Your search keyword '"Ces, Oscar"' showing total 300 results

251. Magnetic Modulation of Biochemical Synthesis in Synthetic Cells.

Author

Zhu KK, Gispert Contamina I, Ces O, Barter LMC, Hindley JW, and Elani Y

Subjects

Magnetite Nanoparticles chemistry, Artificial Cells chemistry, Artificial Cells metabolism, Magnetic Fields

Abstract

Synthetic cells can be constructed from diverse molecular components, without the design constraints associated with modifying 'living' biological systems. This can be exploited to generate cells with abiotic components, creating functionalities absent in biology. One example is magnetic responsiveness, the activation and modulation of encapsulated biochemical processes using a magnetic field, which is absent from existing synthetic cell designs. This is a critical oversight, as magnetic fields are uniquely bio-orthogonal, noninvasive, and highly penetrative. Here, we address this by producing artificial magneto-responsive organelles by coupling thermoresponsive membranes with hyperthermic Fe 3 O 4 nanoparticles and embedding them in synthetic cells. Combining these systems enables synthetic cell microreactors to be built using a nested vesicle architecture, which can respond to alternating magnetic fields through in situ enzymatic catalysis. We also demonstrate the modulation of biochemical reactions by using different magnetic field strengths and the potential to tune the system using different lipid compositions. This platform could unlock a wide range of applications for synthetic cells as programmable micromachines in biomedicine and biotechnology.

Published

2024

252. The effect of hydrostatic pressure on lipid membrane lateral structure.

Author

McCarthy NLC, Chan CL, Mignini Urdaneta GECM, Liao Y, Law RV, Ces O, Seddon JM, and Brooks NJ

Subjects

Scattering, Small Angle, Membrane Lipids chemistry, Membrane Lipids metabolism, Thermodynamics, Hydrostatic Pressure, X-Ray Diffraction methods, Lipid Bilayers chemistry, Lipid Bilayers metabolism

Abstract

High pressure is both an environmental challenge to which deep sea biology has to adapt, and a highly sensitive thermodynamic tool that can be used to trigger structural changes in biological molecules and assemblies. Lipid membranes are amongst the most pressure sensitive biological assemblies and pressure can have a large influence on their structure and properties. In this chapter, we will explore the use of high pressure small angle X-ray diffraction and high pressure microscopy to measure and quantify changes in the lateral structure of lipid membranes under both equilibrium high pressure conditions and in response to pressure jumps., (Copyright © 2024. Published by Elsevier Inc.)

Published

2024

253. Biomimetic behaviors in hydrogel artificial cells through embedded organelles.

Author

Allen ME, Hindley JW, O'Toole N, Cooke HS, Contini C, Law RV, Ces O, and Elani Y

Subjects

Hydrogels, Communication, Organelles, Biomimetics, Artificial Cells

Abstract

Artificial cells are biomimetic structures formed from molecular building blocks that replicate biological processes, behaviors, and architectures. Of these building blocks, hydrogels have emerged as ideal, yet underutilized candidates to provide a gel-like chassis in which to incorporate both biological and nonbiological componentry which enables the replication of cellular functionality. Here, we demonstrate a microfluidic strategy to assemble biocompatible cell-sized hydrogel-based artificial cells with a variety of different embedded functional subcompartments, which act as engineered synthetic organelles. The organelles enable the recreation of increasingly biomimetic behaviors, including stimulus-induced motility, content release through activation of membrane-associated proteins, and enzymatic communication with surrounding bioinspired compartments. In this way, we showcase a foundational strategy for the bottom-up construction of hydrogel-based artificial cell microsystems which replicate fundamental cellular behaviors, paving the way for the construction of next-generation biotechnological devices.

Published

2023

254. Measuring Encapsulation Efficiency in Cell-Mimicking Giant Unilamellar Vesicles.

Author

Supramaniam P, Wang Z, Chatzimichail S, Parperis C, Kumar A, Ho V, Ces O, and Salehi-Reyhani A

Subjects

Microfluidics methods, Synthetic Biology, Emulsions, Unilamellar Liposomes chemistry, Artificial Cells

Abstract

One of the main drivers within the field of bottom-up synthetic biology is to develop artificial chemical machines, perhaps even living systems, that have programmable functionality. Numerous toolkits exist to generate giant unilamellar vesicle-based artificial cells. However, methods able to quantitatively measure their molecular constituents upon formation is an underdeveloped area. We report an artificial cell quality control (AC/QC) protocol using a microfluidic-based single-molecule approach, enabling the absolute quantification of encapsulated biomolecules. While the measured average encapsulation efficiency was 11.4 ± 6.8%, the AC/QC method allowed us to determine encapsulation efficiencies per vesicle, which varied significantly from 2.4 to 41%. We show that it is possible to achieve a desired concentration of biomolecule within each vesicle by commensurate compensation of its concentration in the seed emulsion. However, the variability in encapsulation efficiency suggests caution is necessary when using such vesicles as simplified biological models or standards.

Published

2023

255. Stimuli-responsive vesicles as distributed artificial organelles for bacterial activation.

Author

Gispert I, Hindley JW, Pilkington CP, Shree H, Barter LMC, Ces O, and Elani Y

Subjects

Bacteria, Organelles metabolism, Synthetic Biology, Artificial Cells chemistry, Biological Phenomena

Abstract

Intercellular communication is a hallmark of living systems. As such, engineering artificial cells that possess this behavior has been at the heart of activities in bottom-up synthetic biology. Communication between artificial and living cells has potential to confer novel capabilities to living organisms that could be exploited in biomedicine and biotechnology. However, most current approaches rely on the exchange of chemical signals that cannot be externally controlled. Here, we report two types of remote-controlled vesicle-based artificial organelles that translate physical inputs into chemical messages that lead to bacterial activation. Upon light or temperature stimulation, artificial cell membranes are activated, releasing signaling molecules that induce protein expression in Escherichia coli . This distributed approach differs from established methods for engineering stimuli-responsive bacteria. Here, artificial cells (as opposed to bacterial cells themselves) are the design unit. Having stimuli-responsive elements compartmentalized in artificial cells has potential applications in therapeutics, tissue engineering, and bioremediation. It will underpin the design of hybrid living/nonliving systems where temporal control over population interactions can be exerted.

Published

2022

256. Hydrogels as functional components in artificial cell systems.

Author

Allen ME, Hindley JW, Baxani DK, Ces O, and Elani Y

Subjects

Hydrogels therapeutic use, Tissue Engineering, Biocompatible Materials therapeutic use, Artificial Cells, Biomimetic Materials

Abstract

Recent years have seen substantial efforts aimed at constructing artificial cells from various molecular components with the aim of mimicking the processes, behaviours and architectures found in biological systems. Artificial cell development ultimately aims to produce model constructs that progress our understanding of biology, as well as forming the basis for functional bio-inspired devices that can be used in fields such as therapeutic delivery, biosensing, cell therapy and bioremediation. Typically, artificial cells rely on a bilayer membrane chassis and have fluid aqueous interiors to mimic biological cells. However, a desire to more accurately replicate the gel-like properties of intracellular and extracellular biological environments has driven increasing efforts to build cell mimics based on hydrogels. This has enabled researchers to exploit some of the unique functional properties of hydrogels that have seen them deployed in fields such as tissue engineering, biomaterials and drug delivery. In this Review, we explore how hydrogels can be leveraged in the context of artificial cell development. We also discuss how hydrogels can potentially be incorporated within the next generation of artificial cells to engineer improved biological mimics and functional microsystems., (© 2022. Springer Nature Limited.)

Published

2022

257. Dynamic Reconfiguration of Subcompartment Architectures in Artificial Cells.

Author

Zubaite G, Hindley JW, Ces O, and Elani Y

Subjects

Organelles metabolism, Membranes, Artificial, Cell Membrane, Artificial Cells

Abstract

Artificial cells are minimal structures constructed from biomolecular building blocks designed to mimic cellular processes, behaviors, and architectures. One near-ubiquitous feature of cellular life is the spatial organization of internal content. We know from biology that organization of content (including in membrane-bound organelles) is linked to cellular functions and that this feature is dynamic: the presence, location, and degree of compartmentalization changes over time. Vesicle-based artificial cells, however, are not currently able to mimic this fundamental cellular property. Here, we describe an artificial cell design strategy that addresses this technological bottleneck. We create a series of artificial cell architectures which possess multicompartment assemblies localized either on the inner or on the outer surface of the artificial cell membrane. Exploiting liquid-liquid phase separation, we can also engineer spatially segregated regions of condensed subcompartments attached to the cell surface, aligning with coexisting membrane domains. These structures can sense changes in environmental conditions and respond by reversibly transitioning from condensed multicompartment layers on the membrane surface to a dispersed state in the cell lumen, mimicking the dynamic compartmentalization found in biological cells. Likewise, we engineer exosome-like subcompartments that can be released to the environment. We can achieve this by using two types of triggers: chemical (addition of salts) and mechanical (by pulling membrane tethers using optical traps). These approaches allow us to control the compartmentalization state of artificial cells on population and single-cell levels.

