Label-Free Sensing on Supported Lipid Bilayers

Robison, Aaron Douglas 1982-

14 March 2013

Cell membranes are integral for many biological processes. In addition to containing and protecting cellular contents and maintaining the chemical integrity of the cell, these interfaces host a variety of ligand-receptor interactions. These ligand-receptor interactions are important for cell signaling and transport and the ability to monitor them is key to understanding these processes. In addition, therapeutics and drug discovery is also aided by membrane-specific study, as the majority of drugs target receptors associated with the cell surface. The cell membrane can be effectively mimicked by the use of supported lipid bilayers, which provide a robust platform exhibiting the lateral fluidity and composition associated with cell membranes. The ability to study both ligand-receptor interactions as well as small molecule-membrane interactions on these model membranes is aided by the fact that these assays can be multiplexed and are amenable to use with low sample volumes with high throughput. Our laboratory has recently developed a strategy for fluorescent microscopy studies of ligand-receptor interactions on supported lipid bilayers without the use of fluorescently-labeled analytes. This technique involves the incorporation of pH-sensitive fluorophores into the composition of the supported lipid bilayer as embedded reporter dyes. It was determined that this assay can operate as either a “turn-on” or a “turn-off” sensor depending on the analyte to be detected. It was additionally found that modulating the ionic strength of the operating buffer allows for tuning the operating pH and sensitivity of the assay. This label-free technique can be utilized to monitor small peptide interactions with bilayers containing specific phospholipids. Basic amino acid sequences which are associated with transporting contents across membranes or anti-microbial activity can be monitored binding to negatively charged bilayers without the use of labels. Not only is this a sensitive technique for detecting small peptides, but thermodynamic data can be extracted as well. In a final set of experiments, the interaction of proteins with phosphatidylserine (PS) in supported lipid bilayers is observed by utilizing PS-Cu2+-induced quenching of fluorophores. Disruption of this metal-phospholipid, specifically by Ca2+-dependent protein kinases, results in a turn-on fluorescent assay, which can be used to monitor the binding of the protein to PS and the effects of other metal interference.

Fluorescence

Supported Lipid Bilayer

Sensor

Investigation of the photocatalytic lithographic deposition of metals in sealed microfluidic devices on TiO2 surfaces

Castellana, Edward Thomas

15 May 2009

The research presented within this dissertation explores the photocatalytic deposition of metal carried out within sealed microfluidic channels. Micro scale patterning of metals inside sealed microchannels is investigated as well as nanoscale control over the surface morphology of the nanoparticles making up the patterns. This is achieved by controlling solution conditions during deposition. Finally, the nanoparticle patterns are used in fabricating a sensor device, which demonstrates the ability to address multiple patches within a sealed channel with different surface chemistries. Also presented here is the construction of the first epifluorescence/total internal reflection macroscope. Its ability to carry out high numerical aperture imaging of large arrays of solid supported phospholipid bilayers is explored. For this, three experiments are carried out. First, imaging of a 63 element array where every other box contains a different bilayer is preformed, demonstrating the ability to address large scale arrays by hand. Next, a protein binding experiment is preformed using two different arrays of increasing ligand density on the same chip. Finally, a two-dimensional array of mixed fluorescent dyes contained within solid supported lipid bilayers is imaged illustrating the ability of the instrument to acquire fluorescent resonance energy transfer data. Additionally, the design and fabrication of an improved array chip and addressing method is presented. Using this new array chip and addressing method in conjunction with the epifluorescence/total internal reflection macroscope should provide an efficient platform for high throughput screening of important biological processes which occur at the surfaces of cell membranes.

