Your search keyword '"Beeby M"' showing total 5 results

1. 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

2. 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

3. 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

4. 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

5. Communication across the bacterial cell envelope depends on the size of the periplasm.

Author

Asmar AT, Ferreira JL, Cohen EJ, Cho SH, Beeby M, Hughes KT, and Collet JF

Subjects

Cell Membrane metabolism, Cell Wall, Cytoplasm metabolism, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Gram-Negative Bacteria metabolism, Lipoproteins metabolism, Membrane Proteins metabolism, Membrane Proteins physiology, Peptidoglycan, Periplasm metabolism, Bacterial Outer Membrane Proteins metabolism, Bacterial Outer Membrane Proteins physiology, Periplasm physiology

Abstract

The cell envelope of gram-negative bacteria, a structure comprising an outer (OM) and an inner (IM) membrane, is essential for life. The OM and the IM are separated by the periplasm, a compartment that contains the peptidoglycan. The OM is tethered to the peptidoglycan via the lipoprotein, Lpp. However, the importance of the envelope's multilayered architecture remains unknown. Here, when we removed physical coupling between the OM and the peptidoglycan, cells lost the ability to sense defects in envelope integrity. Further experiments revealed that the critical parameter for the transmission of stress signals from the envelope to the cytoplasm, where cellular behaviour is controlled, is the IM-to-OM distance. Augmenting this distance by increasing the length of the lipoprotein Lpp destroyed signalling, whereas simultaneously increasing the length of the stress-sensing lipoprotein RcsF restored signalling. Our results demonstrate the physiological importance of the size of the periplasm. They also reveal that strict control over the IM-to-OM distance is required for effective envelope surveillance and protection, suggesting that cellular architecture and the structure of transenvelope protein complexes have been evolutionarily co-optimised for correct function. Similar strategies are likely at play in cellular compartments surrounded by 2 concentric membranes, such as chloroplasts and mitochondria.

Published

2017