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4. Chapter 4 - Electron cryotomography.

Author

Oikonomou, C. M., Swulius, M. T., Briegel, A., Beeby, M., Yao, Q., Chang, Y.-W., and Jensen, G. J.

Abstract

Electron cryotomography (ECT) delivers 3D images of native structures inside intact cells with resolution on the scale of large macromolecular complexes (~ 4 nm). It has proven to be an invaluable tool for interrogating the organization of bacterial cells and the structures of the nanomachines inside them. Here we present a brief introduction to the technique, a few examples of what we have learned by imaging bacterial cells with ECT over the last 15 years and a frank discussion of the relative advantages and limitations of the technique compared to some other popular imaging methods used in microbiology. [ABSTRACT FROM AUTHOR]

Published
2016
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5. Mortality associated with emergency abdominal surgery in the elderly.

Author

Arenal JJ and Bengoechea-Beeby M

Abstract

INTRODUCTION: Elderly patients with life-threatening abdominal disease are undergoing emergency surgery in increasing numbers, but emergency procedures generally are associated with increased morbidity and mortality. We carried out a retrospective and prospective study at a tertiary centre in Spain to analyze the factors contributing to death after emergency abdominal surgery in elderly patients and to determine whether there were differences in the death rate between those aged 70-79 years and those aged 80 years and older. METHODS: The study population comprised 710 patients aged 70 years or older who underwent emergency surgery for intra-abdominal disorders. Between 1986 and 1990, we reviewed the charts of 302 patients, and between 1991 and 1995, we collected prospective data on 408 patients. The patients were divided by age into 2 groups: group 1 - 364 patients aged 70-79 years; and group 2 - 346 patients aged 80 years or older. In the analysis, we considered patient age, sex, perioperative risk, the time between onset of symptoms and admission to hospital and between admission to hospital and surgery, diagnosis, type of operation, operative findings, morbidity, mortality and length of hospital stay. RESULTS: The overall mortality was 22% (19% in group 1 and 24% in group 2). Multiple regression analysis showed that American Society of Anesthesiologists (ASA) grading (p = 0.0001), interval from onset of symptoms to admission (p = 0.007), mesenteric infarction (p = 0.005), a defunctioning stoma and palliative bypass (p = 0.003) and nontherapeutic laparotomy (p = 0.0003) were predictive of death. CONCLUSIONS: Mortality in elderly patients operated on for an acute abdomen can be predicted by ASA grade (perioperative risk), delay in surgical treatment and conditions that permit only palliative surgery. Increasing age (70-79 yr or > or = 80 yr) does not affect mortality, morbidity or length of hospital stay. [ABSTRACT FROM AUTHOR]

Published
2003

12. Discovery of a Novel Inner Membrane-Associated Bacterial Structure Related to the Flagellar Type III Secretion System

Author

Kaplan, M., Oikonomou, C.M., Wood, C.R., Chreifi, G., Ghosal, D., Dobro, M.J., Yao, Q., Pal, R.R., Baidya, A.K., Liu, Y., Maggi, S., McDowall, A.W., Ben-Yehuda, S., Rosenshine, I., Briegel, A., Beeby, M., Chang, Y.W., Shaffer, C.L., Jensen, G.J., Galperin Michael Y., and Galperin Michael Y.

Subjects
Bacteria, Bacterial Proteins, Flagella, Type III Secretion Systems, Bacterial Structures, Molecular Biology, Microbiology
Abstract

The bacterial flagellar type III secretion system (fT3SS) is a suite of membrane-embedded and cytoplasmic proteins responsible for building the flagellar motility machinery. Homologous nonflagellar (NF-T3SS) proteins form the injectisome machinery that bacteria use to deliver effector proteins into eukaryotic cells, and other family members were recently reported to be involved in the formation of membrane nanotubes. Here, we describe a novel, evolutionarily widespread, hat-shaped structure embedded in the inner membranes of bacteria, of yet-unidentified function, that is present in species containing fT3SS. Mutant analysis suggests a relationship between this novel structure and the fT3SS, but not the NF-T3SS. While the function of this novel structure remains unknown, we hypothesize that either some of the fT3SS proteins assemble within the hat-like structure, perhaps including the fT3SS core complex, or that fT3SS components regulate other proteins that form part of this novel structure.

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15. Molecular model of a bacterial flagellar motor in situ reveals a "parts-list" of protein adaptations to increase torque.

Author

Drobnič T, Cohen EJ, Calcraft T, Alzheimer M, Froschauer K, Svensson S, Hoffmann WH, Singh N, Garg SG, Henderson L, Umrekar TR, Nans A, Ribardo D, Pedaci F, Nord AL, Hochberg GKA, Hendrixson DR, Sharma CM, Rosenthal PB, and Beeby M

Abstract

One hurdle to understanding how molecular machines work, and how they evolve, is our inability to see their structures in situ . Here we describe a minicell system that enables in situ cryogenic electron microscopy imaging and single particle analysis to investigate the structure of an iconic molecular machine, the bacterial flagellar motor, which spins a helical propeller for propulsion. We determine the structure of the high-torque Campylobacter jejuni motor in situ, including the subnanometre-resolution structure of the periplasmic scaffold, an adaptation essential to high torque. Our structure enables identification of new proteins, and interpretation with molecular models highlights origins of new components, reveals modifications of the conserved motor core, and explain how these structures both template a wider ring of motor proteins, and buttress the motor during swimming reversals. We also acquire insights into universal principles of flagellar torque generation. This approach is broadly applicable to other membrane-residing bacterial molecular machines complexes., Competing Interests: Declaration of Interests The authors declare no competing interests.

Published
2024
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16. Evolution of a large periplasmic disk in Campylobacterota flagella enables both efficient motility and autoagglutination.

Author

Cohen EJ, Drobnič T, Ribardo DA, Yoshioka A, Umrekar T, Guo X, Fernandez JJ, Brock EE, Wilson L, Nakane D, Hendrixson DR, and Beeby M

Abstract

The flagellar motors of Campylobacter jejuni (C. jejuni) and related Campylobacterota (previously epsilonproteobacteria) feature 100-nm-wide periplasmic "basal disks" that have been implicated in scaffolding a wider ring of additional motor proteins to increase torque, but the size of these disks is excessive for a role solely in scaffolding motor proteins. Here, we show that the basal disk is a flange that braces the flagellar motor during disentanglement of its flagellar filament from interactions with the cell body and other filaments. We show that motor output is unaffected when we shrink or displace the basal disk, and suppressor mutations of debilitated motors occur in flagellar-filament or cell-surface glycosylation pathways, thus sidestepping the need for a flange to overcome the interactions between two flagellar filaments and between flagellar filaments and the cell body. Our results identify unanticipated co-dependencies in the evolution of flagellar motor structure and cell-surface properties in the Campylobacterota., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published
2024
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17. Cryo-electron tomography of intact cardiac muscle reveals myosin binding protein-C linking myosin and actin filaments.