Microfluidic

Array

Solid Supported Lipid Bilayer

SENSING AND SEPARATING BIOMOLECULES AT BIOINTERFACES

Jung, Hyunsook

2009 May 1900

Ligand-receptor interactions are ubiquitous on cell membranes. Indeed, many important physiological functions primarily involve such interactions. These include cell signaling, pathogen binding, trafficking of lymphocytes, and the immune response.1-4 Therefore, studying ligand-receptor interactions at appropriate model membrane is of importance for both proper understanding of biological functions and applications to biosensors and bioseparations. Supported lipid bilayers are composed of the same lipid molecules found in the plasma cell membranes of living cells and possess the same two-dimensional fluidity as cell membranes, making them capable of mimicking the cell surface. Moreover, supported lipid bilayer-based in vitro assays are appealing because they require only very small sample volumes and they are suitable for multiplexing and high-throughput screening. Recently, our laboratory has combined supported lipid bilayer-coated microfluidic platforms with total internal reflection fluorescence microscopy to obtain equilibrium dissociation constant data for protein-ligand interactions. Using this method, it was found that equilibrium dissociation constants of antibody-ligand interactions at lipid membrane interfaces can be strongly affected by ligand lipophilicity and linker length/structure. These results are described in Chapter III. Monitoring protein-ligand interactions is routinely performed by fluorescently labeling the proteins of interest. Protein labeling can, however, interfere with detection measurements and be highly inconvenient to employ. To solve these problems, a simple and highly sensitive technique for detection of protein-ligand binding at biointerfaces has been developed. The method is based upon modulation of the interfacial pH when the protein binds. This change is detected by pH-sensitive fluorescent dye molecules embedded into the biointerface. The dye fluoresces strongly in the protonated state but becomes inactive upon deprotonation. These results are demonstrated in Chapter IV. Finally, the study of supported lipid bilayer-based electrophoresis is described in Chapter V. Bilayer electrophoresis is an attractive alternative to gel electrophoresis for the separation of membrane components such as lipids and membrane proteins because it is run in native-like environments and avoids exposing the analytes of interest to harsh chemicals. In this study, lipid rafts of varying size were used as separation matrices to separate two similar lipids with different alkyl chains. Lipid rafts of varying size were formed by a process controlled by varying treatment of the solid substrate. Depending on which method was employed, the results showed that lipid raft size could be modulated over five orders of magnitude. Moreover, it was found that the electrophoretic separation of the two lipid components depended on the size of rafts in the bilayer matrix.

Characterizing molecular-scale interactions between antimicrobial peptides and model cell membranes

Wang, Kathleen F

23 April 2014

Due to the escalating challenge of antibiotic resistance in bacteria over the past several decades, interest in the identification and development of antibiotic alternatives has intensified. Antimicrobial peptides (AMPs), which serve as part of the innate immune systems of most eukaryotic organisms, are being researched extensively as potential alternatives. However, the mechanism behind their bactericidal capabilities is not well understood. Previous studies have suggested that AMPs may first attach to the cell membranes, leading to pore formation caused by peptide insertion, lipid removal in the form of peptide-lipid aggregates, or a combination of both mechanisms. In addition to the lack of mechanistic knowledge, a significant hurdle in AMP-based drug development is their potential cytotoxicity to mammalian cells. Understanding AMP interactions with eukaryotic model membranes would allow therapeutics to be tailored for preferential action toward specific classes of bacterial membranes. In this study, we developed novel methods of quartz crystal microbalance with dissipation monitoring (QCM-D) data analysis to determine the fundamental mechanism of action between eukaryotic and bacterial membrane mimics and select membrane-active AMPs. A new technique for creating supported membranes composed entirely of anionic lipids was developed to model Gram-positive bacterial membranes. Atomic force microscopy (AFM) imaging was also used to capture the progression of AMP-induced changes in supported lipid membranes over time and to validate our method of QCM-D analysis. QCM-D and AFM were used to investigate the molecular-scale interactions of four peptides, alamethicin, chrysophsin-3, sheep myeloid antimicrobial peptide (SMAP-29) and indolicidin, with a supported zwitterionic membrane, which served as a model for eukaryotic cell membranes. Since established methods of QCM-D analysis were not sufficient to provide information about these interaction mechanisms, we developed a novel method of using QCM-D overtones to probe molecular events occurring within supported lipid membranes. Also, most previous studies that have used AFM imaging to investigate AMP-membrane interactions have been inconclusive due to AFM limitations and poor image quality. We were able to capture high-resolution AFM images that clearly show the progression of AMP-induced defects in the membrane. Each AMP produced a unique QCM-D signature that clearly distinguished their mechanism of action and provided information on peptide addition to and lipid removal from the membrane. Alamethicin, an alpha-helical peptide, predominantly demonstrated a pore formation mechanism. Chrysophsin-3 and SMAP-29, which are also alpha-helical peptides of varied lengths, inserted into the membrane and adsorbed to the membrane surface. Indolicidin, a shorter peptide that forms a folded, boat-shaped structure, was shown to adsorb and partially insert into the membrane. An investigation of rates at which the peptide actions were initiated revealed that the highest initial interaction rate was demonstrated by SMAP-29, the most cationic peptide in this study. The mechanistic variations in peptide action were related to their fundamental structural properties including length, net charge, hydrophobicity, hydrophobic moment, accessible surface area and the probability of alpha-helical secondary structures. Due to the charges associated with anionic lipids, previous studies have not been successful in forming consistent anionic supported lipid membranes, which were required to mimic Gram-positive bacterial membranes. We developed a new protocol for forming anionic supported lipid membranes and supported vesicle films using a vesicle fusion process. Chrysophsin-3 was shown to favor insertion into the anionic lipid bilayer and did not adsorb to the surface as it did with zwitterionic membranes. When introduced to supported anionic vesicle films, chrysophsin-3 caused some vesicles to rupture, likely through lipid membrane disruption. This study demonstrated that molecular-level interactions between antimicrobial peptides and model cell membranes are largely determined by peptide structure, peptide concentration, and membrane lipid composition. Novel techniques for analyzing QCM-D overtone data were also developed, which could enable the extraction of more molecular orientation and interaction dynamics information from other QCM-D studies. A new method of forming supported anionic membranes was also designed, which may be used to further investigate the behavior of bacterial membranes in future studies. Insight into AMP-membrane interactions and development of AMP structure-activity relationships will facilitate the selection and design of more efficient AMPs for use in therapeutics that could impact the lives of millions of people per year who are threatened by antibiotic-resistant organisms.

