Iron Oxidation in Escherichia coli Bacterioferritin Ferroxidase Centre, a Site Designed to React Rapidly with H2O2 but Slowly with O2

Pullin, Jacob; Wilson, Michael T.; Clémancey, Martin; Blondin, Geneviève; Bradley, Justin M.; Moore, Geoffrey R.; Brun, Nick E. Le; Lučić, Marina; Worrall, J.A.R.; Svistunenko, Dimitri A.

doi:10.1002/anie.202015964

“…19−21 However, on the one hand, monitoring H 2 O 2 released from cells is challenging due to its rapid diffusion, self-transformation, and dilution to ultralow concentration in the cellular microenvironment. 7,22 On the other hand, it is difficult to detect molecules with low Raman scattering cross-sections or with poor affinity to the SERS-active substrates. 18,23 These problems severely limit the application of SERS in H 2 O 2 detection.…”

Section: ■ Introductionmentioning

confidence: 99%

In Situ Monitoring of Hydrogen Peroxide Released from Living Cells Using a ZIF-8-Based Surface-Enhanced Raman Scattering Sensor

Jiang

¹

,

He

²

,

Chen

³

et al. 2021

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Hydrogen peroxide (H2O2) widely involves in intracellular and intercellular redox signaling pathways, playing a vital role in regulating various physiological events. Nevertheless, current analytical methods for the H2O2 assay are often hindered by relatively long response time, low sensitivity, or self-interference. Herein, a zeolitic imidazolate framework-8 (ZIF-8)-based surface-enhanced Raman scattering (SERS) sensor has been developed to detect H2O2 released from living cells by depositing ZIF-8 over SERS active gold nanoparticles (AuNPs) grafted with H2O2-responsive probe molecules, 2-mercaptohydroquinone. Combining the superior fingerprint identification of SERS and the highly efficient enrichment and selective response of H2O2 by ZIF, the ZIF-8-based SERS sensor exhibits a high anti-interference ability for H2O2 detection, with a limit of detection as low as 0.357 nM. Satisfyingly, owing to the enhanced catalytic activity derived from the successful integration of AuNPs and ZIF, the response time as short as 1 min can be obtained, demonstrating the effectiveness of the SERS sensor for rapid H2O2 detection. Furthermore, the developed SERS sensor enables real-time detection of H2O2 secreted from living cells under phorbol myristate acetate stimulation, as cells can be cultured on-chip. This study will pave the way toward the development of a metal–organic framework-based SERS platform for application in the fields of biosensing and early disease diagnosis associated with H2O2 secretion, thus exhibiting promising potential for future therapies.

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“…[22] The observation that heme is seemingly unimportant for the rate at which Bfr is able to oxidise and mineralise iron [23] led to the proposal that the ferroxidase centres and hemes function as two independent cofactors involved in iron uptake and iron release, respectively. Under oxidative stress or iron-replete conditions the Bfr ferroxidase centre couples oxidation of Fe 2 + to the reduction of an external electron acceptor, most likely peroxide, [24] performing the dual roles of consuming ROS and converting the potentially toxic Fe 2 + into a chemically inert ferric mineral solubilized within the protein coat. Under low-iron conditions the heme cycles oxidation state by accepting electrons from reduced Bfd and passing them to the mineral core, mobilising the iron by reducing it to Fe 2 + , leading to release into the cytoplasm.…”

Section: Introductionmentioning

confidence: 99%

The Ferroxidase Centre of Escherichia coli Bacterioferritin Plays a Key Role in the Reductive Mobilisation of the Mineral Iron Core