Published

2022

258. UV-DIB: label-free permeability determination using droplet interface bilayers.

Author

Strutt R, Sheffield F, Barlow NE, Flemming AJ, Harling JD, Law RV, Brooks NJ, Barter LMC, and Ces O

Subjects

Diffusion, Kinetics, Permeability, Lipid Bilayers chemistry, Phospholipids chemistry

Abstract

Simple diffusion of molecular entities through a phospholipid bilayer, is a phenomenon of great importance to the pharmaceutical and agricultural industries. Current model lipid systems to probe this typically only employ fluorescence as a readout, thus limiting the range of assessable chemical matter that can be studied. We report a new technology platform, the UV-DIB, which facilitates label free measurement of small molecule translocation rates. This is based upon the coupling of droplet interface bilayer technology with implemented fiber optics to facilitate analysis via ultraviolet spectroscopy, in custom designed PMMA wells. To improve on current DIB technology, the platform was designed to be reusable, with a high sampling rate and a limit of UV detection in the low μM regime. We demonstrate the use of our system to quantify passive diffusion in a reproducible and rapid manner where the system was validated by investigating multiple permeants of varying physicochemical properties across a range of lipid interfaces, each demonstrating differing kinetics. Our system permits the interrogation of structural dependence on the permeation rate of a given compound. We present this ability from two structural perspectives, that of the membrane, and the permeant. We observed a reduction in permeability between pure DOPC and DPhPC interfaces, concurring with literature and demonstrating our ability to study the effects of lipid composition on permeability. In relation to the effects of permeant structure, our device facilitated the rank ordering of various compounds from the xanthine class of compounds, where the structure of each permeant differed by a single group alteration. We found that DIBs were stable up to 5% DMSO, a molecule often used to aid solubilisation of pharmaceutical and agrochemical compounds. The ability of our device to rank-order compounds with such minor structural differences provides a level of precision that is rarely seen in current, industrially applied technologies.

Published

2022

259. Molecular interaction and partitioning in α-keratin using 1 H NMR spin-lattice ( T 1 ) relaxation times.

Author

Molisso S, Williams DR, Ces O, Rowlands LJ, Marsh JM, and Law RV

Subjects

Humans, Magnetic Resonance Spectroscopy, Molecular Weight, Proton Magnetic Resonance Spectroscopy, Hair, Keratins

Abstract

The interactions between small molecules and keratins are poorly understood. In this paper, a nuclear magnetic resonance method is presented to measure changes in the 1 H T 1 relaxation times of small molecules in human hair keratin to quantify their interaction with the fibre. Two populations of small-molecule compounds were identified with distinct relaxation times, demonstrating the partitioning of the compounds into different keratin environments. The changes in relaxation time for solvent in hair compared with bulk solvent were shown to be related to the molecular weight (MW) and the partition coefficient, LogP, of the solvent investigated. Compounds with low MWs and high hydrophilicities had greater reductions in their T 1 relaxation times and therefore experienced increased interactions with the hair fibre. The relative population sizes were also calculated. This is a significant step towards modelling the behaviour of small molecules in keratinous materials and other large insoluble fibrous proteins.

Published

2021

260. The membrane transporter lactose permease increases lipid bilayer bending rigidity.

Author

Lopez Mora N, Findlay HE, Brooks NJ, Purushothaman S, Ces O, and Booth PJ

Subjects

Membrane Transport Proteins, Unilamellar Liposomes, Lipid Bilayers, Phosphatidylcholines

Abstract

Cellular life relies on membranes, which provide a resilient and adaptive cell boundary. Many essential processes depend upon the ease with which the membrane is able to deform and bend, features that can be characterized by the bending rigidity. Quantitative investigations of such mechanical properties of biological membranes have primarily been undertaken in solely lipid bilayers and frequently in the absence of buffers. In contrast, much less is known about the influence of integral membrane proteins on bending rigidity under physiological conditions. We focus on an exemplar member of the ubiquitous major facilitator superfamily of transporters and assess the influence of lactose permease on the bending rigidity of lipid bilayers. Fluctuation analysis of giant unilamellar vesicles (GUVs) is a useful means to measure bending rigidity. We find that using a hydrogel substrate produces GUVs that are well suited to fluctuation analysis. Moreover, the hydrogel method is amenable to both physiological salt concentrations and anionic lipids, which are important to mimic key aspects of the native lactose permease membrane. Varying the fraction of the anionic lipid in the lipid mixture DOPC/DOPE/DOPG allows us to assess the dependence of membrane bending rigidity on the topology and concentration of an integral membrane protein in the lipid bilayer of GUVs. The bending rigidity gradually increases with the incorporation of lactose permease, but there is no further increase with greater amounts of the protein in the membrane., (Copyright © 2021 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2021

261. Engineering motile aqueous phase-separated droplets via liposome stabilisation.

Author

Zhang S, Contini C, Hindley JW, Bolognesi G, Elani Y, and Ces O

Subjects

Chemotaxis, Dextrans chemistry, Emulsions, Motion, Particle Size, Polyethylene Glycols chemistry, Water, Liposomes chemistry

Abstract

There are increasing efforts to engineer functional compartments that mimic cellular behaviours from the bottom-up. One behaviour that is receiving particular attention is motility, due to its biotechnological potential and ubiquity in living systems. Many existing platforms make use of the Marangoni effect to achieve motion in water/oil (w/o) droplet systems. However, most of these systems are unsuitable for biological applications due to biocompatibility issues caused by the presence of oil phases. Here we report a biocompatible all aqueous (w/w) PEG/dextran Pickering-like emulsion system consisting of liposome-stabilised cell-sized droplets, where the stability can be easily tuned by adjusting liposome composition and concentration. We demonstrate that the compartments are capable of negative chemotaxis: these droplets can respond to a PEG/dextran polymer gradient through directional motion down to the gradient. The biocompatibility, motility and partitioning abilities of this droplet system offers new directions to pursue research in motion-related biological processes.

Published

2021

262. Design, Development and Optimization of a Functional Mammalian Cell-Free Protein Synthesis Platform.

Author

Heide C, Buldum G, Moya-Ramirez I, Ces O, Kontoravdi C, and Polizzi KM

Abstract

In this paper, we describe the stepwise development of a cell-free protein synthesis (CFPS) platform derived from cultured Chinese hamster ovary (CHO) cells. We provide a retrospective summary of the design challenges we faced, and the optimized methods developed for the cultivation of cells and the preparation of translationally active lysates. To overcome low yields, we developed procedures to supplement two accessory proteins, GADD34 and K3L, into the reaction to prevent deactivation of the translational machinery by phosphorylation. We compared different strategies for implementing these accessory proteins including two variants of the GADD34 protein to understand the potential trade-offs between yield and ease of implementation. Addition of the accessory proteins increased yield of turbo Green Fluorescent Protein (tGFP) by up to 100-fold depending on which workflow was used. Using our optimized protocols as a guideline, users can successfully develop their own functional CHO CFPS system, allowing for broader application of mammalian CFPS., 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 Heide, Buldum, Moya-Ramirez, Ces, Kontoravdi and Polizzi.)