supported lipid bilayer

QCM-D

AFM

antimicrobial peptides

Supported lipid bilayer interactions with nanoparticles, peptides and polymers

Kamaloo, Elaheh

21 January 2018

Supported lipid bilayers (SLBs) are one of the most common model membranes used in the field of cell membrane biology as they provide a well-defined model membrane platform for determination of molecular-level interactions between different biomolecules (e.g. proteins, peptides) and lipid membrane. Compared to model organisms, the use of SLB is preferable since it mimics cell plasma membrane in a very simple and well-controlled way. Therefore, molecular structure of membrane and experimental conditions (e.g. solution chemistry, temperature, and pH) can be easily adjusted to the required conditions of any systematic research. In addition, SLBs are typically easy to form, cheap and very reproducible and they are compatible with different surface characterization techniques, such as quartz crystal microbalance with dissipation (QCM-D), ellipsometry and atomic force microscopy (AFM). This study demonstrates that QCM-D analysis of SLBs serve as powerful tool to investigate and characterize the mechanisms of interactions between lipid membrane and gold nanoparticles (NPs), environmentally relevant polymers, and disease-inducing peptides. Due to many critical applications of gold NPs in drug delivery and diagnostics, understanding of membrane-NP interactions is crucial especially for determination of NPs cytotoxicity. In this study we focus on membrane disruption as one of the different mechanisms by which metal NPs induce cytotoxicity. The use of SLB is beneficial for this goal as it elucidates the unique mechanism of membrane disruption without interference of other mechanisms taking place simultaneously in biological cells. For NP-membrane interaction studies, a SLB composed of L-α-phosphatidylcholine (egg PC) was formed on a SiO2-coated crystal and QCM-D analysis was performed to obtain information about mass and viscoelastic changes of SLB resulting from interactions with gold NPs. For better understanding of the mechanisms of NP-membrane interactions, we systematically changed the NPs properties and the experimental conditions. In order to understand the effect of NP size, gold NPs with diameters of 2,5,10, and 40 nm were tested and compared to each other. NPs were tested in their citric acid-stabilized state as well as in the presence of poly (methacrylic acid) (PMAA), representing an organic coating that could become associated with NPs in the environment. The results indicated that when dissolved in water, gold NPs with the dimeters of 2, 5, 10, and 40 nm did not perturb the membrane, but in the presence of environmentally relevant polymer, the larger nanoparticles were found to disrupt the membrane. In order to elucidate the effect of surface chemistry, 10 nm - gold NPs with various functionalizations (i.e. anionic, cationic and non-ionic ligands) were tested. Control experiments were designed to test the effect of NPs in the absence of humic substances which means the NPs were dissolved in water. In these cases, regardless of the type of NP functionalization, no substantial bilayer mass changes were observed. This suggests that the charge and chemistry of the ligands had a minor effect on NP-membrane interactions. Furthermore, in both the control and humic acid experiments, there were small dissipation changes (less than 1 unit) indicating that the overall membrane structure was not perturbed. In order to mimic environmentally-relevant conditions, mass and viscoelasticity of SLB was characterized in the presence of four different natural polymers, also known as natural organic materials (NOMs): Fulvic and humic acids extracted from Suwannee River (SRFA and SRHA), which had relatively lower molecular weights and a commercial humic acid (HA) and the humic acid extracted from Elliott soil (ESHA) with higher molecular weight. The results showed that NOMs with lower molecular weights, adsorbed to the bilayer, while higher molecular weight