Investigating spatial distribution and dynamics of membrane proteins in polymer-tethered lipid bilayer systems using single molecule-sensitive imaging techniques

Ge, Yifan

12 1900

Indiana University-Purdue University Indianapolis (IUPUI) / Plasma membranes are complex supramolecular assemblies comprised of lipids and membrane proteins. Both types of membrane constituents are organized in highly dynamic patches with profound impact on membrane functionality, illustrating the functional importance of plasma membrane fluidity. Exemplary, dynamic processes of membrane protein oligomerization and distribution are of physiological and pathological importance. However, due to the complexity of the plasma membrane, the underlying regulatory mechanisms of membrane protein organization and distribution remain elusive. To address this shortcoming, in this thesis work, different mechanisms of dynamic membrane protein assembly and distribution are examined in a polymer-tethered lipid bilayer system using comple-mentary confocal optical detection techniques, including 2D confocal imaging and single molecule-sensitive confocal fluorescence intensity analysis methods [fluorescence correlation spectroscopy (FCS) autocorrelation analysis and photon counting histogram (PCH) method]. Specifically, this complementary methodology was applied to investigate mechanisms of membrane protein assembly and distribution, which are of significance in the areas of membrane biophysics and cellular mechanics. From the membrane biophysics perspective, the role of lipid heterogeneities in the distribution and function of membrane proteins in the plasma membrane has been a long-standing problem. One of the most well-known membrane heterogeneities are known as lipid rafts, which are domains enriched in sphingolipids and cholesterol (CHOL). A hallmark of lipid rafts is that they are important regulators of membrane protein distribution and function in the plasma membrane. Unfortunately, progress in deciphering the mechanisms of raft-mediated regulation of membrane protein distribution has been sluggish, largely due to the small size and transient nature of raft domains in cellular membranes. To overcome this challenge, the current thesis explored the distribution and oligomerization of membrane proteins in raft-mimicking lipid mixtures, which form stable coexisting CHOL-enriched and CHOL-deficient lipid domains of micron-size, which can easily be visualized using optical microscopy techniques. In particular, model membrane experiments were designed, which provided insight into the role of membrane CHOL level versus binding of native ligands on the oligomerization state and distribution of GPI-anchored urokinase plasminogen activator receptor (uPAR) and the transmembrane protein αvβ3 integrin. Experiments on uPAR showed that receptor oligomerization and raft sequestration are predominantly influenced by the binding of natural ligands, but are largely independent of CHOL level changes. In contrast, through a presumably different mechanism, the sequestration of αvβ3 integrin in raft-mimicking lipid mixtures is dependent on both ligand binding and CHOL content changes without altering protein oligomerization state. In addition, the significance of membrane-embedded ligands as regulators of integrin sequestration in raft-mimicking lipid mixtures was explored. One set of experiments showed that ganglioside GM3 induces dimerization of α5β1 integrins in a CHOL-free lipid bilayer, while addition of CHOL suppresses such a dimerization process. Furthermore, GM3 was found to recruit α5β1 integrin into CHOL-enriched domains, illustrating the potential sig-nificance of GM3 as a membrane-associated ligand of α5β1 integrin. Similarly, uPAR was observed to form complexes with αvβ3 integrin in a CHOL dependent manner, thereby causing the translocation of the complex into CHOL-enriched domains. Moreover, using a newly developed dual color FCS and PCH assay, the composition of uPAR and integrin within complexes was determined for the first time. From the perspective of cell mechanics, the characterization of the dynamic assembly of membrane proteins during formation of cell adhesions represents an important scientific problem. Cell adhesions play an important role as force transducers of cellular contractile forces. They may be formed between cell and extracellular matrix, through integrin-based focal adhesions, as well as between different cells, through cadherin-based adherens junctions (AJs). Importantly, both types of cell adhesions act as sensitive force sensors, which change their size and shape in response to external mechanical signals. Traditionally, the correlation between adhesion linker assembly and external mechanical cues was investigated by employing polymeric substrates of adjustable substrate stiffness containing covalently attached linkers. Such systems are well suited to mimic the mechanosensitive assembly of focal adhesions (FAs), but fail to replicate the rich dynamics of cell-cell linkages, such as treadmilling of adherens junctions, during cellular force sensing. To overcome this limitation, the 2D confocal imaging methodology was applied to investigate the dynamic assembly of N-cadherin-chimera on the surface of a polymer-tethered lipid multi-bilayer in the presence of plated cells. Here, the N-cadherin chimera-functionalized polymer-tethered lipid bilayer acts as a cell surface-mimicking cell substrate, which: (i) allows the adjustment of substrate stiffness by changing the degree of bilayer stacking and (ii) enables the free assembly of N-cadherin chimera linkers into clusters underneath migrating cells, thereby forming highly dynamic cell-substrate linkages with remarkable parallels to adherens junctions. By applying the confocal methodology, the dynamic assembly of dye-labeled N-cadherin chimera into clusters was monitored underneath adhered cells. Moreover, the long-range mobility of N-cadherin chimera clusters was analyzed by tracking the cluster positions over time using a MATLAB-based multiple-particle tracking method. Disruption of the cytoskeleton organization of plated cells confirmed the disassembly of N-cadherin chimera clusters, emphasizing the important role of the cytoskeleton of migrating cells during formation of cadherin-based cell-substrate linkages. Size and dynamics of N-cadherin chimera clusters were also analyzed as a function of substrate stiffness.