Published

2021

263. Activating mechanosensitive channels embedded in droplet interface bilayers using membrane asymmetry.

Author

Strutt R, Hindley JW, Gregg J, Booth PJ, Harling JD, Law RV, Friddin MS, and Ces O

Abstract

Droplet microcompartments linked by lipid bilayers show great promise in the construction of synthetic minimal tissues. Central to controlling the flow of information in these systems are membrane proteins, which can gate in response to specific stimuli in order to control the molecular flux between membrane separated compartments. This has been demonstrated with droplet interface bilayers (DIBs) using several different membrane proteins combined with electrical, mechanical, and/or chemical activators. Here we report the activation of the bacterial mechanosensitive channel of large conductance (MscL) in a dioleoylphosphatidylcholine:dioleoylphosphatidylglycerol DIB by controlling membrane asymmetry. We show using electrical measurements that the incorporation of lysophosphatidylcholine (LPC) into one of the bilayer leaflets triggers MscL gating in a concentration-dependent manner, with partial and full activation observed at 10 and 15 mol% LPC respectively. Our findings could inspire the design of new minimal tissues where flux pathways are dynamically defined by lipid composition., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2021

264. Controlled Dendrimersome Nanoreactor System for Localized Hypochlorite-Induced Killing of Bacteria.

Author

Potter M, Najer A, Klöckner A, Zhang S, Holme MN, Nele V, Che J, Massi L, Penders J, Saunders C, Doutch JJ, Edwards AM, Ces O, and Stevens MM

Abstract

Antibiotic resistance is a serious global health problem necessitating new bactericidal approaches such as nanomedicines. Dendrimersomes (DSs) have recently become a valuable alternative nanocarrier to polymersomes and liposomes due to their molecular definition and synthetic versatility. Despite this, their biomedical application is still in its infancy. Inspired by the localized antimicrobial function of neutrophil phagosomes and the versatility of DSs, a simple three-component DS-based nanoreactor with broad-spectrum bactericidal activity is presented. This was achieved by encapsulation of glucose oxidase (GOX) and myeloperoxidase (MPO) within DSs (GOX-MPO-DSs), self-assembled from an amphiphilic Janus dendrimer, that possesses a semipermeable membrane. By external addition of glucose to GOX-MPO-DS, the production of hypochlorite ( - OCl), a highly potent antimicrobial, by the enzymatic cascade was demonstrated. This cascade nanoreactor yielded a potent bactericidal effect against two important multidrug resistant pathogens, Staphylococcus aureus ( S. aureus ) and Pseudomonas aeruginosa ( P. aeruginosa ), not observed for H 2 O 2 producing nanoreactors, GOX-DS. The production of highly reactive species such as - OCl represents a harsh bactericidal approach that could also be cytotoxic to mammalian cells. This necessitates the development of strategies for activating - OCl production in a localized manner in response to a bacterial stimulus. One option of locally releasing sufficient amounts of substrate using a bacterial trigger (released toxins) was demonstrated with lipidic glucose-loaded giant unilamellar vesicles (GUVs), envisioning, e.g ., implant surface modification with nanoreactors and GUVs for localized production of bactericidal agents in the presence of bacterial growth.

Published

2020

265. Engineering Swollen Cubosomes Using Cholesterol and Anionic Lipids.

Author

Barriga HMG, Ces O, Law RV, Seddon JM, and Brooks NJ

Subjects

Cholesterol chemistry, Engineering, Glycerophospholipids chemistry

Abstract

Dispersions of nonlamellar lipid membrane assemblies are gaining increasing interest for drug delivery and protein therapeutic application. A key bottleneck has been the lack of rational design rules for these systems linking different lipid species and conditions to defined lattice parameters and structures. We have developed robust methods to form cubosomes (nanoparticles with porous internal structures) with water channel diameters of up to 171 Å, which are over 4 times larger than archetypal cubosome structures. The water channel diameter can be tuned via the incorporation of cholesterol and the charged lipid DOPA, DOPG, or DOPS. We have found that large molecules can be incorporated into the porous cubosome structure and that these molecules can interact with the internal cubosome membrane. This offers huge potential for accessible encapsulation and protection of biomolecules and development of confined interfacial reaction environments.

Published

2019

266. New Directions for Artificial Cells Using Prototyped Biosystems.

Author

Friddin MS, Elani Y, Trantidou T, and Ces O

Subjects

Engineering, Humans, Lab-On-A-Chip Devices, Artificial Cells

Abstract

Microfluidics has has enabled the generation of  a range of single compartment and multicompartment vesicles and bilayer-delineated droplets that can be assembled in 2D and 3D. These model systems are becoming increasingly used as artificial cell chassis and as biomimetic constructs for assembling tissue models, engineering therapeutic delivery systems, and screening drugs. One bottleneck in developing this technology is the time, expertise, and equipment required for device fabrication. This has led to interest across the microfluidics community in using rapid prototyping to engineer microfluidic devices from computer-aided-design (CAD) drawings. We highlight how this rapid-prototyping revolution is transforming the fabrication of microfluidic devices for artificial cell construction in bottom-up synthetic biology. We provide an outline of the current landscape and present how advances in the field may give rise to the next generation of multifunctional biodevices, particularly with Industry 4.0 on the horizon. Successfully developing this technology and making it open-source could pave the way for a new generation of citizen-led science, fueling the possibility that the next multibillion-dollar start-up could emerge from an attic or a basement.

Published

2019

267. Community building in synthetic biology.

Author

Ces O and Elani Y

Subjects

Interdisciplinary Studies, Periodicals as Topic, Residence Characteristics, Synthetic Biology

Published

2019

268. Mask-Free Laser Lithography for Rapid and Low-Cost Microfluidic Device Fabrication.

Author

Trantidou T, Friddin MS, Gan KB, Han L, Bolognesi G, Brooks NJ, and Ces O

Abstract

Microfluidics has become recognized as a powerful platform technology associated with a constantly increasing array of applications across the life sciences. This surge of interest over recent years has led to an increased demand for microfluidic chips, resulting in more time being spent in the cleanroom fabricating devices using soft lithography-a slow and expensive process that requires extensive materials, training and significant engineering resources. This bottleneck limits platform complexity as a byproduct of lengthy delays between device iterations and affects the time spent developing the final application. To address this problem, we report a new, rapid, and economical approach to microfluidic device fabrication using dry resist films to laminate laser cut sheets of acrylic. We term our method laser lithography and show that our technique can be used to engineer 200 μm width channels for assembling droplet generators capable of generating monodisperse water droplets in oil and micromixers designed to sustain chemical reactions. Our devices offer high transparency, negligible device to device variation, and low X-ray background scattering, demonstrating their suitability for real-time X-ray-based characterization applications. Our approach also requires minimal materials and apparatus, is cleanroom free, and at a cost of around $1.00 per chip could significantly democratize device fabrication, thereby increasing the interdisciplinary accessibility of microfluidics.

Published

2018

269. Measuring bilayer surface energy and curvature in asymmetric droplet interface bilayers.

Author

Barlow NE, Kusumaatmaja H, Salehi-Reyhani A, Brooks N, Barter LMC, Flemming AJ, and Ces O

Subjects

Surface Tension, Lipid Bilayers chemistry, Models, Chemical, Phosphatidylcholines chemistry, Phosphatidylglycerols chemistry

Abstract

For the past decade, droplet interface bilayers (DIBs) have had an increased prevalence in biomolecular and biophysical literature. However, much of the underlying physics of these platforms is poorly characterized. To further our understanding of these structures, lipid membrane tension on DIB membranes is measured by analysing the equilibrium shape of asymmetric DIBs. To this end, the morphology of DIBs is explored for the first time using confocal laser scanning fluorescence microscopy. The experimental results confirm that, in accordance with theory, the bilayer interface of a volume-asymmetric DIB is curved towards the smaller droplet and a lipid-asymmetric DIB is curved towards the droplet with the higher monolayer surface tension. Moreover, the DIB shape can be exploited to measure complex bilayer surface energies. In this study, the bilayer surface energy of DIBs composed of lipid mixtures of phosphatidylgylcerol (PG) and phosphatidylcholine are shown to increase linearly with PG concentrations up to 25%. The assumption that DIB bilayer area can be geometrically approximated as a spherical cap base is also tested, and it is discovered that the bilayer curvature is negligible for most practical symmetric or asymmetric DIB systems with respect to bilayer area., (© 2018 The Authors.)

Published

2018

270. Functionalizing cell-mimetic giant vesicles with encapsulated bacterial biosensors.

Author

Trantidou T, Dekker L, Polizzi K, Ces O, and Elani Y

Abstract

The design of vesicle microsystems as artificial cells (bottom-up synthetic biology) has traditionally relied on the incorporation of molecular components to impart functionality. These cell mimics have reduced capabilities compared with their engineered biological counterparts (top-down synthetic biology), as they lack the powerful metabolic and regulatory pathways associated with living systems. There is increasing scope for using whole intact cellular components as functional modules within artificial cells, as a route to increase the capabilities of artificial cells. In this feasibility study, we design and embed genetically engineered microbes ( Escherichia coli ) in a vesicle-based cell mimic and use them as biosensing modules for real-time monitoring of lactate in the external environment. Using this conceptual framework, the functionality of other microbial devices can be conferred into vesicle microsystems in the future, bridging the gap between bottom-up and top-down synthetic biology., Competing Interests: The authors have no competing interests.

