Your search keyword '"Fujiwara, Takahiro"' showing total 20 results

1. Transient, nano-scale, liquid-like molecular assemblies coming of age.

Author

Kusumi A, Tsunoyama TA, Suzuki KGN, Fujiwara TK, and Aladag A

Subjects

Humans, Animals, Signal Transduction, Cell Membrane metabolism, Cell Membrane chemistry

Abstract

This review examines the dynamic mechanisms underlying cellular signaling, communication, and adhesion via transient, nano-scale, liquid-like molecular assemblies on the plasma membrane (PM). Traditional views posit that stable, solid-like molecular complexes perform these functions. However, advanced imaging reveals that many signaling and scaffolding proteins only briefly reside in these molecular complexes and that micron-scale protein assemblies on the PM, including cell adhesion structures and synapses, are likely made of archipelagoes of nanoliquid protein islands. Borrowing the concept of liquid-liquid phase separation to form micron-scale biocondensates, we propose that these nano-scale oligomers and assemblies are enabled by multiple weak but specific molecular interactions often involving intrinsically disordered regions. The signals from individual nanoliquid signaling complexes would occur as pulses. Single-molecule imaging emerges as a crucial technique for characterizing these transient nanoliquid assemblies on the PM, suggesting a shift toward a model where the fluidity of interactions underpins signal regulation and integration., Competing Interests: Declaration of competing interest Nothing declared., (Copyright © 2024 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2024

2. Dynamic actin-mediated nano-scale clustering of CD44 regulates its meso-scale organization at the plasma membrane.

Author

Sil P, Mateos N, Nath S, Buschow S, Manzo C, Suzuki KGN, Fujiwara T, Kusumi A, Garcia-Parajo MF, and Mayor S

Subjects

Actomyosin metabolism, Animals, Cell Line, Cytoplasm metabolism, Diffusion, Formins metabolism, Humans, Hyaluronan Receptors chemistry, Models, Biological, Protein Domains, Single Molecule Imaging, Actins metabolism, Cell Membrane metabolism, Hyaluronan Receptors metabolism, Nanoparticles chemistry

Abstract

Transmembrane adhesion receptors at the cell surface, such as CD44, are often equipped with modules to interact with the extracellular matrix (ECM) and the intracellular cytoskeletal machinery. CD44 has been recently shown to compartmentalize the membrane into domains by acting as membrane pickets, facilitating the function of signaling receptors. While spatial organization and diffusion studies of membrane proteins are usually conducted separately, here we combine observations of organization and diffusion by using high spatio-temporal resolution imaging on living cells to reveal a hierarchical organization of CD44. CD44 is present in a meso-scale meshwork pattern where it exhibits enhanced confinement and is enriched in nanoclusters of CD44 along its boundaries. This nanoclustering is orchestrated by the underlying cortical actin dynamics. Interaction with actin is mediated by specific segments of the intracellular domain. This influences the organization of the protein at the nano-scale, generating a selective requirement for formin over Arp2/3-based actin-nucleation machinery. The extracellular domain and its interaction with elements of ECM do not influence the meso-scale organization, but may serve to reposition the meshwork with respect to the ECM. Taken together, our results capture the hierarchical nature of CD44 organization at the cell surface, with active cytoskeleton-templated nanoclusters localized to a meso-scale meshwork pattern.

Published

2020

3. Revealing the Raft Domain Organization in the Plasma Membrane by Single-Molecule Imaging of Fluorescent Ganglioside Analogs.

Author

Suzuki KGN, Ando H, Komura N, Konishi M, Imamura A, Ishida H, Kiso M, Fujiwara TK, and Kusumi A

Subjects

Animals, CD59 Antigens metabolism, CHO Cells, Cell Membrane chemistry, Cricetulus, Fluorescent Dyes chemistry, G(M1) Ganglioside antagonists & inhibitors, G(M1) Ganglioside chemistry, G(M1) Ganglioside metabolism, G(M3) Ganglioside analogs & derivatives, G(M3) Ganglioside chemistry, G(M3) Ganglioside metabolism, Intravital Microscopy instrumentation, Membrane Microdomains chemistry, Microscopy, Fluorescence instrumentation, Microscopy, Fluorescence methods, Single Molecule Imaging instrumentation, Cell Membrane metabolism, Intravital Microscopy methods, Membrane Microdomains metabolism, Single Molecule Imaging methods

