Zak McIver scite author profile

Zak McIver

5Publications

121Citation Statements Received

340Citation Statements Given

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Conservation of the structural and functional architecture of encapsulated ferritins in bacteria and archaea

Piergentili

Ross

et al. 2019

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Ferritins are a large family of intracellular proteins that protect the cell from oxidative stress by catalytically converting Fe(II) into less toxic Fe(III) and storing iron minerals within their core. Encapsulated ferritins (EncFtn) are a sub-family of ferritin-like proteins, which are widely distributed in all bacterial and archaeal phyla. The recently characterized Rhodospirillum rubrum EncFtn displays an unusual structure when compared with classical ferritins, with an open decameric structure that is enzymatically active, but unable to store iron. This EncFtn must be associated with an encapsulin nanocage in order to act as an iron store. Given the wide distribution of the EncFtn family in organisms with diverse environmental niches, a question arises as to whether this unusual structure is conserved across the family. Here, we characterize EncFtn proteins from the halophile Haliangium ochraceum and the thermophile Pyrococcus furiosus, which show the conserved annular pentamer of dimers topology. Key structural differences are apparent between the homologues, particularly in the centre of the ring and the secondary metal-binding site, which is not conserved across the homologues. Solution and native mass spectrometry analyses highlight that the stability of the protein quaternary structure differs between EncFtn proteins from different species. The ferroxidase activity of EncFtn proteins was confirmed, and we show that while the quaternary structure around the ferroxidase centre is distinct from classical ferritins, the ferroxidase activity is still inhibited by Zn(II). Our results highlight the common structural organization and activity of EncFtn proteins, despite diverse host environments and contexts within encapsulins.

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Pore dynamics and asymmetric cargo loading in an encapsulin nanocompartment

et al. 2022

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Encapsulins are protein nanocompartments that house various cargo enzymes, including a family of decameric ferritin-like proteins. Here, we study a recombinant Haliangium ochraceum encapsulin:encapsulated ferritin complex using cryo–electron microscopy and hydrogen/deuterium exchange mass spectrometry to gain insight into the structural relationship between the encapsulin shell and its protein cargo. An asymmetric single-particle reconstruction reveals four encapsulated ferritin decamers in a tetrahedral arrangement within the encapsulin nanocompartment. This leads to a symmetry mismatch between the protein cargo and the icosahedral encapsulin shell. The encapsulated ferritin decamers are offset from the interior face of the encapsulin shell. Using hydrogen/deuterium exchange mass spectrometry, we observed the dynamic behavior of the major fivefold pore in the encapsulin shell and show the pore opening via the movement of the encapsulin A-domain. These data will accelerate efforts to engineer the encapsulation of heterologous cargo proteins and to alter the permeability of the encapsulin shell via pore modifications.

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Conservation of the structural and functional architecture of encapsulated ferritins in bacteria and archaea

Piergentili

Ross

et al. 2018

Preprint

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+44(0)191 208 4855, Jon.marles-wright1@ncl.ac.uk; David J. Clarke, +44(0)131 650 4808, Dave.clarke@ed.ac.uk. ABSTRACT Iron is an essential element for many biological processes; however, due to its high reactivity iron can also be very toxic, producing reactive oxygen species through Fenton chemistry. Ferritins protect the cell from oxidative stress by catalytically converting Fe(II) into less toxic Fe(III) and storing the resulting iron minerals within their core. Encapsulated ferritins (EncFtn) are a sub-family of ferritin-like proteins, which are widely distributed in all bacterial and archaeal phyla. We recently characterised the Rhodospirillum rubrum EncFtn, showing that although enzymatically active, due to its open structure it requires the association with an encapsulin nanocage in order to act as an iron store. Given the wide distribution of the EncFtn family in organisms with diverse environmental niches, a question arises as to whether the structure and catalytic activity is conserved across the family. Here we structurally characterise two EncFtn members from the halophile Haliangium ochraceum and the thermophile Pyrococcus furiosus, which show the same distinct annular decamer topology observed in R. rubrum EncFtn, with the ferroxidase centre (FOC) formed between one of the dimer interfaces. Solution and native mass

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Pore dynamics and asymmetric cargo loading in an encapsulin nanocompartment

Ross

McIver

Lambert

et al. 2021

Preprint

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Encapsulins (Enc) are protein nanocompartments which house various cargo enzymes, including a family of decameric ferritin-like proteins. Previously, we elucidated the structure and activity of these ferritin-like proteins (EncFtn) and demonstrated that they must be encapsulated in a nanocompartment for iron storage. Here, we study a recombinant Haliangium ochraceum Enc:EncFtn complex using electron cryo-microscopy (Cryo-EM) and hydrogen/deuterium exchange mass spectrometry (HDX-MS) to gain insight into the structural relationship between Enc and EncFtn. An asymmetric single particle reconstruction reveals four EncFtn decamers in a tetrahedral arrangement within the encapsulin nanocompartment. This leads to a symmetry mismatch between the EncFtn cargo and the icosahedral encapsulin shell. The EncFtn decamers are offset from the interior face of the encapsulin shell and are resolved at a much lower overall resolution in the final reconstruction. This flexibility, and the fixed number of EncFtn decamers sequestered within, implies that the loading of the encapsulin nanocompartment is limited by the steric effect of both engaged and free encapsulin localization sequences. Using a combination of focused refinements and HDX-MS, we observed dynamic behavior of the major five-fold pore, and show the pore opening via the movement of the encapsulin A-domain. These data can accelerate efforts to engineer the sequestration of heterologous cargo proteins and to alter the permeability of the encapsulin shell via pore modifications.

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Cryo-EM and single-particle analysis reveals pore dynamics and asymmetric cargo loading in an encapsulin nanocompartment.

McIver¹

2021

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Zak McIver

Conservation of the structural and functional architecture of encapsulated ferritins in bacteria and archaea

Pore dynamics and asymmetric cargo loading in an encapsulin nanocompartment

Conservation of the structural and functional architecture of encapsulated ferritins in bacteria and archaea

Pore dynamics and asymmetric cargo loading in an encapsulin nanocompartment

Cryo-EM and single-particle analysis reveals pore dynamics and asymmetric cargo loading in an encapsulin nanocompartment.

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