Morphology and Magnetic Structure of the Ferritin Core during Iron Loading and Release by Magnetooptical and NMR Methods

Koralewski, M.; Balejčíková, Lucia; Mitróová, Z.; Pochylski, Mikołaj; Baranowski, Mikołaj; Kopčanský, P.

doi:10.1021/acsami.7b18304

Cited by 26 publications

(16 citation statements)

References 64 publications

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“…Interestingly, the iron oxide NPs inside E2-LFtn are dominated by Fe II rather than Fe III ions as reported for ferritin. 54,55 This observation suggests that the iron mineralisation process in E2-LFtn differs from that of ferritin which could be related to the differences in cavity size and spatial arrangement of the M-ferritin mimicking catalytic sites. 22 The ratio of the peak areas (R I = Fe II /Fe III ) for 3000Fe E2-LFtn decreases with decreasing T from 1.25 at 300 K to 0.50 at 120 K (Fig.…”

Section: Characterisation Of Iron Oxide Nps Inside E2-lftnmentioning

confidence: 95%

Switching of the mechanism of charge transport induced by phase transitions in tunnel junctions with large biomolecular cages

et al. 2021

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Section: Characterisation Of Iron Oxide Nps Inside E2-lftnmentioning

confidence: 95%

Switching of the mechanism of charge transport induced by phase transitions in tunnel junctions with large biomolecular cages

et al. 2021

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“…So far, side-chain conformational changes in the amino acid that interacts with Au +3 or Au 0 have been reported [28,51]. In addition, different authors have reported the conservation of the secondary structures of ferritin after iron incorporation to produce magnetoferritin, therefore maintaining the almost intact protein cage after iron mineralization [56][57][58][59]. Identical results were reported by Xiangyou Lui et al, revealing that ferritin with Pt nanoparticles does not have significant changes in the secondary structures of the protein, markedly α-helical [60].…”

Section: Gold Nanoparticles Synthesis and Characterizationmentioning

confidence: 99%

Enhanced Cellular Uptake of H-Chain Human Ferritin Containing Gold Nanoparticles

et al. 2021

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Gold nanoparticles (AuNP) capped with biocompatible layers have functional optical, chemical, and biological properties as theranostic agents in biomedicine. The ferritin protein containing in situ synthesized AuNPs has been successfully used as an effective and completely biocompatible nanocarrier for AuNPs in human cell lines and animal experiments in vivo. Ferritin can be uptaken by different cell types through receptor-mediated endocytosis. Despite these advantages, few efforts have been made to evaluate the toxicity and cellular internalization of AuNP-containing ferritin nanocages. In this work, we study the potential of human heavy-chain (H) and light-chain (L) ferritin homopolymers as nanoreactors to synthesize AuNPs and their cytotoxicity and cellular uptake in different cell lines. The results show very low toxicity of ferritin-encapsulated AuNPs on different human cell lines and demonstrate that efficient cellular ferritin uptake depends on the specific H or L protein chains forming the ferritin protein cage and the presence or absence of metallic cargo. Cargo-devoid apoferritin is poorly internalized in all cell lines, and the highest ferritin uptake was achieved with AuNP-loaded H-ferritin homopolymers in transferrin-receptor-rich cell lines, showing more than seven times more uptake than apoferritin.

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“…In case of the ferritin protein, the CD spectrum showed bands at 222 nm (ellipticity: -42.9 ± 5.7 mdeg), 203.9 nm (ellipticity: -24.3 ± 11 mdeg) and 197.9 nm (ellipticity: 8.2 ± 3 mdeg) (Fig 1B, black curve). The shape of the curve and magnitude of these far UV-CD bands suggest that ferritin protein has a substantial helical content and the polypeptide chains exist in an ordered structure [48,49]. For the protease-treated holoferritin, the bands observed at 222.1 nm, 202.8 nm and 198 nm (Fig 1B , red curve) indicate minimal shift in the band positions, although the ellipticity values, i.e., -30.7 ± 0.8 mdeg, -28.7 ± 2 mdeg and 14.6 ± 9 mdeg for the bands at 222.1 nm, 202.8 nm and 198 nm, respectively, are significantly altered.…”

Section: Plos Onementioning

confidence: 99%

How stable are the collagen and ferritin proteins for application in bioelectronics?

Kolay

Bera

2021

PLoS ONE

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One major obstacle in development of biomolecular electronics is the loss of function of biomolecules upon their surface-integration and storage. Although a number of reports on solid-state electron transport capacity of proteins have been made, no study on whether their functional integrity is preserved upon surface-confinement and storage over a long period of time (few months) has been reported. We have investigated two specific cases—collagen and ferritin proteins, since these proteins exhibit considerable potential as bioelectronic materials as we reported earlier. Since one of the major factors for protein degradation is the proteolytic action of protease, such studies were made under the action of protease, which was either added deliberately or perceived to have entered in the reaction vial from ambient environment. Since no significant change in the structural characteristics of these proteins took place, as observed in the circular dichroism and UV-visible spectrophotometry experiments, and the electron transport capacity was largely retained even upon direct protease exposure as revealed from the current sensing atomic force spectroscopy experiments, we propose that stable films can be formed using the collagen and ferritin proteins. The observed protease-resistance and robust nature of these two proteins support their potential application in bioelectronics.

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Morphology and Magnetic Structure of the Ferritin Core during Iron Loading and Release by Magnetooptical and NMR Methods

Cited by 26 publications

References 64 publications

Switching of the mechanism of charge transport induced by phase transitions in tunnel junctions with large biomolecular cages

Switching of the mechanism of charge transport induced by phase transitions in tunnel junctions with large biomolecular cages

Enhanced Cellular Uptake of H-Chain Human Ferritin Containing Gold Nanoparticles

How stable are the collagen and ferritin proteins for application in bioelectronics?

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