Abstract

Gangliosides have been implicated in a variety of physiological processes, particularly in the formation and function of raft domains in the plasma membrane. However, the scarcity of suitable fluorescent ganglioside analogs had long prevented us from determining exactly how gangliosides perform their functions in the live-cell plasma membrane. With the development of new fluorescent ganglioside analogs, as described by Komura et al. (2017), this barrier has been broken. We can now address the dynamic behaviors of gangliosides in the live-cell plasma membrane, using fluorescence microscopy, particularly by single-fluorescent molecule imaging and tracking. Single-molecule tracking of fluorescent GM1 and GM3 revealed that these molecules are transiently and dynamically recruited to monomers (monomer-associated rafts) and homodimer rafts of the raftophilic GPI-anchored protein CD59 in quiescent cells, with exponential residency times of 12 and 40ms, respectively, in a manner dependent on raft-lipid interactions. Upon CD59 stimulation, which induces CD59-cluster signaling rafts, the fluorescent GM1 and GM3 analogs were recruited to the signaling rafts, with a lifetime of 48ms. These results represent the first direct evidence that GPI-anchored receptors and gangliosides interact in a cholesterol-dependent manner. Furthermore, they show that gangliosides continually move in and out of rafts that contain CD59 in an extremely dynamic manner, with much higher frequency than expected previously. Such studies would not have been possible without fluorescent ganglioside probes, which exhibit native-like behavior and single-molecule tracking. In this chapter, we review the methods for single-molecule tracking of fluorescent ganglioside analogs and the results obtained by applying these methods., (© 2018 Elsevier Inc. All rights reserved.)

Published

2018

4. Dynamic Meso-Scale Anchorage of GPI-Anchored Receptors in the Plasma Membrane: Prion Protein vs. Thy1.

Author

Nemoto YL, Morris RJ, Hijikata H, Tsunoyama TA, Shibata ACE, Kasai RS, Kusumi A, and Fujiwara TK

Subjects

Animals, CHO Cells, Cell Membrane chemistry, Cells, Cultured, Cricetinae, Cricetulus, Diffusion, Fluorescent Dyes chemistry, Glycosylphosphatidylinositols metabolism, Hippocampus cytology, Hippocampus metabolism, Microscopy, Fluorescence, Prion Proteins chemistry, Rats, Rats, Wistar, Thy-1 Antigens chemistry, Cell Membrane metabolism, Glycosylphosphatidylinositols chemistry, Prion Proteins metabolism, Thy-1 Antigens metabolism

Abstract

The central mechanism for the transmission of the prion protein misfolding is the structural conversion of the normal cellular prion protein to the pathogenic misfolded prion protein, by the interaction with misfolded prion protein. This process might be enhanced due to the homo-dimerization/oligomerization of normal prion protein. However, the behaviors of normal prion protein in the plasma membrane have remained largely unknown. Here, using single fluorescent-molecule imaging, we found that both prion protein and Thy1, a control glycosylphosphatidylinositol-anchored protein, exhibited very similar intermittent transient immobilizations lasting for a few seconds within an area of 24.2 and 3.5 nm in diameter in CHO-K1 and hippocampal neurons cultured for 1- and 2-weeks, respectively. Prion protein molecules were immobile during 72% of the time, approximately 1.4× more than Thy1, due to prion protein's higher immobilization frequency. When mobile, prion protein diffused 1.7× slower than Thy1. Prion protein's slower diffusion might be caused by its transient interaction with other prion protein molecules, whereas its brief immobilization might be due to temporary association with prion protein clusters. Prion protein molecules might be newly recruited to prion protein clusters all the time, and simultaneously, prion protein molecules in the cluster might be departing continuously. Such dynamic interactions of normal prion protein molecules would strongly enhance the spreading of misfolded prion protein.

Published

2017

5. Confined diffusion of transmembrane proteins and lipids induced by the same actin meshwork lining the plasma membrane.