components, did not induce any changes to the bilayers. In addition, the NPs in SRFA and SRHA increased the mass of the bilayer by 20-30 ng, while the NPs in HA and ESHA changed the mass of the bilayer by < 10 ng. It was concluded that the presence of humic substances as well as their physical and chemical properties exert a direct impact on the interactions between cell membrane and the nanoparticles. In addition to the field of NP toxicity, SLBs play a pivotal role in the field of neurodegenerative diseases, such as Alzheimer’s disease (AD), in which the pathological cascade of events starts from interactions of a misfolded peptide with cell membrane. In this thesis, we confirm the validity of QCM-D analysis of SLB as an important platform for investigation of amyloid β (the peptide associated with AD) interactions with lipid membrane. Adsorption of Aβ peptide to cell membrane is known to take place on the so-called “lipid raftâ€� which are membrane microdomains enriched with cholesterol, sphingomyelin and ganglioside. The formation of SLBs containing lipid rafts is not only important for the field of AD research, but also it is important for other in vitro studies of cell biology as the lipid rafts are responsible for a variety of biological functions such as association of some membrane proteins and cellular signaling. However, the presence of lipid raft components such as sphingomyelin and cholesterol makes the formation of the bilayer more challenging which leads to adsorption of intact vesicles on the substrate without formation of the bilayer. In this study, the formation of lipid bilayer composed of 1,2-Dioleoyl-sn-glycero-3-phosphocholine (DOPC), 1,2-dioleoyl- sn-glycero-3-phospho-L-serine (DOPS), cholesterol (Chol), sphingomyelin (SM), and ganglioside (GM) was investigated using QCM-D. A challenge was that the raft-containing vesicles remained intact on the SiO2 crystal. Therefore, different experimental conditions were tested to induce vesicle fusion, such as pH, temperature, osmotic pressure, and vesicle size. The key parameter in forming the bilayer was found to be applying osmotic pressure to the vesicles by having the vesicles exterior concentration of NaCl higher than interior concentration. When this concentration gradient was applied to the vesicles before flowing them on the substrate, vesicle rupture was favored and formation of a complete bilayer could occur. Here, we report the effects of each tested variable on the adsorption and fusion of the raft-containing vesicles, and the results are discussed based on the mechanisms of vesicle-vesicle and vesicle-substrate interactions.After developing the robust method for formation of SLB with lipid rafts, we used that as a template to characterize the mechanism of interactions between Aβ peptide and cell membrane which leads to onset of AD. The mechanism of Aβ toxicity leading to AD has not fully discovered yet, due to the complexity of the process including several steps of Aβ peptide adsorption on membrane, conformational change from disordered in solution to a membrane-bound α-helix structure and then formation of β-sheet aggregates that serve as fibrillation seeds. In this study, we showed that QCM-D technique as a promising tool to conduct systematic studies on the mechanism of interactions between Aβ peptide with lipid membrane. To our knowledge, this was the first time QCM-D was utilized for characterization of Aβ fibrillation starting from monomer states until formation of mature fibrils. The data indicated that peptide-membrane interactions follow a two-step kinetic pathway starting with the adsorption of small (low-n) oligomers until covering all the adsorption sites on the surface. In the second step, the membrane structure is destabilized as the result of interaction with oligomers which leads to lipid loss from the surface. Consistency of the results with the data obtained via other techniques substantiates QCM-D technique as a robust approach to answer the remaining unanswered questions in the field of Alzheimer’s disease.