Author

Huang X, Torre I, Chiappi M, Yin Z, Vydyanath A, Cao S, Raschdorf O, Beeby M, Quigley B, de Tombe PP, Liu J, Morris EP, and Luther PK

Subjects
Rats, Animals, Myocardium metabolism, Myosins metabolism, Actin Cytoskeleton metabolism, Mammals metabolism, Actins metabolism, Electron Microscope Tomography
Abstract

Myosin binding protein C (MyBP-C) is an accessory protein of the thick filament in vertebrate cardiac muscle arranged over 9 stripes of intervals of 430 Å in each half of the A-band in the region called the C-zone. Mutations in cardiac MyBP-C are a leading cause of hypertrophic cardiomyopathy the mechanism of which is unknown. It is a rod-shaped protein composed of 10 or 11 immunoglobulin- or fibronectin-like domains labelled C0 to C10 which binds to the thick filament via its C-terminal region. MyBP-C regulates contraction in a phosphorylation dependent fashion that may be through binding of its N-terminal domains with myosin or actin. Understanding the 3D organisation of MyBP-C in the sarcomere environment may provide new light on its function. We report here the fine structure of MyBP-C in relaxed rat cardiac muscle by cryo-electron tomography and subtomogram averaging of refrozen Tokuyasu cryosections. We find that on average MyBP-C connects via its distal end to actin across a disc perpendicular to the thick filament. The path of MyBP-C suggests that the central domains may interact with myosin heads. Surprisingly MyBP-C at Stripe 4 is different; it has weaker density than the other stripes which could result from a mainly axial or wavy path. Given that the same feature at Stripe 4 can also be found in several mammalian cardiac muscles and in some skeletal muscles, our finding may have broader implication and significance. In the D-zone, we show the first demonstration of myosin crowns arranged on a uniform 143 Å repeat., (© 2023. The Author(s).)

Published
2023
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18. The malaria parasite chaperonin containing TCP-1 (CCT) complex: Data integration with other CCT proteomes.

Author

Wilkinson MD, Ferreira JL, Beeby M, Baum J, and Willison KR

Abstract

The multi-subunit chaperonin containing TCP-1 (CCT) is an essential molecular chaperone that functions in the folding of key cellular proteins. This paper reviews the interactome of the eukaryotic chaperonin CCT and its primary clients, the ubiquitous cytoskeletal proteins, actin and tubulin. CCT interacts with other nascent proteins, especially the WD40 propeller proteins, and also assists in the assembly of several protein complexes. A new proteomic dataset is presented for CCT purified from the human malarial parasite, P. falciparum (PfCCT). The CCT8 subunit gene was C-terminally FLAG-tagged using Selection Linked Integration (SLI) and CCT complexes were extracted from infected human erythrocyte cultures synchronized for maximum expression levels of CCT at the trophozoite stage of the parasite's asexual life cycle. We analyze the new PfCCT proteome and incorporate it into our existing model of the CCT system, supported by accumulated data from biochemical and cell biological experiments in many eukaryotic species. Together with measurements of CCT mRNA, CCT protein subunit copy number and the post-translational and chemical modifications of the CCT subunits themselves, a cumulative picture is emerging of an essential molecular chaperone system sitting at the heart of eukaryotic cell growth control and cell cycle regulation., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Wilkinson, Ferreira, Beeby, Baum and Willison.)

Published
2022
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19. Discovery of a Novel Inner Membrane-Associated Bacterial Structure Related to the Flagellar Type III Secretion System.

Author

Kaplan M, Oikonomou CM, Wood CR, Chreifi G, Ghosal D, Dobro MJ, Yao Q, Pal RR, Baidya AK, Liu Y, Maggi S, McDowall AW, Ben-Yehuda S, Rosenshine I, Briegel A, Beeby M, Chang YW, Shaffer CL, and Jensen GJ

Subjects
Bacteria metabolism, Bacterial Proteins metabolism, Bacterial Structures, Flagella metabolism, Type III Secretion Systems genetics, Type III Secretion Systems metabolism
Abstract

The bacterial flagellar type III secretion system (fT3SS) is a suite of membrane-embedded and cytoplasmic proteins responsible for building the flagellar motility machinery. Homologous nonflagellar (NF-T3SS) proteins form the injectisome machinery that bacteria use to deliver effector proteins into eukaryotic cells, and other family members were recently reported to be involved in the formation of membrane nanotubes. Here, we describe a novel, evolutionarily widespread, hat-shaped structure embedded in the inner membranes of bacteria, of yet-unidentified function, that is present in species containing fT3SS. Mutant analysis suggests a relationship between this novel structure and the fT3SS, but not the NF-T3SS. While the function of this novel structure remains unknown, we hypothesize that either some of the fT3SS proteins assemble within the hat-like structure, perhaps including the fT3SS core complex, or that fT3SS components regulate other proteins that form part of this novel structure. IMPORTANCE The type III secretion system (T3SS) is a fascinating suite of proteins involved in building diverse macromolecular systems, including the bacterial flagellar motility machine, the injectisome machinery that bacteria use to inject effector proteins into host cells, and probably membrane nanotubes which connect bacterial cells. Here, we accidentally discovered a novel inner membrane-associated complex related to the flagellar T3SS. Examining our lab database, which is comprised of more than 40,000 cryo-tomograms of dozens of species, we discovered that this novel structure is both ubiquitous and ancient, being present in highly divergent classes of bacteria. Discovering a novel, widespread structure related to what are among the best-studied molecular machines in bacteria will open new venues for research aiming at understanding the function and evolution of T3SS proteins.

Published
2022
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20. Novel transient cytoplasmic rings stabilize assembling bacterial flagellar motors.

Author

Kaplan M, Oikonomou CM, Wood CR, Chreifi G, Subramanian P, Ortega DR, Chang YW, Beeby M, Shaffer CL, and Jensen GJ

Subjects
Bacterial Proteins metabolism, Electron Microscope Tomography methods, Escherichia coli genetics, Escherichia coli metabolism, Flagella metabolism, Type III Secretion Systems metabolism, Campylobacter jejuni metabolism, Helicobacter pylori
Abstract

The process by which bacterial cells build their intricate flagellar motility apparatuses has long fascinated scientists. Our understanding of this process comes mainly from studies of purified flagella from two species, Escherichia coli and Salmonella enterica. Here, we used electron cryo-tomography (cryo-ET) to image the assembly of the flagellar motor in situ in diverse Proteobacteria: Hylemonella gracilis, Helicobacter pylori, Campylobacter jejuni, Pseudomonas aeruginosa, Pseudomonas fluorescens, and Shewanella oneidensis. Our results reveal the in situ structures of flagellar intermediates, beginning with the earliest flagellar type III secretion system core complex (fT3SScc) and MS-ring. In high-torque motors of Beta-, Gamma-, and Epsilon-proteobacteria, we discovered novel cytoplasmic rings that interact with the cytoplasmic torque ring formed by FliG. These rings, associated with the MS-ring, assemble very early and persist until the stators are recruited into their periplasmic ring; in their absence the stator ring does not assemble. By imaging mutants in Helicobacter pylori, we found that the fT3SScc proteins FliO and FliQ are required for the assembly of these novel cytoplasmic rings. Our results show that rather than a simple accretion of components, flagellar motor assembly is a dynamic process in which accessory components interact transiently to assist in building the complex nanomachine., (© 2022 The Authors.)

Published
2022
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21. How Did the Archaellum Get Its Rotation?

Author

Ortega D and Beeby M

Abstract

How new functions evolve fascinates many evolutionary biologists. Particularly captivating is the evolution of rotation in molecular machines, as it evokes familiar machines that we have made ourselves. The archaellum, an archaeal analog of the bacterial flagellum, is one of the simplest rotary motors. It features a long helical propeller attached to a cell envelope-embedded rotary motor. Satisfyingly, the archaellum is one of many members of the large type IV filament superfamily, which includes pili, secretion systems, and adhesins, relationships that promise clues as to how the rotating archaellum evolved from a non-rotary ancestor. Nevertheless, determining exactly how the archaellum got its rotation remains frustratingly elusive. Here we review what is known about how the archaellum got its rotation, what clues exist, and what more is needed to address this question., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Ortega and Beeby.)

Published
2022
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22. Adaptation of the periplasm to maintain spatial constraints essential for cell envelope processes and cell viability.

