flavin and its associated enzymes participate in oxygen and iron metabolism in Amphibacillus xylanus lacking a respiratory chain

et al. 2018

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Amphibacillus xylanus is a recently identified bacterium which grows well under both aerobic and anaerobic conditions and may prove useful for biomass utilization. Amphibacillus xylanus, despite lacking a respiratory chain, consumes oxygen at a similar rate to Escherichia coli (130–140 μmol oxygen·min −1 ·g −1 dry cells at 37 °C), suggesting that it has an alternative system that uses a large amount of oxygen. Amphibacillus xylanus NADH oxidase (Nox) was previously reported to rapidly reduce molecular oxygen content in the presence of exogenously added free flavin. Here, we established a quantitative method for determining the intracellular concentrations of free flavins in A. xylanus , involving French pressure and ultrafiltration membranes. The intracellular concentrations of flavin adenine dinucleotide ( FAD ), flavin mononucleotide ( FMN ), and riboflavin were estimated to be approximately 8, 3, and 1 μ m , respectively. In the presence of FAD , the predominant free flavin species, two flavoproteins Nox (which binds FAD ) and NAD (P)H oxidoreductase (Npo, which binds FMN ), were identified as central free flavin‐associated enzymes in the oxygen metabolic pathway. Under 8 μ m free FAD , the catalytic efficiency ( k cat / K m ) of recombinant Nox and Npo for oxygen increased by approximately fivefold and ninefold, respectively. Nox and Npo levels were increased, and intracellular FAD formation was stimulated following exposure of A. xylanus to oxygen. This suggests that these two enzymes and free FAD contribute to effective oxygen detoxification and NAD (P) + regeneration to maintain redox balance during aerobic growth. Furthermore, A. xylanus required iron to grow aerobically. We also discuss the contribution of the free flavin‐associated system to the process of iron utilization.

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The release of iron from horse spleen ferritin by reduced flavins

Cited by 170 publications

References 13 publications

Mobilisation of iron from ferritin fractions of defined iron content by biological reductants

Mobilisation of iron from ferritin fractions of defined iron content by biological reductants

Reductive mobilisation of ferritin iron

Intracellular free flavin and its associated enzymes participate in oxygen and iron metabolism in Amphibacillus xylanus lacking a respiratory chain

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