Helical ultrastructure of the L-ENA spore aggregation factor of a Bacillus paranthracis foodborne outbreak strain

Mike Sleutel; Ephrem Debebe Zegeye; Ann-Katrin Llarena; Brajabandhu Pradhan; Marcus Fislage; Kristin O'Sullivan; Nani Van Gerven; Marina Aspholm; Han Remaut

doi:10.1038/s41467-024-51804-w

Helical ultrastructure of the L-ENA spore aggregation factor of a Bacillus paranthracis foodborne outbreak strain

Mike Sleutel, Ephrem Debebe Zegeye, Ann-Katrin Llarena, Brajabandhu Pradhan, Marcus Fislage, Kristin O'Sullivan, Nani Van Gerven, Marina Aspholm, Han Remaut

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Abstract

In pathogenic Bacillota, spores can form an infectious particle and can take up a central role in the environmental persistence and dissemination of disease. A poorly understood aspect of spore-mediated infection is the fibrous structures or 'endospore appendages' (ENAs) that have been seen to decorate the spores of pathogenic Bacilli and Clostridia. Current methodological approaches are opening a window on these long enigmatic structures. Using cryoID, Alphafold modelling and genetic approaches we identify a sub-class of robust ENAs in a Bacillus paranthracis foodborne outbreak strain. We demonstrate that L-ENA are encoded by a rare three-gene cluster (ena3) that contains all components for the self-assembly of ladder-like protein nanofibers of stacked heptameric rings, their anchoring to the exosporium, and their termination in a trimeric 'ruffle' made of a complement C1Q-like BclA paralogue. The role of ENA fibers in spore-spore interaction and the distribution of L-ENA operon as mobile genetic elements in B. cereus s.l. strains suggest that L-ENA fibers may increase the survival, spread and virulence of these strains.

Original language	English
Article number	7514
Number of pages <span style="color:red"p> <font size="1.5"> ✽ </span> </font>	12
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-51804-w
Publication status	Published - 29 Aug 2024

Bibliographical note

Funding Information:
We thank Dirk Reiter at the VIB-VUB Facility for Bio Electron Cryogenic Microscopy (BECM) and Yohannes Beyene Mekonnen at NMBU for technical assistance. This work was funded by VIB, NMBU, EOS Excellence in Research Program by FWO through grant G0G0818N to H.R. and G043021N to M.S. M.A. recognizes the Grant from the Norwegian Research Council (NFR): 335029 - FORSKER22.

Publisher Copyright:
© The Author(s) 2024.

Keywords

Spores, Bacterial/ultrastructure
Bacillus/genetics
Bacterial Proteins/genetics
Foodborne Diseases/microbiology
Multigene Family
Disease Outbreaks
Cryoelectron Microscopy
Operon/genetics

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114924639Final published version, 4.14 MBLicence: CC BY-NC-ND

Cite this

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title = "Helical ultrastructure of the L-ENA spore aggregation factor of a Bacillus paranthracis foodborne outbreak strain",

abstract = "In pathogenic Bacillota, spores can form an infectious particle and can take up a central role in the environmental persistence and dissemination of disease. A poorly understood aspect of spore-mediated infection is the fibrous structures or 'endospore appendages' (ENAs) that have been seen to decorate the spores of pathogenic Bacilli and Clostridia. Current methodological approaches are opening a window on these long enigmatic structures. Using cryoID, Alphafold modelling and genetic approaches we identify a sub-class of robust ENAs in a Bacillus paranthracis foodborne outbreak strain. We demonstrate that L-ENA are encoded by a rare three-gene cluster (ena3) that contains all components for the self-assembly of ladder-like protein nanofibers of stacked heptameric rings, their anchoring to the exosporium, and their termination in a trimeric 'ruffle' made of a complement C1Q-like BclA paralogue. The role of ENA fibers in spore-spore interaction and the distribution of L-ENA operon as mobile genetic elements in B. cereus s.l. strains suggest that L-ENA fibers may increase the survival, spread and virulence of these strains.",

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note = "Funding Information: We thank Dirk Reiter at the VIB-VUB Facility for Bio Electron Cryogenic Microscopy (BECM) and Yohannes Beyene Mekonnen at NMBU for technical assistance. This work was funded by VIB, NMBU, EOS Excellence in Research Program by FWO through grant G0G0818N to H.R. and G043021N to M.S. M.A. recognizes the Grant from the Norwegian Research Council (NFR): 335029 - FORSKER22. Publisher Copyright: {\textcopyright} The Author(s) 2024.",

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Helical ultrastructure of the L-ENA spore aggregation factor of a Bacillus paranthracis foodborne outbreak strain. / Sleutel, Mike; Zegeye, Ephrem Debebe; Llarena, Ann-Katrin; Pradhan, Brajabandhu; Fislage, Marcus; O'Sullivan, Kristin; Van Gerven, Nani; Aspholm, Marina; Remaut, Han.

In: Nature Communications , Vol. 15, No. 1, 7514, 29.08.2024.

Research output: Contribution to journal › Article › peer-review

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T1 - Helical ultrastructure of the L-ENA spore aggregation factor of a Bacillus paranthracis foodborne outbreak strain

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AU - Pradhan, Brajabandhu

AU - Fislage, Marcus

AU - O'Sullivan, Kristin

AU - Van Gerven, Nani

AU - Aspholm, Marina

AU - Remaut, Han

N1 - Funding Information: We thank Dirk Reiter at the VIB-VUB Facility for Bio Electron Cryogenic Microscopy (BECM) and Yohannes Beyene Mekonnen at NMBU for technical assistance. This work was funded by VIB, NMBU, EOS Excellence in Research Program by FWO through grant G0G0818N to H.R. and G043021N to M.S. M.A. recognizes the Grant from the Norwegian Research Council (NFR): 335029 - FORSKER22. Publisher Copyright: © The Author(s) 2024.

PY - 2024/8/29

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N2 - In pathogenic Bacillota, spores can form an infectious particle and can take up a central role in the environmental persistence and dissemination of disease. A poorly understood aspect of spore-mediated infection is the fibrous structures or 'endospore appendages' (ENAs) that have been seen to decorate the spores of pathogenic Bacilli and Clostridia. Current methodological approaches are opening a window on these long enigmatic structures. Using cryoID, Alphafold modelling and genetic approaches we identify a sub-class of robust ENAs in a Bacillus paranthracis foodborne outbreak strain. We demonstrate that L-ENA are encoded by a rare three-gene cluster (ena3) that contains all components for the self-assembly of ladder-like protein nanofibers of stacked heptameric rings, their anchoring to the exosporium, and their termination in a trimeric 'ruffle' made of a complement C1Q-like BclA paralogue. The role of ENA fibers in spore-spore interaction and the distribution of L-ENA operon as mobile genetic elements in B. cereus s.l. strains suggest that L-ENA fibers may increase the survival, spread and virulence of these strains.

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KW - Bacillus/genetics

KW - Bacterial Proteins/genetics

KW - Foodborne Diseases/microbiology

KW - Multigene Family

KW - Disease Outbreaks

KW - Cryoelectron Microscopy

KW - Operon/genetics

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DO - 10.1038/s41467-024-51804-w

M3 - Article

C2 - 39209852

VL - 15

JO - Nature Communications

JF - Nature Communications

SN - 2041-1723

IS - 1

M1 - 7514

ER -

Helical ultrastructure of the L-ENA spore aggregation factor of a Bacillus paranthracis foodborne outbreak strain

Abstract

Bibliographical note

Keywords

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