Amyloid peptide

Nanoparticles

Natural organic matter

Supported lipid bilayer

Constructing an Ionic diode using Solid Supported Lipid bilayers: A Proposal

ruan, cunfan

01 January 2018

Ionic-type transistors are important devices for precise chemical control and biosensing applications. Previous work by Tybrandt et al. has demonstrated a novel approach to constructing an ionic transistor using conducting polymers poly(3,4-ethylenedioxythiophene) polystyrene sulfonate (PEDOT:PSS) and quarternized- polyvinyl benzyl chloride (q-PVBC). This approach could be combined with the 3D stamp method of generating concentration gradients in supported lipid bilayers (SLBs) as shown by Liu et al. to create a charged lipid-based ionic polar junction transistor. An electric potential applied across the SLB would drive charged lipids towards the opposite electrode, thus generating current flow across the SLB. Incorporation of a charged-lipid functionalized PEDOT derivative as demonstrated by Johansson et al. would allow a longer period of current flow before charge carriers are depleted. Such a device could offer novel approaches to biosensing.

Chemisty

Proposal

Solid Supported Lipid Bilayer

Diode

Other Chemistry

Transport by kinesin motors diffusing on a lipid bilayer

Grover, Rahul

23 March 2016

Intracellular transport of membrane-bound vesicles and organelles is a process fundamental for many cellular functions including cell morphogenesis and signaling. The transport is mediated by ensembles of motor proteins, such as kinesins, walking on microtubule tracks. When transporting membrane-bound cargo inside a cell, the motors are linked to diffusive lipid bilayers either directly or via adaptor molecules. The fluidity of the lipid bilayers induces loose inter-motor coupling which is likely to impact the collective motor dynamics and may induce cooperativity. Here, we investigate the influence of loose coupling of kinesin motors on its transport characteristics. In the first part of this thesis, we used truncated kinesin-1 motors with a streptavidin-binding-peptide (SBP) tag and performed gliding motility assays on streptavidin-loaded biotinylated supported lipid bilayers (SLBs), so called ‘membrane-anchored’ gliding motility assays. We show that the membrane-anchored motors act cooperatively; the microtubule gliding velocity increases with increasing motor density. This is in contrast to the transport behavior of multiple motors rigidly bound to a substrate. There, the motility is either insensitive to the motor density or shows negative interference at higher motor density, depending on the structure of the motors. The cooperativity in transport driven by membrane-anchored motors can be explained as following: while stepping on a microtubule, membrane-anchored motors slip backwards in the viscous membrane, thus propelling the microtubule in the solution at a velocity, given by the difference of the motor stepping velocity and the slipping velocity. The motor stepping on the microtubule occurs at maximal stepping velocity because the load on the membrane-anchored motors is minute. Thus, the slipping velocity of membrane-anchored motors determines the microtubule gliding velocity. At steady state, the drag force on the microtubule in the solution is equal to the collective drag force on the membrane-anchored motors slipping in the viscous membrane. As a consequence, at low motor density, membrane-anchored motors slip back faster to balance the drag force of the microtubule in the solution. This results in a microtubule gliding velocity significantly lower than the maximal stepping velocity of the individual motors. In contrast, at high motor density, the microtubules are propelled faster with velocities equal to the maximal stepping velocity of individual motors. Because, in this case, the collective drag force on the motors even at very low slipping velocity, is large enough to balance the microtubule drag in the solution. The theoretical model developed based on this explanation is in good agreement with the experimental data of gliding velocities at different motor densities. The model gives information about the distance that the diffusing motors can isotropically reach to bind to a microtubule, which for membrane-anchored kinesin-1 is ~0.3 µm, an order of magnitude higher as compared to rigidly bound motors, owing to the lateral mobility of motors on the membrane. In addition, the model can be used to predict the number of motors involved in transport of a microtubule based on its gliding velocity. In the second part of the thesis, we investigated the effect of loose inter-motor coupling on the transport behavior of KIF16B, a recently discovered kinesin motor with an inherent lipid-binding domain. Recent studies based on cell biological and cell extract experiments, have postulated that cargo binding of KIF16B is required to activate and dimerize the motor, making it a superprocessive motor. Here, we demonstrate that recombinant full-length KIF16B is a dimer even in the absence of cargo or additional proteins. The KIF16B dimers are active and processive, which demonstrates that the motors are not auto-inhibited in our experiments. Thus, in cells and cell extracts Kif16B may be inhibited by additional factors, which are removed upon cargo binding. Single molecule analysis of KIF16B-GFP reveals that the motors are not superprocessive but exhibit a processivity similar to kinesin-1 indicating that additional factors are most likely necessary to achieve superprocessivity. Transport on membrane-anchored KIF16B motors exhibited a similar cooperative behavior as membrane-anchored kinesin-1 where the microtubule gliding velocity increased with increasing motor density. Taken together, our results demonstrate that the loose coupling of motors via lipid bilayers provides flexibility to cytoskeletal transport systems and induces cooperativity in multi-motor transport. Moreover, our ‘membrane-anchored’ gliding motility assays can be used to study the effects of lipid diffusivity (e.g. the presence of lipid micro-domains and rafts), lipid composition, and adaptor proteins on the collective dynamics of different motors.

