A Molecularly Complete Planar Bacterial Outer Membrane Platform

Hsia, Chih‐Yun; Chen, Linxiao; Singh, Rohit; DeLisa, Matthew P.; Daniel, Susan

doi:10.1038/srep32715

Cited by 51 publications

(90 citation statements)

References 62 publications

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“…The result is consistent with previous studies, which showed at least ∼2 mM of Ca 2+ is necessary for the formation of PLE-SLB on SiO 2 /Si, mica, TiO 2 , indium tin oxide and gold (Dodd et al, 2008;Merz et al, 2008;Lopes et al, 2010;Unsay et al, 2013;Lind et al, 2015;Hsia et al, 2016;Konarzewska et al, 2017;Márquez and Vélez, 2017). In the previous studies of the bacterial mimic lipid bilayer, however, averaged response from the sample was mainly obtained using QCM and fluorescence microscopy (Dodd et al, 2008;Merz et al, 2008;Lopes et al, 2010;Unsay et al, 2013;Lind et al, 2015;Phan and Shin, 2015;Hsia et al, 2016;Konarzewska et al, 2017;Márquez and Vélez, 2017). The results in this study showed the heterogeneity of SLB especially at the threshold [Ca 2+ ] around 2.5 mM.…”

Section: Resultssupporting

confidence: 93%

“…As a bacterial model cell system, reconstituted Escherichia coli (E. coli) cell membrane has been studied (Dodd et al, 2008;Merz et al, 2008;Lopes et al, 2010;Unsay et al, 2013;Lind et al, 2015;Phan and Shin, 2015;Hsia et al, 2016;Konarzewska et al, 2017;Márquez and Vélez, 2017). Understanding the bacterial membrane system helps in revealing the mechanism of molecular recognition and material transportation during bacterial infection for medical technology.…”

Section: Introductionmentioning

confidence: 99%

“…There are several previous studies on the formation of SLBs containing E. coli lipids such as polar lipid extract (PLE) or total lipid extract (TLE) (Dodd et al, 2008;Merz et al, 2008;Lopes et al, 2010;Unsay et al, 2013;Lind et al, 2015;Hsia et al, 2016;Konarzewska et al, 2017;Márquez and Vélez, 2017). Solid substrates, which are generally used for SLB formation, e.g., glass, oxidized layer on a Si wafer, and mica, are negatively charged.…”

Section: Introductionmentioning

confidence: 99%

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Supported Lipid Bilayers of Escherichia coli Extracted Lipids and Their Calcium Dependence

Kakimoto

Tero

2018

Front. Mater.

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Formation of supported lipid bilayer (SLB) and additional structures of Escherichia coli (E. coli) lipids were investigated with fluorescence microscopy and atomic force microscopy. Ca 2+ in the aqueous phase with concentration above 2 mM was necessary for the formation of SLB. Additional lipid structures, string-like structures, the second lipid bilayer, and multilayer stacking appeared on the first layer SLB depending on Ca 2+ concentration. The bridging effect of Ca 2+ between the negatively charged E. coli lipid bilayers and substrate is the dominant factor determining the two-dimensional and three-dimensional morphology of the E. coli lipid bilayer membranes.

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Section: Resultssupporting

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Supported Lipid Bilayers of Escherichia coli Extracted Lipids and Their Calcium Dependence

Kakimoto

Tero

2018

Front. Mater.