Author

Mandela E, Stubenrauch CJ, Ryoo D, Hwang H, Cohen EJ, Torres VL, Deo P, Webb CT, Huang C, Schittenhelm RB, Beeby M, Gumbart JC, Lithgow T, and Hay ID

Subjects
Cell Membrane metabolism, Cell Wall, Escherichia coli metabolism, Gram-Negative Bacteria metabolism, Peptidoglycan, Protein Transport, Bacterial Outer Membrane Proteins metabolism, Cell Survival physiology, Escherichia coli Proteins metabolism, Lipoproteins metabolism, Periplasm physiology
Abstract

The cell envelope of Gram-negative bacteria consists of two membranes surrounding a periplasm and peptidoglycan layer. Molecular machines spanning the cell envelope depend on spatial constraints and load-bearing forces across the cell envelope and surface. The mechanisms dictating spatial constraints across the cell envelope remain incompletely defined. In Escherichia coli , the coiled-coil lipoprotein Lpp contributes the only covalent linkage between the outer membrane and the underlying peptidoglycan layer. Using proteomics, molecular dynamics, and a synthetic lethal screen, we show that lengthening Lpp to the upper limit does not change the spatial constraint but is accommodated by other factors which thereby become essential for viability. Our findings demonstrate E. coli expressing elongated Lpp does not simply enlarge the periplasm in response, but the bacteria accommodate by a combination of tilting Lpp and reducing the amount of the covalent bridge. By genetic screening, we identified all of the genes in E. coli that become essential in order to enact this adaptation, and by quantitative proteomics discovered that very few proteins need to be up- or down-regulated in steady-state levels in order to accommodate the longer Lpp. We observed increased levels of factors determining cell stiffness, a decrease in membrane integrity, an increased membrane vesiculation and a dependance on otherwise non-essential tethers to maintain lipid transport and peptidoglycan biosynthesis. Further this has implications for understanding how spatial constraint across the envelope controls processes such as flagellum-driven motility, cellular signaling, and protein translocation., Competing Interests: EM, CS, DR, HH, EC, VT, PD, CW, CH, RS, MB, JG, TL, IH No competing interests declared, (© 2022, Mandela et al.)

Published
2022
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23. Evolution of Archaellum Rotation Involved Invention of a Stator Complex by Duplicating and Modifying a Core Component.

Author

Umrekar TR, Winterborn YB, Sivabalasarma S, Brantl J, Albers SV, and Beeby M

Abstract

Novelty in biology can arise from opportunistic repurposing of nascent characteristics of existing features. Understanding how this process happens at the molecular scale, however, suffers from a lack of case studies. The evolutionary emergence of rotary motors is a particularly clear example of evolution of a new function. The simplest of rotary motors is the archaellum, a molecular motor that spins a helical propeller for archaeal motility analogous to the bacterial flagellum. Curiously, emergence of archaellar rotation may have pivoted on the simple duplication and repurposing of a pre-existing component to produce a stator complex that anchors to the cell superstructure to enable productive rotation of the rotor component. This putative stator complex is composed of ArlF and ArlG, gene duplications of the filament component ArlB, providing an opportunity to study how gene duplication and neofunctionalization contributed to the radical innovation of rotary function. Toward understanding how this happened, we used electron cryomicroscopy to determine the structure of isolated ArlG filaments, the major component of the stator complex. Using a hybrid modeling approach incorporating structure prediction and validation, we show that ArlG filaments are open helices distinct to the closed helical filaments of ArlB. Curiously, further analysis reveals that ArlG retains a subset of the inter-protomer interactions of homologous ArlB, resulting in a superficially different assembly that nevertheless reflects the common ancestry of the two structures. This relatively simple mechanism to change quaternary structure was likely associated with the evolutionary neofunctionalization of the archaellar stator complex, and we speculate that the relative deformable elasticity of an open helix may facilitate elastic energy storage during the transmission of the discrete bursts of energy released by ATP hydrolysis to continuous archaellar rotation, allowing the inherent properties of a duplicated ArlB to be co-opted to fulfill a new role. Furthermore, agreement of diverse experimental evidence in our work supports recent claims to the power of new structure prediction techniques., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Umrekar, Winterborn, Sivabalasarma, Brantl, Albers and Beeby.)

Published
2021
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25. Lpp positions peptidoglycan at the AcrA-TolC interface in the AcrAB-TolC multidrug efflux pump.

Author

Gumbart JC, Ferreira JL, Hwang H, Hazel AJ, Cooper CJ, Parks JM, Smith JC, Zgurskaya HI, and Beeby M

Subjects
Anti-Bacterial Agents, Bacterial Outer Membrane Proteins metabolism, Carrier Proteins, Cell Wall metabolism, Cryoelectron Microscopy, Escherichia coli metabolism, Lipoproteins metabolism, Membrane Transport Proteins, Multidrug Resistance-Associated Proteins, Escherichia coli Proteins metabolism, Peptidoglycan metabolism
Abstract

The multidrug efflux pumps of Gram-negative bacteria are a class of complexes that span the periplasm, coupling both the inner and outer membranes to expel toxic molecules. The best-characterized example of these tripartite pumps is the AcrAB-TolC complex of Escherichia coli. However, how the complex interacts with the peptidoglycan (PG) cell wall, which is anchored to the outer membrane (OM) by Braun's lipoprotein (Lpp), is still largely unknown. In this work, we present molecular dynamics simulations of a complete, atomistic model of the AcrAB-TolC complex with the inner membrane, OM, and PG layers all present. We find that the PG localizes to the junction of AcrA and TolC, in agreement with recent cryo-tomography data. Free-energy calculations reveal that the positioning of PG is determined by the length and conformation of multiple Lpp copies anchoring it to the OM. The distance between the PG and OM measured in cryo-electron microscopy images of wild-type E. coli also agrees with the simulation-derived spacing. Sequence analysis of AcrA suggests a conserved role for interactions with PG in the assembly and stabilization of efflux pumps, one that may extend to other trans-envelope complexes as well., (Copyright © 2021 Biophysical Society. All rights reserved.)

Published
2021
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26. In situ imaging of bacterial outer membrane projections and associated protein complexes using electron cryo-tomography.

Author

Kaplan M, Chreifi G, Metskas LA, Liedtke J, Wood CR, Oikonomou CM, Nicolas WJ, Subramanian P, Zacharoff LA, Wang Y, Chang YW, Beeby M, Dobro MJ, Zhu Y, McBride MJ, Briegel A, Shaffer CL, and Jensen GJ

Subjects
Bacteria classification, Multiprotein Complexes, Bacteria ultrastructure, Bacterial Outer Membrane ultrastructure, Bacterial Outer Membrane Proteins ultrastructure, Cell Surface Extensions ultrastructure, Cryoelectron Microscopy, Electron Microscope Tomography
Abstract

The ability to produce outer membrane projections in the form of tubular membrane extensions (MEs) and membrane vesicles (MVs) is a widespread phenomenon among diderm bacteria. Despite this, our knowledge of the ultrastructure of these extensions and their associated protein complexes remains limited. Here, we surveyed the ultrastructure and formation of MEs and MVs, and their associated protein complexes, in tens of thousands of electron cryo-tomograms of ~90 bacterial species that we have collected for various projects over the past 15 years (Jensen lab database), in addition to data generated in the Briegel lab. We identified outer MEs and MVs in 13 diderm bacterial species and classified several major ultrastructures: (1) tubes with a uniform diameter (with or without an internal scaffold), (2) tubes with irregular diameter, (3) tubes with a vesicular dilation at their tip, (4) pearling tubes, (5) connected chains of vesicles (with or without neck-like connectors), (6) budding vesicles and nanopods. We also identified several protein complexes associated with these MEs and MVs which were distributed either randomly or exclusively at the tip. These complexes include a secretin-like structure and a novel crown-shaped structure observed primarily in vesicles from lysed cells. In total, this work helps to characterize the diversity of bacterial membrane projections and lays the groundwork for future research in this field., Competing Interests: MK, LM, JL, CW, CO, WN, PS, LZ, YW, YC, MB, MD, YZ, MM, AB, CS, GJ none, GC None, (© 2021, Kaplan et al.)