Published

2018

271. Micropatterning of planar metal electrodes by vacuum filling microfluidic channel geometries.

Author

Chatzimichail S, Supramaniam P, Ces O, and Salehi-Reyhani A

Abstract

We present a simple, facile method to micropattern planar metal electrodes defined by the geometry of a microfluidic channel network template. By introducing aqueous solutions of metal into reversibly adhered PDMS devices by desiccation instead of flow, we are able to produce difficult to pattern "dead end" or discontinuous features with ease. We characterize electrodes fabricated using this method and perform electrical lysis of mammalian cancer cells and demonstrate their use as part of an antibody capture assay for GFP. Cell lysis in microwell arrays is achieved using the electrodes and the protein released is detected using an antibody microarray. We show how the template channels used as part of the workflow for patterning the electrodes may be produced using photolithography-free methods, such as laser micromachining and PDMS master moulding, and demonstrate how the use of an immiscible phase may be employed to create electrode spacings on the order of 25-50 μm, that overcome the current resolution limits of such methods. This work demonstrates how the rapid prototyping of electrodes for use in total analysis systems can be achieved on the bench with little or no need for centralized facilities.

Published

2018

272. Counting Proteins in Single Cells with Addressable Droplet Microarrays.

Author

Chatzimichail S, Supramaniam P, Ces O, and Salehi-Reyhani A

Subjects

Humans, Microarray Analysis methods, Nanotechnology methods, Proteins metabolism, Single-Cell Analysis methods

Abstract

Often cellular behavior and cellular responses are analyzed at the population level where the responses of many cells are pooled together as an average result masking the rich single cell behavior within a complex population. Single cell protein detection and quantification technologies have made a remarkable impact in recent years. Here we describe a practical and flexible single cell analysis platform based on addressable droplet microarrays. This study describes how the absolute copy numbers of target proteins may be measured with single cell resolution. The tumor suppressor p53 is the most commonly mutated gene in human cancer, with more than 50% of total cancer cases exhibiting a non-healthy p53 expression pattern. The protocol describes steps to create 10 nL droplets within which single human cancer cells are isolated and the copy number of p53 protein is measured with single molecule resolution to precisely determine the variability in expression. The method may be applied to any cell type including primary material to determine the absolute copy number of any target proteins of interest.

Published

2018

273. Sculpting and fusing biomimetic vesicle networks using optical tweezers.

Author

Bolognesi G, Friddin MS, Salehi-Reyhani A, Barlow NE, Brooks NJ, Ces O, and Elani Y

Subjects

Amino Acids metabolism, Bacterial Toxins metabolism, Biological Transport, Biomimetic Materials metabolism, Carbocyanines chemistry, Carbocyanines metabolism, Gene Expression, Green Fluorescent Proteins metabolism, Hemolysin Proteins metabolism, Lasers, Lipid Bilayers metabolism, Membrane Fusion, Optical Tweezers, Phosphatidylcholines chemistry, Phosphatidylcholines metabolism, Phosphatidylethanolamines chemistry, Phosphatidylethanolamines metabolism, RNA, Transfer metabolism, Ribonucleotides genetics, Ribonucleotides metabolism, Sodium Chloride chemistry, Amino Acids genetics, Bacterial Toxins chemistry, Biomimetic Materials chemistry, Green Fluorescent Proteins genetics, Hemolysin Proteins chemistry, Lipid Bilayers chemistry, RNA, Transfer genetics

Abstract

Constructing higher-order vesicle assemblies has discipline-spanning potential from responsive soft-matter materials to artificial cell networks in synthetic biology. This potential is ultimately derived from the ability to compartmentalise and order chemical species in space. To unlock such applications, spatial organisation of vesicles in relation to one another must be controlled, and techniques to deliver cargo to compartments developed. Herein, we use optical tweezers to assemble, reconfigure and dismantle networks of cell-sized vesicles that, in different experimental scenarios, we engineer to exhibit several interesting properties. Vesicles are connected through double-bilayer junctions formed via electrostatically controlled adhesion. Chemically distinct vesicles are linked across length scales, from several nanometres to hundreds of micrometres, by axon-like tethers. In the former regime, patterning membranes with proteins and nanoparticles facilitates material exchange between compartments and enables laser-triggered vesicle merging. This allows us to mix and dilute content, and to initiate protein expression by delivering biomolecular reaction components.

Published

2018

274. Engineering thermoresponsive phase separated vesicles formed via emulsion phase transfer as a content-release platform.

Author

Karamdad K, Hindley JW, Bolognesi G, Friddin MS, Law RV, Brooks NJ, Ces O, and Elani Y

Abstract

Giant unilamellar vesicles (GUVs) are a well-established tool for the study of membrane biophysics and are increasingly used as artificial cell models and functional units in biotechnology. This trend is driven by the development of emulsion-based generation methods such as Emulsion Phase Transfer (EPT), which facilitates the encapsulation of almost any water-soluble compounds (including biomolecules) regardless of size or charge, is compatible with droplet microfluidics, and allows GUVs with asymmetric bilayers to be assembled. However, the ability to control the composition of membranes formed via EPT remains an open question; this is key as composition gives rise to an array of biophysical phenomena which can be used to add functionality to membranes. Here, we evaluate the use of GUVs constructed via this method as a platform for phase behaviour studies and take advantage of composition-dependent features to engineer thermally-responsive GUVs. For the first time, we generate ternary GUVs (DOPC/DPPC/cholesterol) using EPT, and by compensating for the lower cholesterol incorporation efficiencies, show that these possess the full range of phase behaviour displayed by electroformed GUVs. As a demonstration of the fine control afforded by this approach, we demonstrate release of dye and peptide cargo when ternary GUVs are heated through the immiscibility transition temperature, and show that release temperature can be tuned by changing vesicle composition. We show that GUVs can be individually addressed and release triggered using a laser beam. Our findings validate EPT as a suitable method for generating phase separated vesicles and provide a valuable proof-of-concept for engineering content release functionality into individually addressable vesicles, which could have a host of applications in the development of smart synthetic biosystems.

Published

2018

275. Light-triggered enzymatic reactions in nested vesicle reactors.

Author

Hindley JW, Elani Y, McGilvery CM, Ali S, Bevan CL, Law RV, and Ces O

Subjects

Biocatalysis, Hydrolysis, beta-Galactosidase metabolism, Ultraviolet Rays

Abstract

Cell-sized vesicles have tremendous potential both as miniaturised pL reaction vessels and in bottom-up synthetic biology as chassis for artificial cells. In both these areas the introduction of light-responsive modules affords increased functionality, for example, to initiate enzymatic reactions in the vesicle interior with spatiotemporal control. Here we report a system composed of nested vesicles where the inner compartments act as phototransducers, responding to ultraviolet irradiation through diacetylene polymerisation-induced pore formation to initiate enzymatic reactions. The controlled release and hydrolysis of a fluorogenic β-galactosidase substrate in the external compartment is demonstrated, where the rate of reaction can be modulated by varying ultraviolet exposure time. Such cell-like nested microreactor structures could be utilised in fields from biocatalysis through to drug delivery.

Published

2018

276. Constructing vesicle-based artificial cells with embedded living cells as organelle-like modules.

Author

Elani Y, Trantidou T, Wylie D, Dekker L, Polizzi K, Law RV, and Ces O

Subjects

Bioreactors, Lipid Bilayers, Microfluidic Analytical Techniques instrumentation, Models, Biological, Artificial Cells metabolism, Organelles metabolism

Abstract

There is increasing interest in constructing artificial cells by functionalising lipid vesicles with biological and synthetic machinery. Due to their reduced complexity and lack of evolved biochemical pathways, the capabilities of artificial cells are limited in comparison to their biological counterparts. We show that encapsulating living cells in vesicles provides a means for artificial cells to leverage cellular biochemistry, with the encapsulated cells serving organelle-like functions as living modules inside a larger synthetic cell assembly. Using microfluidic technologies to construct such hybrid cellular bionic systems, we demonstrate that the vesicle host and the encapsulated cell operate in concert. The external architecture of the vesicle shields the cell from toxic surroundings, while the cell acts as a bioreactor module that processes encapsulated feedstock which is further processed by a synthetic enzymatic metabolism co-encapsulated in the vesicle.