Molekular Motoren

Molecular motors

Supported Lipid Bilayer

mutli-motor

ddc:570

rvk:WD 5400

Le surfactant pulmonaire, une barrière déterminante de la réponse des cellules à l'exposition aux nanoparticules / Pulmonary surfactant, a critical factor in the cell response to nanoparticles exposure

Mousseau, Fanny

26 January 2017

Les particules fines émises par l'activité humaine sont la cause de diverses pathologies pulmonaires et cardiaques. Les particules de taille inférieure à 100 nm, appelées nanoparticules, sont particulièrement nocives car une fois inhalées, elles peuvent atteindre les alvéoles pulmonaires, lieux des échanges gazeux. Dans les alvéoles, les nanoparticules entrent d'abord en contact avec le surfactant pulmonaire. Ce fluide biologique tapisse les cellules épithéliales des alvéoles sur une épaisseur de quelques centaines de nanomètres et est composé de phospholipides et de protéines, les phospholipides étant assemblés sous forme de vésicules et corps multi-lamellaires. Dans ce travail, nous avons sélectionné des nanoparticules modèles de nature différente connues pour leur toxicité cellulaire (latex, oxydes métalliques, silice). Leur interaction avec un fluide pulmonaire mimétique administré aux prématurés (Curosurf®) a été étudiée en détail par microscopie optique et électronique, et par diffusion de la lumière. Nous avons mis en évidence que cette interaction est non spécifique et d'origine électrostatique. La diversité des structures hybrides obtenues entre particules et vésicules témoigne cependant de la complexité de cette interaction. En contrôlant cette interaction, nous avons formulé des particules couvertes d’une bicouche supportée de Curosurf® qui possèdent des propriétés remarquables de stabilité et de furtivité en milieu biologique.Dans une seconde partie, nous avons étudié le rôle du surfactant pulmonaire sur l’interaction entre particules et cellules épithéliales alvéolaires (A459). A l'aide d'expériences de biologie cellulaire réalisées in vitro, nous avons observé que la présence de surfactant diminue de manière significative le nombre de particules internalisées par les cellules. Dans le même temps, nous avons constaté une augmentation importante de la viabilité cellulaire. Une conclusion majeure de notre travail concerne la mise en évidence du rôle protecteur joué par le surfactant pulmonaire dans les mécanismes d'interaction des nanoparticules avec l'épithélium alvéolaire / Particulate matter emitted by human activity are the cause of various pulmonary and cardiac diseases. After inhalation, nanoparticles (ie particles smaller than 100 nm) can reach the pulmonary alveoli, where the gas exchanges take place. In the alveoli, the nanoparticles first encounter the pulmonary surfactant which is the fluid that lines the epithelial cells. Of a few hundreds of nanometers in thickness, the pulmonary fluid is composed of phospholipids and proteins, the phospholipids being assembled in multilamellar vesicles. In this work, we considered model nanoparticles of different nature (latex, metal oxides, silica). Their interaction with a mimetic pulmonary fluid administered to premature infants (Curosurf®) was studied by light scattering and by optical and electron microscopy. We have shown that the interaction is non-specific and mainly of electrostatic origin. The wide variety of hybrid structures found in this work attests however of the complexity of the phospholipid/particle interaction. In addition, we succeeded in formulating particles covered with a Curosurf® supported bilayer. These particles exhibit remarkable stability and stealthiness in biological environment. In a second part, we studied the role of the pulmonary surfactant on the interactions between nanoparticles and alveolar epithelial cells (A459). With cellular biology assays, we observed that the number of internalized particles decreases dramatically in presence of surfactant. At the same time, we found a significant increase in the A459 cell viability. Our study shows the importance of the pulmonary surfactant in protecting the alveolar epithelium in case of nanoparticle exposure