Published
2021
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27. Loss of the Bacterial Flagellar Motor Switch Complex upon Cell Lysis.

Author

Kaplan M, Tocheva EI, Briegel A, Dobro MJ, Chang YW, Subramanian P, McDowall AW, Beeby M, and Jensen GJ

Subjects
Bacteria chemistry, Bacteria classification, Bacterial Physiological Phenomena, Bacterial Proteins chemistry, Protein Conformation, Bacteria metabolism, Flagella physiology
Abstract

The bacterial flagellar motor is a complex macromolecular machine whose function and self-assembly present a fascinating puzzle for structural biologists. Here, we report that in diverse bacterial species, cell lysis leads to loss of the cytoplasmic switch complex and associated ATPase before other components of the motor. This loss may be prevented by the formation of a cytoplasmic vesicle around the complex. These observations suggest a relatively loose association of the switch complex with the rest of the flagellar machinery. IMPORTANCE We show in eight different bacterial species (belonging to different phyla) that the flagellar motor loses its cytoplasmic switch complex upon cell lysis, while the rest of the flagellum remains attached to the cell body. This suggests an evolutionary conserved weak interaction between the switch complex and the rest of the flagellum which is important to understand how the motor evolved. In addition, this information is crucial for mimicking such nanomachines in the laboratory.

Published
2021
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28. Structure of the cytoplasmic domain of SctV (SsaV) from the Salmonella SPI-2 injectisome and implications for a pH sensing mechanism.

Author

Matthews-Palmer TRS, Gonzalez-Rodriguez N, Calcraft T, Lagercrantz S, Zachs T, Yu XJ, Grabe GJ, Holden DW, Nans A, Rosenthal PB, Rouse SL, and Beeby M

Subjects
Bacterial Proteins genetics, Cryoelectron Microscopy, Cytoplasm metabolism, Hydrogen-Ion Concentration, Models, Molecular, Molecular Dynamics Simulation, Protein Domains, Type III Secretion Systems metabolism, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Salmonella typhimurium chemistry, Salmonella typhimurium pathogenicity, Salmonella typhimurium physiology, Type III Secretion Systems chemistry
Abstract

Bacterial type III secretion systems assemble the axial structures of both injectisomes and flagella. Injectisome type III secretion systems subsequently secrete effector proteins through their hollow needle into a host, requiring co-ordination. In the Salmonella enterica serovar Typhimurium SPI-2 injectisome, this switch is triggered by sensing the neutral pH of the host cytoplasm. Central to specificity switching is a nonameric SctV protein with an N-terminal transmembrane domain and a toroidal C-terminal cytoplasmic domain. A 'gatekeeper' complex interacts with the SctV cytoplasmic domain in a pH dependent manner, facilitating translocon secretion while repressing effector secretion through a poorly understood mechanism. To better understand the role of SctV in SPI-2 translocon-effector specificity switching, we purified full-length SctV and determined its toroidal cytoplasmic region's structure using cryo-EM. Structural comparisons and molecular dynamics simulations revealed that the cytoplasmic torus is stabilized by its core subdomain 3, about which subdomains 2 and 4 hinge, varying the flexible outside cleft implicated in gatekeeper and substrate binding. In light of patterns of surface conservation, deprotonation, and structural motion, the location of previously identified critical residues suggest that gatekeeper binds a cleft buried between neighboring subdomain 4s. Simulations suggest that a local pH change from 5 to 7.2 stabilizes the subdomain 3 hinge and narrows the central aperture of the nonameric torus. Our results are consistent with a model of local pH sensing at SctV, where pH-dependent dynamics of SctV cytoplasmic domain affect binding of gatekeeper complex., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published
2021
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29. The "Jack-of-all-Trades" Flagellum From Salmonella and E. coli Was Horizontally Acquired From an Ancestral β-Proteobacterium.

Author

Ferreira JL, Coleman I, Addison ML, Zachs T, Quigley BL, Wuichet K, and Beeby M

Abstract

The γ-proteobacteria are a group of diverse bacteria including pathogenic Escherichia, Salmonella, Vibrio , and Pseudomonas species. The majority swim in liquids with polar, sodium-driven flagella and swarm on surfaces with lateral, non-chemotactic flagella. Notable exceptions are the enteric Enterobacteriaceae such as Salmonella and E. coli . Many of the well-studied Enterobacteriaceae are gut bacteria that both swim and swarm with the same proton-driven peritrichous flagella. How different flagella evolved in closely related lineages, however, has remained unclear. Here, we describe our phylogenetic finding that Enterobacteriaceae flagella are not native polar or lateral γ-proteobacterial flagella but were horizontally acquired from an ancestral β-proteobacterium. Using electron cryo-tomography and subtomogram averaging, we confirmed that Enterobacteriaceae flagellar motors resemble contemporary β-proteobacterial motors and are distinct to the polar and lateral motors of other γ-proteobacteria. Structural comparisons support a model in which γ-proteobacterial motors have specialized, suggesting that acquisition of a β-proteobacterial flagellum may have been beneficial as a general-purpose motor suitable for adjusting to diverse conditions. This acquisition may have played a role in the development of the enteric lifestyle., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Ferreira, Coleman, Addison, Zachs, Quigley, Wuichet and Beeby.)

Published
2021
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30. CryoEM of bacterial secretion systems: A primer for microbiologists.

Author

Umrekar TR, Cohen E, Drobnič T, Gonzalez-Rodriguez N, and Beeby M

Subjects
Bacterial Proteins chemistry, Bacterial Proteins metabolism, Imaging, Three-Dimensional, Membrane Transport Proteins chemistry, Models, Molecular, Molecular Biology, Protein Conformation, Single Molecule Imaging, Cryoelectron Microscopy methods, Membrane Transport Proteins metabolism, Type III Secretion Systems chemistry, Type III Secretion Systems metabolism
Abstract

"CryoEM" has come of age, enabling considerable structural insights into many facets of molecular biology. Here, we present a primer for microbiologists to understand the capabilities and limitations of two complementary cryoEM techniques for studying bacterial secretion systems. The first, single particle analysis, determines the structures of purified protein complexes to resolutions sufficient for molecular modeling, while the second, electron cryotomography and subtomogram averaging, tends to determine more modest resolution structures of protein complexes in intact cells. We illustrate these abilities with examples of insights provided into how secretion systems work by cryoEM, with a focus on type III secretion systems., (© 2020 The Authors. Molecular Microbiology published by John Wiley & Sons Ltd.)

Published
2021
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31. Analysis of Cell-Cell Bridges in Haloferax volcanii Using Electron Cryo-Tomography Reveal a Continuous Cytoplasm and S-Layer.

Author

Sivabalasarma S, Wetzel H, Nußbaum P, van der Does C, Beeby M, and Albers SV

Abstract

Halophilic archaea have been proposed to exchange DNA and proteins using a fusion-based mating mechanism. Scanning electron microscopy previously suggested that mating involves an intermediate state, where cells are connected by an intercellular bridge. To better understand this process, we used electron cryo-tomography (cryoET) and fluorescence microscopy to visualize cells forming these intercellular bridges. CryoET showed that the observed bridges were enveloped by an surface layer (S-layer) and connected mating cells via a continuous cytoplasm. Macromolecular complexes like ribosomes and unknown thin filamentous helical structures were visualized in the cytoplasm inside the bridges, demonstrating that these bridges can facilitate exchange of cellular components. We followed formation of a cell-cell bridge by fluorescence time-lapse microscopy between cells at a distance of 1.5 μm. These results shed light on the process of haloarchaeal mating and highlight further mechanistic questions., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Sivabalasarma, Wetzel, Nußbaum, van der Does, Beeby and Albers.)