Published

2018

277. Rheological Droplet Interface Bilayers (rheo-DIBs): Probing the Unstirred Water Layer Effect on Membrane Permeability via Spinning Disk Induced Shear Stress.

Author

Barlow NE, Bolognesi G, Haylock S, Flemming AJ, Brooks NJ, Barter LMC, and Ces O

Abstract

A new rheological droplet interface bilayer (rheo-DIB) device is presented as a tool to apply shear stress on biological lipid membranes. Despite their exciting potential for affecting high-throughput membrane translocation studies, permeability assays conducted using DIBs have neglected the effect of the unstirred water layer (UWL). However as demonstrated in this study, neglecting this phenomenon can cause significant underestimates in membrane permeability measurements which in turn limits their ability to predict key processes such as drug translocation rates across lipid membranes. With the use of the rheo-DIB chip, the effective bilayer permeability can be modulated by applying shear stress to the droplet interfaces, inducing flow parallel to the DIB membranes. By analysing the relation between the effective membrane permeability and the applied stress, both the intrinsic membrane permeability and UWL thickness can be determined for the first time using this model membrane approach, thereby unlocking the potential of DIBs for undertaking diffusion assays. The results are also validated with numerical simulations.

Published

2017

278. Programming membrane permeability using integrated membrane pores and blockers as molecular regulators.

Author

Thomas JM, Friddin MS, Ces O, and Elani Y

Subjects

Cyclodextrins chemistry, Fluorescence, Hemolysin Proteins chemistry, Kinetics, Permeability, Staphylococcus aureus chemistry, Cyclodextrins metabolism, Hemolysin Proteins metabolism

Abstract

We report a bottom-up synthetic biology approach to engineering vesicles with programmable permeabilities. Exploiting the concentration-dependent relationship between constitutively active pores (alpha-hemolysin) and blockers allows blockers to behave as molecular regulators for tuning permeability, enabling us to systematically modulate cargo release kinetics without changing the lipid fabric of the system.

Published

2017

279. Spontaneous charged lipid transfer between lipid vesicles.

Author

Richens JL, Tyler AII, Barriga HMG, Bramble JP, Law RV, Brooks NJ, Seddon JM, Ces O, and O'Shea P

Abstract

An assay to study the spontaneous charged lipid transfer between lipid vesicles is described. A donor/acceptor vesicle system is employed, where neutrally charged acceptor vesicles are fluorescently labelled with the electrostatic membrane probe Fluoresceinphosphatidylethanolamine (FPE). Upon addition of charged donor vesicles, transfer of negatively charged lipid occurs, resulting in a fluorescently detectable change in the membrane potential of the acceptor vesicles. Using this approach we have studied the transfer properties of a range of lipids, varying both the headgroup and the chain length. At the low vesicle concentrations chosen, the transfer follows a first-order process where lipid monomers are transferred presumably through the aqueous solution phase from donor to acceptor vesicle. The rate of transfer decreases with increasing chain length which is consistent with energy models previously reported for lipid monomer vesicle interactions. Our assay improves on existing methods allowing the study of a range of unmodified lipids, continuous monitoring of transfer and simplified experimental procedures.

Published

2017

280. Engineering Compartmentalized Biomimetic Micro- and Nanocontainers.

Author

Trantidou T, Friddin M, Elani Y, Brooks NJ, Law RV, Seddon JM, and Ces O

Abstract

Compartmentalization of biological content and function is a key architectural feature in biology, where membrane bound micro- and nanocompartments are used for performing a host of highly specialized and tightly regulated biological functions. The benefit of compartmentalization as a design principle is behind its ubiquity in cells and has led to it being a central engineering theme in construction of artificial cell-like systems. In this review, we discuss the attractions of designing compartmentalized membrane-bound constructs and review a range of biomimetic membrane architectures that span length scales, focusing on lipid-based structures but also addressing polymer-based and hybrid approaches. These include nested vesicles, multicompartment vesicles, large-scale vesicle networks, as well as droplet interface bilayers, and double-emulsion multiphase systems (multisomes). We outline key examples of how such structures have been functionalized with biological and synthetic machinery, for example, to manufacture and deliver drugs and metabolic compounds, to replicate intracellular signaling cascades, and to demonstrate collective behaviors as minimal tissue constructs. Particular emphasis is placed on the applications of these architectures and the state-of-the-art microfluidic engineering required to fabricate, functionalize, and precisely assemble them. Finally, we outline the future directions of these technologies and highlight how they could be applied to engineer the next generation of cell models, therapeutic agents, and microreactors, together with the diverse applications in the emerging field of bottom-up synthetic biology.

Published

2017

281. Artificial cell mimics as simplified models for the study of cell biology.

Author

Salehi-Reyhani A, Ces O, and Elani Y

Subjects

Artificial Cells, Cell Physiological Phenomena, Cytological Techniques methods

Abstract

Living cells are hugely complex chemical systems composed of a milieu of distinct chemical species (including DNA, proteins, lipids, and metabolites) interconnected with one another through a vast web of interactions: this complexity renders the study of cell biology in a quantitative and systematic manner a difficult task. There has been an increasing drive towards the utilization of artificial cells as cell mimics to alleviate this, a development that has been aided by recent advances in artificial cell construction. Cell mimics are simplified cell-like structures, composed from the bottom-up with precisely defined and tunable compositions. They allow specific facets of cell biology to be studied in isolation, in a simplified environment where control of variables can be achieved without interference from a living and responsive cell. This mini-review outlines the core principles of this approach and surveys recent key investigations that use cell mimics to address a wide range of biological questions. It will also place the field in the context of emerging trends, discuss the associated limitations, and outline future directions of the field. Impact statement Recent years have seen an increasing drive to construct cell mimics and use them as simplified experimental models to replicate and understand biological phenomena in a well-defined and controlled system. By summarizing the advances in this burgeoning field, and using case studies as a basis for discussion on the limitations and future directions of this approach, it is hoped that this minireview will spur others in the experimental biology community to use artificial cells as simplified models with which to probe biological systems.

Published

2017

282. Hydrophilic surface modification of PDMS for droplet microfluidics using a simple, quick, and robust method via PVA deposition.

Author

Trantidou T, Elani Y, Parsons E, and Ces O

Abstract

Polydimethylsiloxane (PDMS) is a dominant material in the fabrication of microfluidic devices to generate water-in-oil droplets, particularly lipid-stabilized droplets, because of its highly hydrophobic nature. However, its key property of hydrophobicity has hindered its use in the microfluidic generation of oil-in-water droplets, which requires channels to have hydrophilic surface properties. In this article, we developed, optimized, and characterized a method to produce PDMS with a hydrophilic surface via the deposition of polyvinyl alcohol following plasma treatment and demonstrated its suitability for droplet generation. The proposed method is simple, quick, effective, and low cost and is versatile with respect to surfactants, with droplets being successfully generated using both anionic surfactants and more biologically relevant phospholipids. This method also allows the device to be selectively patterned with both hydrophilic and hydrophobic regions, leading to the generation of double emulsions and inverted double emulsions., Competing Interests: The authors declare no conflict of interest.

Published

2017

283. Light-activated control of protein channel assembly mediated by membrane mechanics.

Author

Miller DM, Findlay HE, Ces O, Templer RH, and Booth PJ

Subjects

Lipid Bilayers, Membrane Proteins, Protein Folding, Cell Membrane

Abstract

Photochemical processes provide versatile triggers of chemical reactions. Here, we use a photoactivated lipid switch to modulate the folding and assembly of a protein channel within a model biological membrane. In contrast to the information rich field of water-soluble protein folding, there is only a limited understanding of the assembly of proteins that are integral to biological membranes. It is however possible to exploit the foreboding hydrophobic lipid environment and control membrane protein folding via lipid bilayer mechanics. Mechanical properties such as lipid chain lateral pressure influence the insertion and folding of proteins in membranes, with different stages of folding having contrasting sensitivities to the bilayer properties. Studies to date have relied on altering bilayer properties through lipid compositional changes made at equilibrium, and thus can only be made before or after folding. We show that light-activation of photoisomerisable di-(5-[[4-(4-butylphenyl)azo]phenoxy]pentyl)phosphate (4-Azo-5P) lipids influences the folding and assembly of the pentameric bacterial mechanosensitive channel MscL. The use of a photochemical reaction enables the bilayer properties to be altered during folding, which is unprecedented. This mechanical manipulation during folding, allows for optimisation of different stages of the component insertion, folding and assembly steps within the same lipid system. The photochemical approach offers the potential to control channel assembly when generating synthetic devices that exploit the mechanosensitive protein as a nanovalve.