Curosurf®

Bicouche lipidique supportée

Agrégat

Cellules A549

Toxicité

Curosurf®

Supported lipid bilayer

Aggregate

Cells A549

Toxicity

Protein Separation and Label-Free Detection on Supported Lipid Bilayers

Liu, Chunming

2012 August 1900

Membrane-bound proteins and charged lipids are separated based on their charge-to-size ratio by electrophoretic-electroosmotic focusing (EEF) method on supported lipid bilayers (SLBs). EEF uses opposing electrophoretic and electroosmotic forces to focus and separate proteins and lipids into narrow bands from an initially homogeneous mixture. Membrane-associated species were focused into specific positions within the SLB in a highly repeatable fashion. The steady-state focusing positions of the proteins could be predicted and controlled by tuning experimental conditions, such as buffer pH, ionic strength, electric field and temperature. Careful tuning of the variables should enable one to separate mixtures of membrane proteins with only subtle differences. The EEF technique was found to be an effective way to separate protein mixtures with low initial concentrations and it overcame diffusive peak broadening problem. A "SLB differentiation" post-separation SLB treatment method was also developed by using magnetic particles to rapidly slice the whole SLB into many small patches after electrophoretic separation, while keeping the majority of materials on surface and avoiding the use of chemical reactions. Label-free detection techniques were also developed based on EEF on SLBs. First, a new separation based label-free detection method was developed based on the change of focusing position of fluorescently labeled ligands. This technique is capable of simultaneous detecting multiple protein competitive binding on the same ligand on SLBs. Low concentration protein can be detected in the presence of interfering proteins and high concentration of BSA. The fluorescent ligands were moved to different focusing positions in a charged SLB patch by different binding proteins. Both free ligand and protein bound ligand concentrations were obtained. Therefore, both protein identity and quantity information were obtained simultaneously. Second, the focusing position of fluorescent biomarkers on SLB was used to monitor the phospholipase D catalyzed hydrolysis of phosphatidylcholine (PC) to form phosphatidic acid (PA), which is involved with the change of charge on the phospholipids. The focusing position of fluorescent membrane-bound biomarker in the EEF experiment is directly determined by the negative charge density on SLB. Other enzyme reactions involved with the change of phospholipids charge can be monitored in a label-free fashion in a similar way.