Published
2021
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32. Inter-membrane association of the Sec and BAM translocons for bacterial outer-membrane biogenesis.

Author

Alvira S, Watkins DW, Troman L, Allen WJ, Lorriman JS, Degliesposti G, Cohen EJ, Beeby M, Daum B, Gold VA, Skehel JM, and Collinson I

Subjects
Bacterial Outer Membrane Proteins genetics, Bacterial Secretion Systems genetics, Models, Molecular, Protein Conformation, Protein Transport, Bacterial Outer Membrane Proteins metabolism, Bacterial Secretion Systems metabolism, Escherichia coli metabolism, Gene Expression Regulation, Bacterial
Abstract

The outer-membrane of Gram-negative bacteria is critical for surface adhesion, pathogenicity, antibiotic resistance and survival. The major constituent - hydrophobic β-barrel O uter- M embrane P roteins (OMPs) - are first secreted across the inner-membrane through the Sec-translocon for delivery to periplasmic chaperones, for example SurA, which prevent aggregation. OMPs are then offloaded to the β- B arrel A ssembly M achinery (BAM) in the outer-membrane for insertion and folding. We show the H olo- T rans L ocon (HTL) - an assembly of the protein-channel core-complex SecYEG, the ancillary sub-complex SecDF, and the membrane 'insertase' YidC - contacts BAM through periplasmic domains of SecDF and YidC, ensuring efficient OMP maturation. Furthermore, the proton-motive force (PMF) across the inner-membrane acts at distinct stages of protein secretion: (1) SecA-driven translocation through SecYEG and (2) communication of conformational changes via SecDF across the periplasm to BAM. The latter presumably drives efficient passage of OMPs. These interactions provide insights of inter-membrane organisation and communication, the importance of which is becoming increasingly apparent., Competing Interests: SA, DW, LT, WA, JL, GD, EC, MB, BD, VG, JS, IC No competing interests declared, (© 2020, Alvira et al.)

Published
2020
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33. Adenita: interactive 3D modelling and visualization of DNA nanostructures.

Author

de Llano E, Miao H, Ahmadi Y, Wilson AJ, Beeby M, Viola I, and Barisic I

Subjects
DNA ultrastructure, Microscopy, Electron, Transmission, Models, Molecular, Nanostructures ultrastructure, DNA chemistry, Nanostructures chemistry, Nucleic Acid Conformation, Software
Abstract

DNA nanotechnology is a rapidly advancing field, which increasingly attracts interest in many different disciplines, such as medicine, biotechnology, physics and biocomputing. The increasing complexity of novel applications requires significant computational support for the design, modelling and analysis of DNA nanostructures. However, current in silico design tools have not been developed in view of these new applications and their requirements. Here, we present Adenita, a novel software tool for the modelling of DNA nanostructures in a user-friendly environment. A data model supporting different DNA nanostructure concepts (multilayer DNA origami, wireframe DNA origami, DNA tiles etc.) has been developed allowing the creation of new and the import of existing DNA nanostructures. In addition, the nanostructures can be modified and analysed on-the-fly using an intuitive toolset. The possibility to combine and re-use existing nanostructures as building blocks for the creation of new superstructures, the integration of alternative molecules (e.g. proteins, aptamers) during the design process, and the export option for oxDNA simulations are outstanding features of Adenita, which spearheads a new generation of DNA nanostructure modelling software. We showcase Adenita by re-using a large nanorod to create a new nanostructure through user interactions that employ different editors to modify the original nanorod., (© The Author(s) 2020. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published
2020
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34. In situ structure of the Caulobacter crescentus flagellar motor and visualization of binding of a CheY-homolog.

Author

Rossmann FM, Hug I, Sangermani M, Jenal U, and Beeby M

Subjects
Bacterial Proteins genetics, Caulobacter crescentus ultrastructure, Electron Microscope Tomography, Flagella ultrastructure, Genome, Bacterial, Image Processing, Computer-Assisted, Membrane Proteins genetics, Membrane Proteins metabolism, Models, Molecular, Mutation, Protein Binding, Structure-Activity Relationship, Bacterial Proteins metabolism, Caulobacter crescentus metabolism, Flagella metabolism, Methyl-Accepting Chemotaxis Proteins metabolism
Abstract

Bacterial flagellar motility is controlled by the binding of CheY proteins to the cytoplasmic switch complex of the flagellar motor, resulting in changes in swimming speed or direction. Despite its importance for motor function, structural information about the interaction between effector proteins and the motor are scarce. To address this gap in knowledge, we used electron cryotomography and subtomogram averaging to visualize such interactions inside Caulobacter crescentus cells. In C. crescentus, several CheY homologs regulate motor function for different aspects of the bacterial lifestyle. We used subtomogram averaging to image binding of the CheY family protein CleD to the cytoplasmic Cring switch complex, the control center of the flagellar motor. This unambiguously confirmed the orientation of the motor switch protein FliM and the binding of a member of the CheY protein family to the outside rim of the C ring. We also uncovered previously unknown structural elaborations of the alphaproteobacterial flagellar motor, including two novel periplasmic ring structures, and the stator ring harboring eleven stator units, adding to our growing catalog of bacterial flagellar diversity., (© 2020 The Authors. Molecular Microbiology published by John Wiley & Sons Ltd.)

Published
2020
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35. An ATP-dependent partner switch links flagellar C-ring assembly with gene expression.

Author

Blagotinsek V, Schwan M, Steinchen W, Mrusek D, Hook JC, Rossmann F, Freibert SA, Kratzat H, Murat G, Kressler D, Beckmann R, Beeby M, Thormann KM, and Bange G

Subjects
Adenosine Triphosphatases metabolism, Adenosine Triphosphate metabolism, Bacteria metabolism, Biochemical Phenomena, Gene Expression genetics, Gene Expression Regulation, Bacterial genetics, Monomeric GTP-Binding Proteins metabolism, Shewanella putrefaciens genetics, Shewanella putrefaciens metabolism, Bacterial Proteins metabolism, Flagella genetics, Flagella metabolism
Abstract

Bacterial flagella differ in their number and spatial arrangement. In many species, the MinD-type ATPase FlhG (also YlxH/FleN) is central to the numerical control of bacterial flagella, and its deletion in polarly flagellated bacteria typically leads to hyperflagellation. The molecular mechanism underlying this numerical control, however, remains enigmatic. Using the model species Shewanella putrefaciens , we show that FlhG links assembly of the flagellar C ring with the action of the master transcriptional regulator FlrA (named FleQ in other species). While FlrA and the flagellar C-ring protein FliM have an overlapping binding site on FlhG, their binding depends on the ATP-dependent dimerization state of FlhG. FliM interacts with FlhG independent of nucleotide binding, while FlrA exclusively interacts with the ATP-dependent FlhG dimer and stimulates FlhG ATPase activity. Our in vivo analysis of FlhG partner switching between FliM and FlrA reveals its mechanism in the numerical restriction of flagella, in which the transcriptional activity of FlrA is down-regulated through a negative feedback loop. Our study demonstrates another level of regulatory complexity underlying the spationumerical regulation of flagellar biogenesis and implies that flagellar assembly transcriptionally regulates the production of more initial building blocks., Competing Interests: The authors declare no competing interest.

Published
2020
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36. Trichinella spiralis secretes abundant unencapsulated small RNAs with potential effects on host gene expression.