Published

2016

284. Optically assembled droplet interface bilayer (OptiDIB) networks from cell-sized microdroplets.

Author

Friddin MS, Bolognesi G, Elani Y, Brooks NJ, Law RV, Seddon JM, Neil MA, and Ces O

Abstract

We report a new platform technology to systematically assemble droplet interface bilayer (DIB) networks in user-defined 3D architectures from cell-sized droplets using optical tweezers. Our OptiDIB platform is the first demonstration of optical trapping to precisely construct 3D DIB networks, paving the way for the development of a new generation of modular bio-systems.

Published

2016

285. Microfluidic SAXS Study of Lamellar and Multilamellar Vesicle Phases of Linear Sodium Alkylbenzenesulfonate Surfactant with Intrinsic Isomeric Distribution.

Author

Poulos AS, Nania M, Lapham P, Miller RM, Smith AJ, Tantawy H, Caragay J, Gummel J, Ces O, Robles ES, and Cabral JT

Abstract

The structure and flow behavior of a concentrated aqueous solution (45 wt %) of the ubiquitous linear sodium alkylbenzenesulfonate (NaLAS) surfactant is investigated by microfluidic small-angle X-ray scattering (SAXS) at 70 °C. NaLAS is an intrinsically complex mixture of over 20 surfactant molecules, presenting coexisting micellar (L1) and lamellar (Lα) phases. Novel microfluidic devices were fabricated to ensure pressure and thermal resistance, ability to handle viscous fluids, and low SAXS background. Polarized light optical microscopy showed that the NaLAS solution exhibits wall slip in microchannels, with velocity profiles approaching plug flow. Microfluidic SAXS demonstrated the structural spatial heterogeneity of the system with a characteristic length scale of 50 nL. Using a statistical flow-SAXS analysis, we identified the micellar phase and multiple coexisting lamellar phases with a continuous distribution of d spacings between 37.5 and 39.5 Å. Additionally, we showed that the orientation of NaLAS lamellar phases is strongly affected by a single microfluidic constriction. The bilayers align parallel to the velocity field upon entering a constriction and perpendicular to it upon exiting. On the other hand, multilamellar vesicle phases are not affected under the same flow conditions. Our results demonstrate that despite the compositional complexity inherent to NaLAS, microfluidic SAXS can rigorously elucidate its structure and flow response.

Published

2016

286. Mechanical Characterization of Ultralow Interfacial Tension Oil-in-Water Droplets by Thermal Capillary Wave Analysis in a Microfluidic Device.

Author

Bolognesi G, Saito Y, Tyler AI, Ward AD, Bain CD, and Ces O

Abstract

Measurements of the ultralow interfacial tension and surfactant film bending rigidity for micron-sized heptane droplets in bis(2-ethylhexyl) sodium sulfosuccinate-NaCl aqueous solutions were performed in a microfluidic device through the analysis of thermally driven droplet interface fluctuations. The Fourier spectrum of the stochastic droplet interface displacement was measured through bright-field video microscopy and a contour analysis technique. The droplet interfacial tension, together with the surfactant film bending rigidity, was obtained by fitting the experimental results to the prediction of a capillary wave model. Compared to existing methods for ultralow interfacial tension measurements, this contactless, nondestructive, all-optical approach has several advantages, such as fast measurement, easy implementation, cost-effectiveness, reduced amount of liquids, and integration into lab-on-a-chip devices.

Published

2016

287. Transcription Regulation and Membrane Stress Management in Enterobacterial Pathogens.

Author

Zhang N, Jovanovic G, McDonald C, Ces O, Zhang X, and Buck M

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, Cell Membrane metabolism, Enterobacteriaceae genetics, Enterobacteriaceae metabolism, Heat-Shock Proteins genetics, Heat-Shock Proteins metabolism, Host-Pathogen Interactions, Models, Molecular, Protein Conformation, RNA Polymerase Sigma 54 chemistry, RNA Polymerase Sigma 54 genetics, Signal Transduction, Structure-Activity Relationship, Trans-Activators genetics, Trans-Activators metabolism, Cell Membrane physiology, Enterobacteriaceae physiology, Gene Expression Regulation, Bacterial, RNA Polymerase Sigma 54 metabolism, Stress, Physiological, Transcription, Genetic

Abstract

Transcription regulation in a temporal and conditional manner underpins the lifecycle of enterobacterial pathogens. Upon exposure to a wide array of environmental cues, these pathogens modulate their gene expression via the RNA polymerase and associated sigma factors. Different sigma factors, either involved in general 'house-keeping' or specific responses, guide the RNA polymerase to their cognate promoter DNAs. The major alternative sigma54 factor when activated helps pathogens manage stresses and proliferate in their ecological niches. In this chapter, we review the function and regulation of the sigma54-dependent Phage shock protein (Psp) system-a major stress response when Gram-negative pathogens encounter damages to their inner membranes. We discuss the recent development on mechanisms of gene regulation, signal transduction and stress mitigation in light of different biophysical and biochemical approaches.

Published

2016

288. Membrane Stored Curvature Elastic Stress Modulates Recruitment of Maintenance Proteins PspA and Vipp1.

Author

McDonald C, Jovanovic G, Ces O, and Buck M

Subjects

Gene Expression Regulation, Bacterial, Protein Binding, Transcription, Genetic, Bacterial Proteins metabolism, Escherichia coli physiology, Heat-Shock Proteins metabolism, Membrane Proteins metabolism, Membranes metabolism, Stress, Physiological

Abstract

Unlabelled: Phage shock protein A (PspA), which is responsible for maintaining inner membrane integrity under stress in enterobacteria, and vesicle-inducting protein in plastids 1 (Vipp1), which functions for membrane maintenance and thylakoid biogenesis in cyanobacteria and plants, are similar peripheral membrane-binding proteins. Their homologous N-terminal amphipathic helices are required for membrane binding; however, the membrane features recognized and required for expressing their functionalities have remained largely uncharacterized. Rigorously controlled, in vitro methodologies with lipid vesicles and purified proteins were used in this study and provided the first biochemical and biophysical characterizations of membrane binding by PspA and Vipp1. Both proteins are found to sense stored curvature elastic (SCE) stress and anionic lipids within the membrane. PspA has an enhanced sensitivity for SCE stress and a higher affinity for the membrane than Vipp1. These variations in binding may be crucial for some of the proteins' differing roles in vivo. Assays probing the transcriptional regulatory function of PspA in the presence of vesicles showed that a relief of transcription inhibition occurs in an SCE stress-specific manner. This in vitro recapitulation of membrane stress-dependent transcription control suggests that the Psp response may be mounted in vivo when a cell's inner membrane experiences increased SCE stress., Importance: All cell types maintain the integrity of their membrane systems. One widely distributed membrane stress response system in bacteria is the phage shock protein (Psp) system. The central component, peripheral membrane protein PspA, which mitigates inner membrane stress in bacteria, has a counterpart, Vipp1, which functions for membrane maintenance and thylakoid biogenesis in plants and photosynthetic bacteria. Membrane association of both these proteins is accepted as playing a pivotal role in their functions. Here we show that direct membrane binding by PspA and Vipp1 is driven by two physio-chemical signals, one of which is membrane stress specific. Our work points to alleviation of membrane stored curvature elastic stress by amphipathic helix insertions as an attractive mechanism for membrane maintenance by PspA and Vipp1. Furthermore, the identification of a physical, stress-related membrane signal suggests a unilateral mechanism that promotes both binding of PspA and induction of the Psp response., (Copyright © 2015 McDonald et al.)

Published

2015

289. Regulation of PLCβ2 by the electrostatic and mechanical properties of lipid bilayers.

Author

Arduin A, Gaffney PR, and Ces O

Subjects

Dimyristoylphosphatidylcholine chemistry, Elasticity, Electrochemistry, Phosphatidylcholines chemistry, Phosphatidylethanolamines chemistry, Protein Prenylation, Scattering, Small Angle, X-Ray Diffraction, rac GTP-Binding Proteins chemistry, RAC2 GTP-Binding Protein, Lipid Bilayers chemistry, Phospholipase C beta chemistry

Abstract

Phosphoinositide-specific phospholipase C (PLC) is an important family of enzymes constituting a junction between phosphoinositide lipid signaling and the trans-membrane signal transduction processes that are crucial to many living cells. However, the regulatory mechanism of PLC is not yet understood in detail. To address this issue, activity studies were carried out using lipid vesicles in a model system that was specifically designed to study protein-protein and lipid-protein interactions in concert. Evidence was found for a direct interaction between PLC and the GTPases that mediate phospholipase activation. Furthermore, for the first time, the relationships between PLC activity and substrate presentation in lipid vesicles of various sizes, as well as lipid composition and membrane mechanical properties, were analyzed. PLC activity was found to depend upon the electrostatic potential and the stored curvature elastic stress of the lipid membranes.

