Confined Diffusion Without Fences of a G-Protein-Coupled Receptor as Revealed by Single Particle Tracking

Perillo

et al. 2016

Biophysical Journal

Whereas important discoveries made by single-particle tracking have changed our view of the plasma membrane organization and motor protein dynamics in the past three decades, experimental studies of intracellular processes using singleparticle tracking are rather scarce because of the lack of three-dimensional (3D) tracking capacity. In this study we use a newly developed 3D single-particle tracking method termed TSUNAMI (Tracking of Single particles Using Nonlinear And Multiplexed Illumination) to investigate epidermal growth factor receptor (EGFR) trafficking dynamics in live cells at 16/43 nm (xy/z) spatial resolution, with track duration ranging from 2 to 10 min and vertical tracking depth up to tens of microns. To analyze the long 3D trajectories generated by the TSUNAMI microscope, we developed a trajectory analysis algorithm, which reaches 81% segment classification accuracy in control experiments (termed simulated movement experiments). When analyzing 95 EGF-stimulated EGFR trajectories acquired in live skin cancer cells, we find that these trajectories can be separated into three groups-immobilization (24.2%), membrane diffusion only (51.6%), and transport from membrane to cytoplasm (24.2%). When EGFRs are membrane-bound, they show an interchange of Brownian diffusion and confined diffusion. When EGFRs are internalized, transitions from confined diffusion to directed diffusion and from directed diffusion back to confined diffusion are clearly seen. This observation agrees well with the model of clathrin-mediated endocytosis.

Section: Challenges In Molecular Trajectory Analysissupporting

confidence: 74%

Section: Extracting Dynamic Parameters From Msdmentioning

confidence: 99%

Section: Extracting Dynamic Parameters From Msdmentioning

confidence: 99%

Section: Msd Curve Fittingmentioning

confidence: 99%

See 2 more Smart Citations

Segmentation of 3D Trajectories Acquired by TSUNAMI Microscope: An Application to EGFR Trafficking

Perillo

et al. 2016

Biophysical Journal

“…In the work performed on the μ opioid receptor, it was also observed that the macroscopic diffusion coefficient, D M , is correlated to L 2 : D M ∼ L 2 . The detection of jumps by a new algorithm (see "Appendix 1") showed that the trajectories do not display enough jumps over actinlike barriers to account for the observed relationship [48].An alternative mechanism known as "interacting Brownian particle" model was proposed to explain the observed diffusion behaviours [15]. It stated that attractive longrange interactions can be sufficiently strong to ensure the stability of small confined assemblies of proteins without invoking external barriers (see Fig.…”

mentioning

confidence: 99%

What do diffusion measurements tell us about membrane compartmentalisation? Emergence of the role of interprotein interactions

2008

Self Cite

The techniques of diffusion analysis based on optical microscopy approaches have revealed a great diversity of the dynamic organisation of cell membranes. For a long period, two frameworks have dominated the way of representing the membrane structure: the membrane skeleton fences and the lipid raft models. Progresses in the methods of data analysis have shed light on the features and consequently the possible origin of membrane domains: Inter-protein interactions play a role in confinement. Innovative developments pushing forward the spatiotemporal resolution limits are currently emerging, which are likely to provide in the future a detailed understanding of the intimate functional dynamic organisation of the cell membrane. Keywords Membrane domain . Diffusion . Protein interaction OverviewThe main function of membranes is to generate close compartments: The cell itself (by the plasma membrane) and also the nucleus (by nuclear envelope), the Golgi apparatus, the endoplasmic reticulum, various organelles or the vesicles which are involved in transport processes. Membranes delimit these structures and allow them to have a different composition from the rest of the cell by restricting the diffusion of ions and macromolecules. The specific transport of molecules or information across the membrane is devoted to membrane proteins. Membranes are essentially composed of lipid and proteins, each of them representing about 50% in weight. Lipids are amphiphilic molecules that spontaneously form a bilayer in water. Among the variety of lipids, cholesterol has a specific place since it is particularly abundant in eukaryotic cells. Cholesterol can modify the lipid molecular order [1] and is presumed to participate in lipid micro-phase separation (rafts) [2][3][4][5].Since the structure of biological membranes is maintained by non-covalent bonds, they have first been considered as a fluid lipid bilayer in which embedded proteins are free to diffuse [6]. After the advent of this fluid mosaic model postulating a random distribution of membrane molecules [6], experimental evidence showed that the proteins and lipids are distributed heterogeneously in the membrane. For example, incomplete recoveries were systematically observed in fluorescence recovery after photobleaching (FRAP; see "Appendix 1") experiments. The first indication of the presence of micrometer-sized domains was obtained by FRAP. Yechiel and Edidin found a decrease of the mobile fraction with increasing radius of the bleaching spot ([7, 8] and see "Appendix 1").The huge diversity of lipids and proteins implies that a very large number of combinatorial interactions can occur between them [9]. Since all lipids and proteins do not J Chem Biol (2008) [14,15]. Interactions of membrane proteins with the cytoskeleton or with the glycocalyx can also affect the membrane organisation and are likely to play a confining role [16]. A significant challenge of cell biology is to characterise and to understand not only the origin but also the role of these micrometric ...

Encyclopedia of Analytical Chemistry

Membrane Dynamics: Fluorescence Spectroscopy

Subburaj

Gallego

García‐Sáez

2000

Membranes are dynamic lipophilic structures that constitute a selective barrier essential for the smooth functioning of cellular machinery. Their complex and highly heterogeneous composition, as well as the intricate diffusion patterns that they display, have been intensely studied in the past decades. Several innovative microscopy techniques have recently been developed to gain insight into the basis of membrane dynamics, interactions, and molecular organization. In this article, we introduce four pioneer fluorescence‐based approaches that have substantially broadened our overall understanding of membranes: fluorescence correlation spectroscopy (FCS), single particle tracking (SPT), fluorescence recovery after photobleaching (FRAP), and 6‐lauroyl‐2‐(dimethylamino)‐naphtalene (LAURDAN) microscopy. We discuss each technique in detail, explaining their principles, methodology, and applications in the research of the dynamic processes controlled by membranes.