Author

Taylor PJ, Hagen J, Faruqu FN, Al-Jamal KT, Quigley B, Beeby M, Selkirk ME, and Sarkies P

Subjects
Animals, Rats, Rats, Sprague-Dawley, Extracellular Vesicles metabolism, Gene Expression, Life Cycle Stages, MicroRNAs metabolism, RNA, Helminth metabolism, Trichinella spiralis metabolism
Abstract

Many organisms, including parasitic nematodes, secrete small RNAs into the extracellular environment, largely encapsulated within small vesicles. Parasite-secreted material often contains microRNAs (miRNAs), raising the possibility that they might regulate host genes in target cells. Here we characterise secreted RNAs from the parasitic nematode Trichinella spiralis at two different life stages. We show that adult T. spiralis, which inhabit intestinal mucosa, secrete miRNAs within vesicles. Unexpectedly, T. spiralis muscle stage larvae, which live intracellularly within skeletal muscle cells, secrete miRNAs that appear not to be encapsulated. Notably, secreted miRNAs include a homologue of mammalian miRNA-31, which has an important role in muscle development. Our work therefore suggests that RNAs may be secreted without encapsulation in vesicles, with implications for the biology of T. spiralis infection., (Copyright © 2020 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published
2020
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37. Campylobacter jejuni motility integrates specialized cell shape, flagellar filament, and motor, to coordinate action of its opposed flagella.

Author

Cohen EJ, Nakane D, Kabata Y, Hendrixson DR, Nishizaka T, and Beeby M

Subjects
Flagellin metabolism, Campylobacter jejuni physiology, Flagella physiology
Abstract

Campylobacter jejuni rotates a flagellum at each pole to swim through the viscous mucosa of its hosts' gastrointestinal tracts. Despite their importance for host colonization, however, how C. jejuni coordinates rotation of these two opposing flagella is unclear. As well as their polar placement, C. jejuni's flagella deviate from the norm of Enterobacteriaceae in other ways: their flagellar motors produce much higher torque and their flagellar filament is made of two different zones of two different flagellins. To understand how C. jejuni's opposed motors coordinate, and what contribution these factors play in C. jejuni motility, we developed strains with flagella that could be fluorescently labeled, and observed them by high-speed video microscopy. We found that C. jejuni coordinates its dual flagella by wrapping the leading filament around the cell body during swimming in high-viscosity media and that its differentiated flagellar filament and helical body have evolved to facilitate this wrapped-mode swimming., Competing Interests: The authors have declared that no competing interests exist.

Published
2020
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38. Toward Organism-scale Structural Biology: S-layer Reined in by Bacterial LPS.

Author

Beeby M

Subjects
Carbohydrate Conformation, Mass Spectrometry methods, Molecular Dynamics Simulation, Caulobacter crescentus chemistry, Lipopolysaccharides chemistry
Abstract

Technical developments are unifying molecular and cellular biology. A recent electron cryotomography study by von Kügelgen et al. highlights the bright future for such studies, seamlessly integrating near-atomic resolution protein structures, organism-scale architecture, native mass spectrometry, and molecular dynamic simulations to clarify how the Caulobacter crescentus S-layer assembles on the lipopolysaccharides (LPS) of the cell surface., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published
2020
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39. The Brownian and Flow-Driven Rotational Dynamics of a Multicomponent DNA Origami-Based Rotor.

Author

Ahmadi Y, Nord AL, Wilson AJ, Hütter C, Schroeder F, Beeby M, and Barišić I

Subjects
DNA, Nucleic Acid Conformation, Single Molecule Imaging, Nanostructures, Nanotechnology
Abstract

Nanomechanical devices are becoming increasingly popular due to the very diverse field of potential applications, including nanocomputing, robotics, and drug delivery. DNA is one of the most promising building materials to realize complex 3D structures at the nanoscale level. Several mechanical DNA origami structures have already been designed capable of simple operations such as a DNA box with a controllable lid, bipedal walkers, and cargo sorting robots. However, the nanomechanical properties of mechanically interlinked DNA nanostructures that are in general highly deformable have yet to be extensively experimentally evaluated. In this work, a multicomponent DNA origami-based rotor is created and fully characterized by electron microscopy under negative stain and cryo preparations. The nanodevice is further immobilized on a microfluidic chamber and its Brownian and flow-driven rotational behaviors are analyzed in real time by single-molecule fluorescence microscopy. The rotation in previous DNA rotors based either on strand displacement, electric field or Brownian motion. This study is the first to attempt to manipulate the dynamics of an artificial nanodevice with fluidic flow as a natural force., (© 2020 The Authors. Published by WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2020
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40. Propulsive nanomachines: the convergent evolution of archaella, flagella and cilia.

Author

Beeby M, Ferreira JL, Tripp P, Albers SV, and Mitchell DR

Subjects
Archaea classification, Archaea physiology, Bacteria classification, Bacterial Physiological Phenomena, Cell Movement, Eukaryota classification, Eukaryota physiology, Archaeal Proteins metabolism, Biological Evolution, Cilia physiology, Flagella physiology, Locomotion physiology
Abstract

Echoing the repeated convergent evolution of flight and vision in large eukaryotes, propulsive swimming motility has evolved independently in microbes in each of the three domains of life. Filamentous appendages - archaella in Archaea, flagella in Bacteria and cilia in Eukaryotes - wave, whip or rotate to propel microbes, overcoming diffusion and enabling colonization of new environments. The implementations of the three propulsive nanomachines are distinct, however: archaella and flagella rotate, while cilia beat or wave; flagella and cilia assemble at their tips, while archaella assemble at their base; archaella and cilia use ATP for motility, while flagella use ion-motive force. These underlying differences reflect the tinkering required to evolve a molecular machine, in which pre-existing machines in the appropriate contexts were iteratively co-opted for new functions and whose origins are reflected in their resultant mechanisms. Contemporary homologies suggest that archaella evolved from a non-rotary pilus, flagella from a non-rotary appendage or secretion system, and cilia from a passive sensory structure. Here, we review the structure, assembly, mechanism and homologies of the three distinct solutions as a foundation to better understand how propulsive nanomachines evolved three times independently and to highlight principles of molecular evolution., (© FEMS 2020.)

Published
2020
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41. Bacterial flagellar motor PL-ring disassembly subcomplexes are widespread and ancient.

Author

Kaplan M, Sweredoski MJ, Rodrigues JPGLM, Tocheva EI, Chang YW, Ortega DR, Beeby M, and Jensen GJ

Subjects
Bacteria cytology, Bacteria metabolism, Bacterial Outer Membrane metabolism, Bacterial Outer Membrane ultrastructure, Bacterial Outer Membrane Proteins metabolism, Bacterial Proteins metabolism, Computational Biology, Cryoelectron Microscopy, Electron Microscope Tomography, Flagella metabolism, Genes, Bacterial, Phylogeny, Bacteria genetics, Bacterial Outer Membrane Proteins genetics, Bacterial Proteins genetics, Flagella genetics, Genetic Speciation
Abstract

The bacterial flagellum is an amazing nanomachine. Understanding how such complex structures arose is crucial to our understanding of cellular evolution. We and others recently reported that in several Gammaproteobacterial species, a relic subcomplex comprising the decorated P and L rings persists in the outer membrane after flagellum disassembly. Imaging nine additional species with cryo-electron tomography, here, we show that this subcomplex persists after flagellum disassembly in other phyla as well. Bioinformatic analyses fail to show evidence of any recent horizontal transfers of the P- and L-ring genes, suggesting that this subcomplex and its persistence is an ancient and conserved feature of the flagellar motor. We hypothesize that one function of the P and L rings is to seal the outer membrane after motor disassembly., Competing Interests: The authors declare no competing interest., (Copyright © 2020 the Author(s). Published by PNAS.)