Published

2015

290. Influence of High Pressure on the Bending Rigidity of Model Membranes.

Author

Purushothaman S, Cicuta P, Ces O, and Brooks NJ

Subjects

Cell Membrane, Temperature, Mechanical Phenomena, Pressure, Unilamellar Liposomes

Abstract

Curvature is a fundamental lipid membrane property that influences many membrane-mediated biological processes and dynamic soft materials. One of the key parameters that determines the energetics of curvature change is the membrane bending rigidity. Understanding the intrinsic effect of pressure on membrane bending is critical to understanding the adaptation and structural behavior of biomembranes in deep-sea organisms as well as soft material processing. However, it has not previously been possible to measure the influence of high hydrostatic pressure on membrane bending energetics, and this bottleneck has primarily been due to a lack of technology platforms for performing such measurements. We have developed a new high-pressure microscopy cell which, combined with vesicle fluctuation analysis, has allowed us to make the first measurements of membrane bending rigidity as a function of pressure. Our results show a significant increase in bending rigidity at pressures up to 40 MPa. Above 40 MPa, the membrane mechanics become more complex. Corresponding small and wide-angle X-ray diffraction shows an increase in density and thickness of the bilayer with increasing pressure which correlates with the micromechanical measurements. These results are consistent with recent theoretical predictions of the bending rigidity as a function of hydrocarbon chain density. This technology has the potential to transform our quantitative understanding of the role of pressure in soft material processing, the structural behavior of biomembranes, and the adaptation mechanisms employed by deep-sea organisms.

Published

2015

291. Synthesis of unsaturated phosphatidylinositol 4-phosphates and the effects of substrate unsaturation on SopB phosphatase activity.

Author

Furse S, Mak L, Tate EW, Templer RH, Ces O, Woscholski R, and Gaffney PR

Subjects

Bacterial Proteins chemistry, Enzyme Activation, Molecular Conformation, Phosphatidylinositol Phosphates chemistry, Phosphoric Monoester Hydrolases chemistry, Substrate Specificity, Bacterial Proteins metabolism, Phosphatidylinositol Phosphates biosynthesis, Phosphoric Monoester Hydrolases metabolism

Abstract

In this paper evidence is presented that the fatty acid component of an inositide substrate affects the kinetic parameters of the lipid phosphatase Salmonella Outer Protein B (SopB). A succinct route was used to prepare the naturally occurring enantiomer of phosphatidylinositol 4-phosphate (PI-4-P) with saturated, as well as singly, triply and quadruply unsaturated, fatty acid esters, in four stages: (1) The enantiomers of 2,3:5,6-O-dicyclohexylidene-myo-inositol were resolved by crystallisation of their di(acetylmandelate) diastereoisomers. (2) The resulting diol was phosphorylated regio-selectively exclusively on the 1-O using the new reagent tri(2-cyanoethyl)phosphite. (3) With the 4-OH still unprotected, the glyceride was coupled using phosphate tri-ester methodology. (4) A final phosphorylation of the 4-O, followed by global deprotection under basic then acidic conditions, provided PI-4-P bearing a range of sn-1-stearoyl, sn-2-stearoyl, -oleoyl, -γ-linolenoyl and arachidonoyl, glycerides. Enzymological studies showed that the introduction of cis-unsaturated bonds has a measurable influence on the activity (relative Vmax) of SopB. Mono-unsaturated PI-4-P exhibited a five-fold higher activity, with a two-fold higher KM, over the saturated substrate, when presented in DOPC vesicles. Poly-unsaturated PI-4-P showed little further change with respect to the singly unsaturated species. This result, coupled with our previous report that saturated PI-4-P has much higher stored curvature elastic stress than PI, supports the hypothesis that the activity of inositide phosphatase SopB has a physical role in vivo.

Published

2015

292. Vesicle-based artificial cells: recent developments and prospects for drug delivery.

Author

Elani Y, Law RV, and Ces O

Subjects

Humans, Microfluidics, Particle Size, Artificial Cells, Drug Delivery Systems methods, Phospholipids chemistry, Proteins administration & dosage

Published

2015

293. Buffers may adversely affect model lipid membranes: a cautionary tale.

Author

Peiró-Salvador T, Ces O, Templer RH, and Seddon AM

Subjects

Elasticity, Hydrophobic and Hydrophilic Interactions, Membrane Fluidity drug effects, Membrane Lipids metabolism, Membrane Proteins metabolism, Models, Biological, Models, Molecular, Scattering, Small Angle, Solubility, Static Electricity, Thermodynamics, X-Ray Diffraction, Buffers, Membrane Lipids chemistry, Membrane Proteins chemistry, Membranes, Artificial

Abstract

The effects of biological buffers on lipids have not been fully investigated because of the long-standing assumption that these buffers are too hydrophilic to substantially interact with the lipid membrane. We present evidence that for some buffers, this is not necessarily the case. Our research points toward a membrane softening effect caused by the buffer molecules interacting with the headgroup region of the lipid. Changes in the elastic properties of the membrane are known to control membrane protein behavior; this work serves as a warning for the design of assays utilizing model membranes in the presence of buffers.

Published

2009

294. Factors controlling the stability of a kinetically hindered lamellar-lamellar transition.

Author

Shearman GC, Ugazio S, Soubiran L, Hubbard J, Ces O, Seddon JM, and Templer RH

Subjects

Ethanolamines chemistry, Gels chemistry, Kinetics, Molecular Structure, Phase Transition, Quaternary Ammonium Compounds chemistry, Surface-Active Agents chemistry, Temperature, Time Factors, Fatty Alcohols chemistry, Sodium Chloride chemistry

Abstract

We show that we can manipulate the stability of a metastable gel phase, either to enhance its transitory nature or to "lock" it in. Using simple additives such as salt and fatty alcohol we were able to examine both the long-range effect, acting between charged bilayers, and short-range effects on the metastability. We found that the addition of salt to the cationic surfactant diethanolamine ester dimethyl ammonium chloride destabilized the gel phase, and at high concentrations it was able to decrease the length of time taken for the gel phase to revert to a hydrated solid "coagel" phase by an order of magnitude. The growth of the coagel phase was also found to be affected by increasing salt concentration, changing from needle-like (1D) to spherical growth. In contrast to the marked destabilization of the gel phase by salt, the addition of 1-octadecanol was found to prolong the lifetime of the gel phase almost indefinitely by disrupting the short-range packing between the surfactant molecules. This suggests that counterion binding plays a major role in the stability of metastable lamellar gel phases.

Published

2009

295. A 3-D hexagonal inverse micellar lyotropic phase.

Author

Shearman GC, Tyler AI, Brooks NJ, Templer RH, Ces O, Law RV, and Seddon JM

Subjects

Liquid Crystals chemistry, Models, Molecular, Scattering, Small Angle, X-Ray Diffraction, Cholesterol chemistry, Diglycerides chemistry, Membrane Lipids chemistry, Micelles, Phosphatidylcholines chemistry

Abstract

Lipids that are found in cell membranes form a variety of self-assembled phases in the presence of water. Many of these structures are liquid-crystalline with structural motifs mirrored in cells and organelles and can be exploited in the delivery of drugs and genes. We report the discovery of a lyotropic liquid crystalline phase based on a 3-D hexagonal close-packed arrangement of inverse micelles, of space group P6(3)/mmc. This is the first new inverse lyotropic liquid-crystalline phase to be reported for two decades and is the only known lyotropic phase whose structure consists of a close packing of identical inverse micelles.

Published

2009

296. Spatial localization of PtdInsP2 in phase-separated giant unilamellar vesicles with a fluorescent PLC-delta 1 PH domain.