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“…However, recent progresses in the development of supported asymmetric bilayers made OM models amenable to characterization via structural techniques. [18][19][20] The first MD simulation of a bacterial outer membrane was performed for the rough LPS of Pseudomonas aeruginosa using the GLYCAM93 21 and AMBER95 22 atomic parameters to describe carbohydrate and lipid moieties, respectively. 23 The simulated bilayer consisted of 16 LPS units in the outer leaflet, 40 DPPE (1,2-dipalmitoyl-sn-glycero-3-phosphoethanolamine) units in the inner leaflet and a total of 104 Ca 2+ to neutralize the system.…”

Section: Introductionmentioning

confidence: 99%

Compatibility of GROMOS-Derived Atomic Parameters for Lipopolysaccharide Membranes with the SPC/E Water Model and Alternative Long-Range Electrostatic Treatments Using Single Nonbonded Cutoff and Atom-Based Charge Schemes

Lima

Nader

Santos

et al. 2019

J. Braz. Chem. Soc.

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Recent developments of GROMACS v.2016 ceased to support methodological approaches used in the development and validation of the GROMOS force field. We investigated the performance of a previously developed extension of the GROMOS force field for lipopolysaccharides to reproduce the structural dynamics of bacterial outer membrane (OM) using a single cutoff for nonbonded interactions and atom-based charge truncation. We further compared this setup for use with reaction field (RF) or particle mesh Ewald (PME) approximations in the presence of simple point charge (SPC) and extended simple point charge (SPC/E) water models. We find that the OM structural dynamics is well conserved in all simulated conditions, reproducing the available experimental data within the measurement uncertainty. The SPC/E model induces a small increase in OM fluidity, and when combined with the RF correction, shows a decrease in water orientation at the membrane surface. The present simulations support the compatibility of the GROMOS-derived lipopolysaccharide (LPS) parameters for use with single cutoff and atom-based charge schemes, either with RF or PME approximations, in GROMACS v.2016. Both SPC and SPC/E water models are suitable for use, but usage of SPC/E combined with the reaction field correction needs to be further investigated.

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“…Typically, polymyxins bind to lipids in the bacterial membrane via electrostatic interactions. Hydrophobic interactions between their N ‐terminal fatty acid tail and the membrane fatty acid lipid tails lead to insertion, membrane destabilization, and cell lysis . Electrostatic interactions are responsible for the initial binding of the antibacterial compound to the anionic surface of the bacteria.…”

mentioning

confidence: 99%

Biomimetic Electronic Devices for Measuring Bacterial Membrane Disruption

Pitsalidis¹,

Pappa²,

Porel

et al. 2018

Advanced Materials

Self Cite

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Antibiotic discovery has experienced a severe slowdown in terms of discovery of new candidates. In vitro screening methods using phospholipids to model the bacterial membrane provide a route to identify molecules that specifically disrupt bacterial membranes causing cell death. Thanks to the electrically insulating properties of the major component of the cell membrane, phospholipids, electronic devices are highly suitable transducers of membrane disruption. The organic electrochemical transistor (OECT) is a highly sensitive ion-to-electron converter. Here, the OECT is used as a transducer of the permeability of a lipid monolayer (ML) at a liquid:liquid interface, designed to read out changes in ion flux caused by compounds that interact with, and disrupt, lipid assembly. This concept is illustrated using the well-documented antibiotic Polymixin B and the highly sensitive quantitation of permeability of the lipid ML induced by two novel recently described antibacterial amine-based oligothioetheramides is shown, highlighting molecular scale differences in their disruption capabilities. It is anticipated that this platform has the potential to play a role in front-line antimicrobial compound design and characterization thanks to the compatibility of semiconductor microfabrication technology with high-throughput readouts.

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A Molecularly Complete Planar Bacterial Outer Membrane Platform

Cited by 51 publications

References 62 publications

Supported Lipid Bilayers of Escherichia coli Extracted Lipids and Their Calcium Dependence

Supported Lipid Bilayers of Escherichia coli Extracted Lipids and Their Calcium Dependence

Compatibility of GROMOS-Derived Atomic Parameters for Lipopolysaccharide Membranes with the SPC/E Water Model and Alternative Long-Range Electrostatic Treatments Using Single Nonbonded Cutoff and Atom-Based Charge Schemes

Biomimetic Electronic Devices for Measuring Bacterial Membrane Disruption

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