membrane protein

membrane biophysics

polymer-tethered lipid bilayer

integrin

cadherin

urokinase plasminogen activator receptor

confocal microscope

single molecule detection

cell mechanosensation

Incorporation de protéines membranaires produites par un système d'expression protéique acellulaire dans des bicouches lipidiques planes / Incorporation of membrane proteins produced by a cell-free expression system into planar lipid lilayers

Coutable, Angelique

14 March 2014

Les protéines membranaires intégrales jouent un rôle essentiel dans le maintien de l’intégrité cellulaire (transports d’ions et de nutriments, transduction de signal, interaction cellule-cellule). Afin de les étudier, ces protéines doivent être produites in vitro. La production classique de ces protéines membranaires intégrales dans des microorganismes présente de nombreuses difficultés liées à leur structure complexe mais aussi à des problèmes de toxicité, empêchant la production de nombre d’entre elles. En outre, pour être produites efficacement, ces protéines ont besoin d’un environnement amphiphile. Dans cette thèse, afin de pallier à ces difficultés, nous avons d’une part utilisé un système d’expression protéique acellulaire, non affecté par la physiologie des cellules vivantes. En outre, nous avons choisi de les intégrer dans des bicouches lipidiques planes reconstituées artificiellement. Dans une première partie, nous avons mis au point l’intégration d’une protéine membranaire intégrale formant un pore, l’alpha hémolysine, dans une bicouche lipidique supportée. Certaines protéines nécessitant un espace plus important de part etd’autre de la membrane, nous avons, dans une seconde partie, développé une bicouche lipidique espacée et ancrée par fusion de liposomes sur des surfaces d’or. Nous démontrons qu’il est possible d’y incorporer des protéines membranaires de type Aquaporine Z sous certaines conditions. Dans une troisième partie, dédiée à la formation de membranes biomimétiques utilisant des molécules lipidiques provenant d’Escherichia coli, nous montrons que la modification de la composition membranaire ne semble pas avoir d’incidence sur l’incorporation de protéines. Enfin, dans une dernière partie, nous avons réalisé des premiers essais d’insertion de protéines membranaires, de type alpha hémolysine, dans des bicouches suspendues afin de montrer que ces protéines produites par le système d’expression acellulaire sont fonctionnelles. / Integral membrane proteins play an essential role in the cell integrity preservation (transport of nutrients and ions, signal transduction, cell-cell interaction). In order to study these proteins, they have to be produced in vitro. Classical production of integral membrane proteins in microorganisms present many difficulties associated with their complex structure and also toxicity problems, preventing production of many of them. Moreover, to be efficiently produced, these proteins require an amphiphilic environment. In order to overcome these difficulties, we used a cell-free protein expression system, unaffected by the physiology ofliving cells. In addition, we chose to integrate them into artificial planar lipid bilayers. In a first part, we have developed the integration of an integral membrane protein forming a pore, the alpha hemolysin, in a supported lipid bilayer. Some proteins require more space on each side of the membrane, therefore in a second part, we have developed a tethered lipid bilayer membrane by liposome fusion on gold surfaces. We demonstrate that it is possible to incorporate membrane protein Aquaporin Z under certain conditions. The third part is dedicated to the formation of biomimetic membranes using lipid molecules from Escherichiacoli, we show that the membrane composition do not affect the protein incorporation. Finally, we have tested alpha hemolysin membrane proteins insertion in suspended lipid bilayers membranes to show that these proteins produced by the cell-free expression system are functional.

Système d'expression acellulaire

Bicouche lipidique plane

Alpha hémolyse

Aquaporine Z

Protéine membranaire

Transcription traduction in vitro

Bicouche lipidique espacée

Free-cell expression system

Planar lipid bilayers

Alpha hemolysin

Aquaporin Z

Membrane protein

In vitro translation traanscription

Tethered lipid bilayer

572.6