Author

Mulet X, Rosivatz E, Ho KK, Gauthé BL, Ces O, Templer RH, and Woscholski R

Subjects

Animals, Fluorescence, Micromanipulation, Microscopy, Fluorescence, Phosphatidylinositol 4,5-Diphosphate chemistry, Phosphatidylinositol 4,5-Diphosphate metabolism, Protein Structure, Tertiary, Fluorescent Dyes analysis, Fluorescent Dyes chemistry, Phosphatidylinositol 4,5-Diphosphate analysis, Phospholipase C delta chemistry, Phospholipase C delta metabolism, Unilamellar Liposomes chemistry, Unilamellar Liposomes isolation & purification

Abstract

This chapter describes a method for the preparation of giant unilamellar vesicles containing phosphatidylinositol 4,5-bisphosphate that are larger than 20 microm in size. The phospholipids composition of the vesicular membrane is such that fluid lamellar and liquid-ordered or gel phases are formed and separate within the confines of one vesicle. It outlines the preparation of a protein fluorescent label, pleckstrin homology domain from phospholipase C-delta 1, that binds specifically to phosphatidylinositol 4,5-bisphosphate. Using fluorescence microscopy, the presence and spatial position of this phosphorylated phosphatidylinositol lipid on the lipid membrane have been located with the pleckstrin homology domain. We show that phosphatidylinositol 4,5-bisphosphate and the phospholipase C-delta 1 pleckstrin homology domain are located to the fluid phase of the vesicle membrane. This approach can therefore show how membrane physical properties can affect enzyme binding to phosphatidylinositol 4,5-bisphosphate and thus further the understanding of important membrane processes such as endocytosis.

Published

2009

297. Phosphatidylglycerol lipids enhance folding of an alpha helical membrane protein.

Author

Seddon AM, Lorch M, Ces O, Templer RH, Macrae F, and Booth PJ

Subjects

Escherichia coli chemistry, Kinetics, Lipid Bilayers chemistry, Protein Structure, Secondary, Diacylglycerol Kinase chemistry, Membrane Lipids chemistry, Membrane Proteins chemistry, Phosphatidylglycerols chemistry, Protein Folding

Abstract

Membrane lipids are increasingly being recognised as active participants in biological events. The precise roles that individual lipids or global properties of the lipid bilayer play in the folding of membrane proteins remain to be elucidated, Here, we find a significant effect of phosphatidylglycerol (PG) on the folding of a trimeric alpha helical membrane protein from Escherichia coli diacylglycerol kinase. Both the rate and the yield of folding are increased by increasing the amount of PG in lipid vesicles. Moreover, there is a direct correlation between the increase in yield and the increase in rate; thus, folding becomes more efficient in terms of speed and productivity. This effect of PG seems to be a specific requirement for this lipid, rather than a charge effect. We also find an effect of single-chain lyso lipids in decreasing the rate and yield of folding. We compare this to our previous work in which lyso lipids increased the rate and yield of another membrane protein, bacteriorhodopsin. The contrasting effect of lyso lipids on the two proteins can be explained by the different folding reaction mechanisms and key folding steps involved. Our findings provide information on the lipid determinants of membrane protein folding.

Published

2008

298. A pressure-jump time-resolved X-ray diffraction study of cubic-cubic transition kinetics in monoolein.

Author

Conn CE, Ces O, Squires AM, Mulet X, Winter R, Finet SM, Templer RH, and Seddon JM

Subjects

Kinetics, Pressure, Scattering, Small Angle, Time Factors, X-Ray Diffraction, Glycerides chemistry

Abstract

In the past two decades, the geometric pathways involved in the transformations between inverse bicontinuous cubic phases in amphiphilic systems have been extensively theoretically modeled. However, little experimental data exists on the cubic-cubic transformation in pure lipid systems. We have used pressure-jump time-resolved X-ray diffraction to investigate the transition between the gyroid QGII and double-diamond QDII phases in mixtures of 1-monoolein in 30 wt % water. We find for this system that the cubic-cubic transition occurs without any detectable intermediate structures. In addition, we have determined the kinetics of the transition, in both the forward and reverse directions, as a function of pressure-jump amplitude, temperature, and water content. A recently developed model allows (at least in principle) the calculation of the activation energy for lipid phase transitions from such data. The analysis is applicable only if kinetic reproducibility is achieved, at least within one sample, and achievement of such kinetic reproducibility is shown here, by carrying out prolonged pressure-cycling. The rate of transformation shows clear and consistent trends with pressure-jump amplitude, temperature, and water content, all of which are shown to be in agreement with the effect of the shift in the position of the cubic-cubic phase boundary following a change in the thermodynamic parameters.

Published

2008

299. Pressure-jump X-ray studies of liquid crystal transitions in lipids.

Author

Seddon JM, Squires AM, Conn CE, Ces O, Heron AJ, Mulet X, Shearman GC, and Templer RH

Subjects

Hydrostatic Pressure, In Vitro Techniques, Lipid Bilayers chemistry, Liquid Crystals, Models, Molecular, Synchrotrons, Thermodynamics, X-Ray Diffraction, Lipids chemistry

Abstract

In this paper, we give an overview of our studies by static and time-resolved X-ray diffraction of inverse cubic phases and phase transitions in lipids. In [section sign] 1, we briefly discuss the lyotropic phase behaviour of lipids, focusing attention on non-lamellar structures, and their geometric/topological relationship to fusion processes in lipid membranes. Possible pathways for transitions between different cubic phases are also outlined. In [section sign] 2, we discuss the effects of hydrostatic pressure on lipid membranes and lipid phase transitions, and describe how the parameters required to predict the pressure dependence of lipid phase transition temperatures can be conveniently measured. We review some earlier results of inverse bicontinuous cubic phases from our laboratory, showing effects such as pressure-induced formation and swelling. In [section sign] 3, we describe the technique of pressure-jump synchrotron X-ray diffraction. We present results that have been obtained from the lipid system 1:2 dilauroylphosphatidylcholine/lauric acid for cubic-inverse hexagonal, cubic-cubic and lamellar-cubic transitions. The rate of transition was found to increase with the amplitude of the pressure-jump and with increasing temperature. Evidence for intermediate structures occurring transiently during the transitions was also obtained. In [section sign] 4, we describe an IDL-based 'AXcess' software package being developed in our laboratory to permit batch processing and analysis of the large X-ray datasets produced by pressure-jump synchrotron experiments. In [section sign] 5, we present some recent results on the fluid lamellar-Pn3m cubic phase transition of the single-chain lipid 1-monoelaidin, which we have studied both by pressure-jump and temperature-jump X-ray diffraction. Finally, in [section sign] 6, we give a few indicators of future directions of this research. We anticipate that the most useful technical advance will be the development of pressure-jump apparatus on the microsecond time-scale, which will involve the use of a stack of piezoelectric pressure actuators. The pressure-jump technique is not restricted to lipid phase transitions, but can be used to study a wide range of soft matter transitions, ranging from protein unfolding and DNA unwinding and transitions, to phase transitions in thermotropic liquid crystals, surfactants and block copolymers.

Published

2006

300. Degradative transport of cationic amphiphilic drugs across phospholipid bilayers.

Author

Baciu M, Sebai SC, Ces O, Mulet X, Clarke JA, Shearman GC, Law RV, Templer RH, Plisson C, Parker CA, and Gee A

Subjects

Biological Transport, Active, Cations, Diffusion, Drug Delivery Systems, In Vitro Techniques, Lipid Bilayers chemistry, Liquid Crystals, Magnetic Resonance Spectroscopy, Microscopy, Fluorescence, Models, Biological, Phospholipids chemistry, Phospholipids metabolism, Scattering, Radiation, Surface-Active Agents chemistry, X-Rays, Lipid Bilayers metabolism, Surface-Active Agents pharmacokinetics

Abstract

Drug molecules must cross multiple cell membrane barriers to reach their site of action. We present evidence that one of the largest classes of pharmaceutical drug molecules, the cationic amphiphilic drugs (CADs), does so via a catalytic reaction that degrades the phospholipid fabric of the membrane. We find that CADs partition rapidly to the polar-apolar region of the membrane. At physiological pH, the protonated groups on the CAD catalyse the acid hydrolysis of the ester linkage present in the phospholipid chains, producing a fatty acid and a single-chain lipid. The single-chain lipids rapidly destabilize the membrane, causing membranous fragments to separate and diffuse away from the host. These membrane fragments carry the drug molecules with them. The entire process, from drug adsorption to drug release within micelles, occurs on a time-scale of seconds, compatible with in vivo drug diffusion rates. Given the rate at which the reaction occurs, it is probable that this process is a significant mechanism for drug transport.

Published

2006