Supported Lipid Bilayer

Electrophoretic-Electroosmotic Focusing

Protein Separation

Label-Free Detection

Transport by kinesin motors diffusing on a lipid bilayer

Grover, Rahul

25 November 2015

Intracellular transport of membrane-bound vesicles and organelles is a process fundamental for many cellular functions including cell morphogenesis and signaling. The transport is mediated by ensembles of motor proteins, such as kinesins, walking on microtubule tracks. When transporting membrane-bound cargo inside a cell, the motors are linked to diffusive lipid bilayers either directly or via adaptor molecules. The fluidity of the lipid bilayers induces loose inter-motor coupling which is likely to impact the collective motor dynamics and may induce cooperativity. Here, we investigate the influence of loose coupling of kinesin motors on its transport characteristics. In the first part of this thesis, we used truncated kinesin-1 motors with a streptavidin-binding-peptide (SBP) tag and performed gliding motility assays on streptavidin-loaded biotinylated supported lipid bilayers (SLBs), so called ‘membrane-anchored’ gliding motility assays. We show that the membrane-anchored motors act cooperatively; the microtubule gliding velocity increases with increasing motor density. This is in contrast to the transport behavior of multiple motors rigidly bound to a substrate. There, the motility is either insensitive to the motor density or shows negative interference at higher motor density, depending on the structure of the motors. The cooperativity in transport driven by membrane-anchored motors can be explained as following: while stepping on a microtubule, membrane-anchored motors slip backwards in the viscous membrane, thus propelling the microtubule in the solution at a velocity, given by the difference of the motor stepping velocity and the slipping velocity. The motor stepping on the microtubule occurs at maximal stepping velocity because the load on the membrane-anchored motors is minute. Thus, the slipping velocity of membrane-anchored motors determines the microtubule gliding velocity. At steady state, the drag force on the microtubule in the solution is equal to the collective drag force on the membrane-anchored motors slipping in the viscous membrane. As a consequence, at low motor density, membrane-anchored motors slip back faster to balance the drag force of the microtubule in the solution. This results in a microtubule gliding velocity significantly lower than the maximal stepping velocity of the individual motors. In contrast, at high motor density, the microtubules are propelled faster with velocities equal to the maximal stepping velocity of individual motors. Because, in this case, the collective drag force on the motors even at very low slipping velocity, is large enough to balance the microtubule drag in the solution. The theoretical model developed based on this explanation is in good agreement with the experimental data of gliding velocities at different motor densities. The model gives information about the distance that the diffusing motors can isotropically reach to bind to a microtubule, which for membrane-anchored kinesin-1 is ~0.3 µm, an order of magnitude higher as compared to rigidly bound motors, owing to the lateral mobility of motors on the membrane. In addition, the model can be used to predict the number of motors involved in transport of a microtubule based on its gliding velocity. In the second part of the thesis, we investigated the effect of loose inter-motor coupling on the transport behavior of KIF16B, a recently discovered kinesin motor with an inherent lipid-binding domain. Recent studies based on cell biological and cell extract experiments, have postulated that cargo binding of KIF16B is required to activate and dimerize the motor, making it a superprocessive motor. Here, we demonstrate that recombinant full-length KIF16B is a dimer even in the absence of cargo or additional proteins. The KIF16B dimers are active and processive, which demonstrates that the motors are not auto-inhibited in our experiments. Thus, in cells and cell extracts Kif16B may be inhibited by additional factors, which are removed upon cargo binding. Single molecule analysis of KIF16B-GFP reveals that the motors are not superprocessive but exhibit a processivity similar to kinesin-1 indicating that additional factors are most likely necessary to achieve superprocessivity. Transport on membrane-anchored KIF16B motors exhibited a similar cooperative behavior as membrane-anchored kinesin-1 where the microtubule gliding velocity increased with increasing motor density. Taken together, our results demonstrate that the loose coupling of motors via lipid bilayers provides flexibility to cytoskeletal transport systems and induces cooperativity in multi-motor transport. Moreover, our ‘membrane-anchored’ gliding motility assays can be used to study the effects of lipid diffusivity (e.g. the presence of lipid micro-domains and rafts), lipid composition, and adaptor proteins on the collective dynamics of different motors.:Abstract vii 1 Introduction 1 1.1 Intracellular transport driven by motor proteins 2 1.2 Attachment of motor proteins to cargo 13 1.3 In vitro approaches to study transport by motor proteins 16 1.4 Aim of this study 23 2 Transport by kinesin-1 anchored to supported lipid bilayers 24 2.1 Formation and characterization of biotinylated SLBs 26 2.2 Anchoring kinesin-1 to biotinylated SLBs 28 2.3 Gliding motility of microtubules by kinesin-1 linked to SLBs 34 2.4 Theoretical description of gliding motility on diffusing motor proteins 40 2.5 Comparison of the gliding velocity between experiment and theory 46 2.6 Gliding motility on phase-separated SLBs 53 2.7 Discussion 55 3 Transport by KIF16B with an inherent lipid-binding domain 62 3.2 Biophysical characterization of KIF16B 70 3.3 Gliding motility of microtubules by KIF16B linked to SLBs 78 3.4 Transport of SUVs and lipid-coated beads attached to KIF16B 87 3.5 Discussion 90 4 Conclusion and outlook 96 5 Materials and methods 99 5.1 Reagents and solutions 99 5.2 Molecular biology 100 5.3 Protein expression and purification 104 5.4 In vitro motility assays 110 5.5 Image acquisition and data analysis 118 References 126 List of figures 141 List of tables 143 Abbreviations and symbols 144 Acknowledgements 147

info:eu-repo/classification/ddc/570

ddc:570

Molekular Motoren