Bradley,

Bugg,

Sackey

et al. 2024

Angewandte Chemie

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0

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Ferritins are multimeric cage‐forming proteins that play a crucial role in cellular iron homeostasis. All H‐chain‐type ferritins harbour a diiron site, the ferroxidase centre, at the centre of a 4 α–helical bundle, but bacterioferritins are unique in also binding 12 hemes per 24meric assembly. The ferroxidase centre is known to be required for the rapid oxidation of Fe2+ during deposition of an immobilised ferric mineral core within the protein’s hollow interior. In contrast, the heme of bacterioferritin is required for the efficient reduction of the mineral core during iron release, but has little effect on the rate of either oxidation or mineralisation of iron. Thus, the current view is that these two cofactors function in iron uptake and release, respectively, with no functional overlap. However, rapid electron transfer between the heme and ferroxidase centre of bacterioferritin from Escherichia coli was recently demonstrated, suggesting that the two cofactors may be functionally connected. Here we report absorbance and (magnetic) circular dichroism spectroscopies, together with in vitro assays of iron‐release kinetics, which demonstrate that the ferroxidase centre plays an important role in the reductive mobilisation of the bacterioferritin mineral core, which is dependent on the heme‐ferroxidase centre electron transfer pathway.

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“…The observation that heme is seemingly unimportant for the rate at which Bfr is able to oxidise and mineralise iron [23] led to the proposal that the ferroxidase centres and hemes function as two independent cofactors involved in iron uptake and iron release, respectively. Under oxidative stress or iron‐replete conditions the Bfr ferroxidase centre couples oxidation of Fe 2+ to the reduction of an external electron acceptor, most likely peroxide, [24] performing the dual roles of consuming ROS and converting the potentially toxic Fe 2+ into a chemically inert ferric mineral solubilized within the protein coat. Under low‐iron conditions the heme cycles oxidation state by accepting electrons from reduced Bfd and passing them to the mineral core, mobilising the iron by reducing it to Fe 2+ , leading to release into the cytoplasm [20] …”

Section: Introductionmentioning

confidence: 99%

The Ferroxidase Centre of Escherichia coli Bacterioferritin Plays a Key Role in the Reductive Mobilisation of the Mineral Iron Core

Bradley,

Bugg,

Sackey

et al. 2024

Angew Chem Int Ed

Self Cite

1

0

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Ferritins are multimeric cage‐forming proteins that play a crucial role in cellular iron homeostasis. All H‐chain‐type ferritins harbour a diiron site, the ferroxidase centre, at the centre of a 4 α–helical bundle, but bacterioferritins are unique in also binding 12 hemes per 24meric assembly. The ferroxidase centre is known to be required for the rapid oxidation of Fe2+ during deposition of an immobilised ferric mineral core within the protein’s hollow interior. In contrast, the heme of bacterioferritin is required for the efficient reduction of the mineral core during iron release, but has little effect on the rate of either oxidation or mineralisation of iron. Thus, the current view is that these two cofactors function in iron uptake and release, respectively, with no functional overlap. However, rapid electron transfer between the heme and ferroxidase centre of bacterioferritin from Escherichia coli was recently demonstrated, suggesting that the two cofactors may be functionally connected. Here we report absorbance and (magnetic) circular dichroism spectroscopies, together with in vitro assays of iron‐release kinetics, which demonstrate that the ferroxidase centre plays an important role in the reductive mobilisation of the bacterioferritin mineral core, which is dependent on the heme‐ferroxidase centre electron transfer pathway.

show abstract

Iron Oxidation in Escherichia coli Bacterioferritin Ferroxidase Centre, a Site Designed to React Rapidly with H₂O₂ but Slowly with O₂

Cited by 18 publications

References 59 publications

In Situ Monitoring of Hydrogen Peroxide Released from Living Cells Using a ZIF-8-Based Surface-Enhanced Raman Scattering Sensor

In Situ Monitoring of Hydrogen Peroxide Released from Living Cells Using a ZIF-8-Based Surface-Enhanced Raman Scattering Sensor

The Ferroxidase Centre of Escherichia coli Bacterioferritin Plays a Key Role in the Reductive Mobilisation of the Mineral Iron Core

The Ferroxidase Centre of Escherichia coli Bacterioferritin Plays a Key Role in the Reductive Mobilisation of the Mineral Iron Core

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