Published
2020
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42. Diversification of Campylobacter jejuni Flagellar C-Ring Composition Impacts Its Structure and Function in Motility, Flagellar Assembly, and Cellular Processes.

Author

Henderson LD, Matthews-Palmer TRS, Gulbronson CJ, Ribardo DA, Beeby M, and Hendrixson DR

Subjects
Bacterial Proteins chemistry, Bacterial Proteins metabolism, Biological Evolution, Campylobacter jejuni classification, Structure-Activity Relationship, Type III Secretion Systems, Campylobacter jejuni physiology, Flagella physiology
Abstract

Bacterial flagella are reversible rotary motors that rotate external filaments for bacterial propulsion. Some flagellar motors have diversified by recruiting additional components that influence torque and rotation, but little is known about the possible diversification and evolution of core motor components. The mechanistic core of flagella is the cytoplasmic C ring, which functions as a rotor, directional switch, and assembly platform for the flagellar type III secretion system (fT3SS) ATPase. The C ring is composed of a ring of FliG proteins and a helical ring of surface presentation of antigen (SPOA) domains from the switch proteins FliM and one of two usually mutually exclusive paralogs, FliN or FliY. We investigated the composition, architecture, and function of the C ring of Campylobacter jejuni , which encodes FliG, FliM, and both FliY and FliN by a variety of interrogative approaches. We discovered a diversified C. jejuni C ring containing FliG, FliM, and both FliY, which functions as a classical FliN-like protein for flagellar assembly, and FliN, which has neofunctionalized into a structural role. Specific protein interactions drive the formation of a more complex heterooligomeric C. jejuni C-ring structure. We discovered that this complex C ring has additional cellular functions in polarly localizing FlhG for numerical regulation of flagellar biogenesis and spatial regulation of division. Furthermore, mutation of the C. jejuni C ring revealed a T3SS that was less dependent on its ATPase complex for assembly than were other systems. Our results highlight considerable evolved flagellar diversity that impacts motor output, biogenesis, and cellular processes in different species. IMPORTANCE The conserved core of bacterial flagellar motors reflects a shared evolutionary history that preserves the mechanisms essential for flagellar assembly, rotation, and directional switching. In this work, we describe an expanded and diversified set of core components in the Campylobacter jejuni flagellar C ring, the mechanistic core of the motor. Our work provides insight into how usually conserved core components may have diversified by gene duplication, enabling a division of labor of the ancestral protein between the two new proteins, acquisition of new roles in flagellar assembly and motility, and expansion of the function of the flagellum beyond motility, including spatial regulation of cell division and numerical control of flagellar biogenesis in C. jejuni Our results highlight that relatively small changes, such as gene duplications, can have substantial ramifications on the cellular roles of a molecular machine., (Copyright © 2020 Henderson et al.)

Published
2020
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43. The structure of the periplasmic FlaG-FlaF complex and its essential role for archaellar swimming motility.

Author

Tsai CL, Tripp P, Sivabalasarma S, Zhang C, Rodriguez-Franco M, Wipfler RL, Chaudhury P, Banerjee A, Beeby M, Whitaker RJ, Tainer JA, and Albers SV

Subjects
Archaeal Proteins genetics, Cell Membrane metabolism, Flagella physiology, Models, Biological, Models, Molecular, Movement, Mutation, Protein Folding, Protein Interaction Domains and Motifs, Protein Multimerization, Protein Processing, Post-Translational, Structure-Activity Relationship, Archaeal Proteins chemistry, Archaeal Proteins metabolism, Periplasm metabolism, Sulfolobus acidocaldarius physiology
Abstract

Motility structures are vital in all three domains of life. In Archaea, motility is mediated by the archaellum, a rotating type IV pilus-like structure that is a unique nanomachine for swimming motility in nature. Whereas periplasmic FlaF binds the surface layer (S-layer), the structure, assembly and roles of other periplasmic components remain enigmatic, limiting our knowledge of the archaellum's functional interactions. Here, we find that the periplasmic protein FlaG and the association with its paralogue FlaF are essential for archaellation and motility. Therefore, we determine the crystal structure of Sulfolobus acidocaldarius soluble FlaG (sFlaG), which reveals a β-sandwich fold resembling the S-layer-interacting FlaF soluble domain (sFlaF). Furthermore, we solve the sFlaG 2 -sFlaF 2 co-crystal structure, define its heterotetrameric complex in solution by small-angle X-ray scattering and find that mutations that disrupt the complex abolish motility. Interestingly, the sFlaF and sFlaG of Pyrococcus furiosus form a globular complex, whereas sFlaG alone forms a filament, indicating that FlaF can regulate FlaG filament assembly. Strikingly, Sulfolobus cells that lack the S-layer component bound by FlaF assemble archaella but cannot swim. These collective results support a model where a FlaG filament capped by a FlaG-FlaF complex anchors the archaellum to the S-layer to allow motility.

Published
2020
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44. Evolution of a family of molecular Rube Goldberg contraptions.

Author

Beeby M

Subjects
DNA, Phylogeny, Protein Transport, Archaea genetics, Bacteria genetics
Abstract

Case studies of the evolution of molecular machines remain scarce. One of the most diverse and widespread homologous families of machines is the type IV filament (TFF) superfamily, comprised of type IV pili, type II secretion systems (T2SSs), archaella, and other less-well-characterized families. These families have functions including twitching motility, effector export, rotary propulsion, nutrient uptake, DNA uptake, and even electrical conductance, but it is unclear how such diversity evolved from a common ancestor. In this issue, Denise and colleagues take a significant step toward understanding evolution of the TFF superfamily by determining a global phylogeny and using it to infer an evolutionary pathway. Results reveal that the superfamily predates the divergence of Bacteria and Archaea, and show how duplications, acquisitions, and losses coincide with changes in function. Surprises include that tight adherence (Tad) pili were horizontally acquired from Archaea and that T2SSs were relatively recently repurposed from type IV pili. Results also enable better understanding of the function of the ATPase family that powers the superfamily. The study highlights the role of tinkering by exaptation-the repurposing of pre-existing functions for new roles-in the diversification of molecular machines., Competing Interests: The authors have declared that no competing interests exist.

Published
2019
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45. Simulations suggest a constrictive force is required for Gram-negative bacterial cell division.

Author

Nguyen LT, Oikonomou CM, Ding HJ, Kaplan M, Yao Q, Chang YW, Beeby M, and Jensen GJ

Subjects
Cell Wall ultrastructure, Computer Simulation, Constriction, Electron Microscope Tomography methods, Intravital Microscopy methods, Software, Bacterial Proteins metabolism, Cell Division physiology, Cell Wall metabolism, Cytoskeletal Proteins metabolism, Gram-Negative Bacteria physiology, Models, Biological
Abstract

To divide, Gram-negative bacterial cells must remodel cell wall at the division site. It remains debated, however, whether this cell wall remodeling alone can drive membrane constriction, or if a constrictive force from the tubulin homolog FtsZ is required. Previously, we constructed software (REMODELER 1) to simulate cell wall remodeling during growth. Here, we expanded this software to explore cell wall division (REMODELER 2). We found that simply organizing cell wall synthesis complexes at the midcell is not sufficient to cause invagination, even with the implementation of a make-before-break mechanism, in which new hoops of cell wall are made inside the existing hoops before bonds are cleaved. Division can occur, however, when a constrictive force brings the midcell into a compressed state before new hoops of relaxed cell wall are incorporated between existing hoops. Adding a make-before-break mechanism drives division with a smaller constrictive force sufficient to bring the midcell into a relaxed, but not necessarily compressed, state.

Published
2019
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46. γ-proteobacteria eject their polar flagella under nutrient depletion, retaining flagellar motor relic structures.

Author

Ferreira JL, Gao FZ, Rossmann FM, Nans A, Brenzinger S, Hosseini R, Wilson A, Briegel A, Thormann KM, Rosenthal PB, and Beeby M

Subjects
Flagella metabolism, Gammaproteobacteria metabolism, Plesiomonas metabolism, Plesiomonas pathogenicity, Pseudomonas aeruginosa metabolism, Pseudomonas aeruginosa pathogenicity, Shewanella putrefaciens metabolism, Shewanella putrefaciens pathogenicity, Vibrio cholerae metabolism, Vibrio cholerae pathogenicity, Gammaproteobacteria pathogenicity
Abstract

Bacteria switch only intermittently to motile planktonic lifestyles under favorable conditions. Under chronic nutrient deprivation, however, bacteria orchestrate a switch to stationary phase, conserving energy by altering metabolism and stopping motility. About two-thirds of bacteria use flagella to swim, but how bacteria deactivate this large molecular machine remains unclear. Here, we describe the previously unreported ejection of polar motors by γ-proteobacteria. We show that these bacteria eject their flagella at the base of the flagellar hook when nutrients are depleted, leaving a relic of a former flagellar motor in the outer membrane. Subtomogram averages of the full motor and relic reveal that this is an active process, as a plug protein appears in the relic, likely to prevent leakage across their outer membrane; furthermore, we show that ejection is triggered only under nutritional depletion and is independent of the filament as a possible mechanosensor. We show that filament ejection is a widespread phenomenon demonstrated by the appearance of relic structures in diverse γ-proteobacteria including Plesiomonas shigelloides, Vibrio cholerae, Vibrio fischeri, Shewanella putrefaciens, and Pseudomonas aeruginosa. While the molecular details remain to be determined, our results demonstrate a novel mechanism for bacteria to halt costly motility when nutrients become scarce., Competing Interests: The authors have declared that no competing interests exist.

Published
2019
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47. Giant flagellins form thick flagellar filaments in two species of marine γ-proteobacteria.

Author

Thomson NM, Ferreira JL, Matthews-Palmer TR, Beeby M, and Pallen MJ

Subjects
Biological Evolution, Flagella genetics, Flagella ultrastructure, Flagellin genetics, Flagellin ultrastructure, Gammaproteobacteria genetics, Gammaproteobacteria ultrastructure, Phylogeny, Repetitive Sequences, Nucleic Acid, Species Specificity, Flagella metabolism, Flagellin metabolism, Gammaproteobacteria metabolism
Abstract

Flagella, the primary means of motility in bacteria, are helical filaments that function as microscopic propellers composed of thousands of copies of the protein flagellin. Here, we show that many bacteria encode "giant" flagellins, greater than a thousand amino acids in length, and that two species that encode giant flagellins, the marine γ-proteobacteria Bermanella marisrubri and Oleibacter marinus, produce monopolar flagellar filaments considerably thicker than filaments composed of shorter flagellin monomers. We confirm that the flagellum from B. marisrubri is built from its giant flagellin. Phylogenetic analysis reveals that the mechanism of evolution of giant flagellins has followed a stepwise process involving an internal domain duplication followed by insertion of an additional novel insert. This work illustrates how "the" bacterial flagellum should not be seen as a single, idealised structure, but as a continuum of evolved machines adapted to a range of niches., Competing Interests: The authors have declared that no competing interests exist.

Published
2018
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48. Bacterial Flagellins: Does Size Matter?

Author

Thomson NM, Rossmann FM, Ferreira JL, Matthews-Palmer TR, Beeby M, and Pallen MJ

Subjects
Amino Acid Sequence, Amino Acids metabolism, Bacteria classification, Bacterial Physiological Phenomena, Bacterial Proteins metabolism, Biotechnology, Evolution, Molecular, Flagella chemistry, Flagella classification, Flagella ultrastructure, Flagellin classification, Flagellin genetics, Flagellin ultrastructure, Rhizobiaceae physiology, Bacteria metabolism, Flagella physiology, Flagellin chemistry
Abstract

The bacterial flagellum is the principal organelle of motility in bacteria. Here, we address the question of size when applied to the chief flagellar protein flagellin and the flagellar filament. Surprisingly, nature furnishes multiple examples of 'giant flagellins' greater than a thousand amino acids in length, with large surface-exposed hypervariable domains. We review the contexts in which these giant flagellins occur, speculate as to their functions, and highlight the potential for biotechnology to build on what nature provides., (Copyright © 2017. Published by Elsevier Ltd.)

Published
2018
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49. Insights into the evolution of bacterial flagellar motors from high-throughput in situ electron cryotomography and subtomogram averaging.

Author

Rossmann FM and Beeby M

Subjects
Bacterial Proteins chemistry, Flagella ultrastructure, Cryoelectron Microscopy methods, Electron Microscope Tomography methods, Evolution, Molecular, Flagella chemistry, Molecular Motor Proteins chemistry
Abstract

In situ structural information on molecular machines can be invaluable in understanding their assembly, mechanism and evolution. Here, the use of electron cryotomography (ECT) to obtain significant insights into how an archetypal molecular machine, the bacterial flagellar motor, functions and how it has evolved is described. Over the last decade, studies using a high-throughput, medium-resolution ECT approach combined with genetics, phylogenetic reconstruction and phenotypic analysis have revealed surprising structural diversity in flagellar motors. Variations in the size and the number of torque-generating proteins in the motor visualized for the first time using ECT has shown that these variations have enabled bacteria to adapt their swimming torque to the environment. Much of the structural diversity can be explained in terms of scaffold structures that facilitate the incorporation of additional motor proteins, and more recent studies have begun to infer evolutionary pathways to higher torque-producing motors. This review seeks to highlight how the emerging power of ECT has enabled the inference of ancestral states from various bacterial species towards understanding how, and `why', flagellar motors have evolved from an ancestral motor to a diversity of variants with adapted or modified functions., (open access.)

Published
2018
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50. Evolution of higher torque in Campylobacter-type bacterial flagellar motors.

Author

Chaban B, Coleman I, and Beeby M

Subjects
Bacterial Proteins genetics, Campylobacter classification, Campylobacter ultrastructure, Campylobacter jejuni physiology, Cell Membrane metabolism, Cell Membrane ultrastructure, Flagella ultrastructure, Molecular Motor Proteins genetics, Bacterial Proteins metabolism, Campylobacter physiology, Flagella physiology, Mechanical Phenomena, Molecular Motor Proteins metabolism
Abstract

Understanding the evolution of molecular machines underpins our understanding of the development of life on earth. A well-studied case are bacterial flagellar motors that spin helical propellers for bacterial motility. Diverse motors produce different torques, but how this diversity evolved remains unknown. To gain insights into evolution of the high-torque ε-proteobacterial motor exemplified by the Campylobacter jejuni motor, we inferred ancestral states by combining phylogenetics, electron cryotomography, and motility assays to characterize motors from Wolinella succinogenes, Arcobacter butzleri and Bdellovibrio bacteriovorus. Observation of ~12 stator complexes in many proteobacteria, yet ~17 in ε-proteobacteria suggest a "quantum leap" evolutionary event. Campylobacter-type motors have high stator occupancy in wider rings of additional stator complexes that are scaffolded by large proteinaceous periplasmic rings. We propose a model for motor evolution wherein independent inner- and outer-membrane structures fused to form a scaffold for additional stator complexes. Significantly, inner- and outer-membrane associated structures have evolved independently multiple times, suggesting that evolution of such structures is facile and poised the ε-proteobacteria to fuse them to form the high-torque Campylobacter-type motor.

Published
2018
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