Author

Fujiwara TK, Iwasawa K, Kalay Z, Tsunoyama TA, Watanabe Y, Umemura YM, Murakoshi H, Suzuki KG, Nemoto YL, Morone N, and Kusumi A

Subjects

Animals, Cell Line, Diffusion, Humans, Models, Biological, Potoroidae, Rats, Actin Cytoskeleton, Cell Membrane metabolism, Phospholipids chemistry, Receptors, Transferrin chemistry

Abstract

The mechanisms by which the diffusion rate in the plasma membrane (PM) is regulated remain unresolved, despite their importance in spatially regulating the reaction rates in the PM. Proposed models include entrapment in nanoscale noncontiguous domains found in PtK2 cells, slow diffusion due to crowding, and actin-induced compartmentalization. Here, by applying single-particle tracking at high time resolutions, mainly to the PtK2-cell PM, we found confined diffusion plus hop movements (termed "hop diffusion") for both a nonraft phospholipid and a transmembrane protein, transferrin receptor, and equal compartment sizes for these two molecules in all five of the cell lines used here (actual sizes were cell dependent), even after treatment with actin-modulating drugs. The cross-section size and the cytoplasmic domain size both affected the hop frequency. Electron tomography identified the actin-based membrane skeleton (MSK) located within 8.8 nm from the PM cytoplasmic surface of PtK2 cells and demonstrated that the MSK mesh size was the same as the compartment size for PM molecular diffusion. The extracellular matrix and extracellular domains of membrane proteins were not involved in hop diffusion. These results support a model of anchored TM-protein pickets lining actin-based MSK as a major mechanism for regulating diffusion., (© 2016 Fujiwara et al. This article is distributed by The American Society for Cell Biology under license from the author(s). Two months after publication it is available to the public under an Attribution–Noncommercial–Share Alike 3.0 Unported Creative Commons License (http://creativecommons.org/licenses/by-nc-sa/3.0).)

Published

2016

6. Lateral diffusion in a discrete fluid membrane with immobile particles.

Author

Kalay Z, Fujiwara TK, Otaka A, and Kusumi A

Subjects

Computer Simulation, Membrane Fluidity, Microfluidics methods, Models, Chemical, Solutions, Biopolymers chemistry, Cell Membrane chemistry, Cell Membrane Permeability, Diffusion, Lipid Bilayers chemistry, Models, Biological

Abstract

Due to the coupling between the plasma membrane and the actin cytoskeleton, membrane molecules such as receptor proteins can become immobilized by binding to cytoskeletal structures. We investigate the effect of immobile membrane molecules on the diffusion of mobile ones by modeling the membrane as a two-dimensional (2D) fluid composed of hard particles and performing event-driven molecular dynamics simulations at a particle density where the system is in an isotropic liquid state. We show that the diffusion coefficient sharply decreases with increasing immobile fraction, dropping by a factor of ∼ 3 as the fraction of immobile particles increases from 0 to 0.1, in a system-size dependent manner. By combining our results with earlier calculations, we estimate that a factor-of-∼ 20 reduction in diffusion coefficients in live cell membranes, a puzzling finding in cell biology, can be accounted for when less than ∼ 22% of the particles in our model system is immobilized. Furthermore, we investigate the effects of confinement induced by a correlated distribution of immobile particles by calculating the distribution of the time it takes for particles to escape from a corral. In the regime where the particles can always escape from the corral, it is found that the escape times follow an exponential distribution, and the mean escape time grows exponentially with the density of obstacles at the corral boundary, increasing by a factor of 3-5 when immobile particles cover 50% of the boundary, and is approximately proportional to the area of the corral. We believe that our findings will be useful in interpreting (1) single molecule observations of membrane molecules and (2) results of particle based simulations that explore the effect of fluid dynamics on molecular transport in a 2D fluid.

Published

2014

7. Rac1 recruitment to the archipelago structure of the focal adhesion through the fluid membrane as revealed by single-molecule analysis.

Author

Shibata AC, Chen LH, Nagai R, Ishidate F, Chadda R, Miwa Y, Naruse K, Shirai YM, Fujiwara TK, and Kusumi A

Subjects

Cytoplasm metabolism, HeLa Cells, Humans, Rho Guanine Nucleotide Exchange Factors, Cell Membrane metabolism, Focal Adhesions metabolism, Guanine Nucleotide Exchange Factors metabolism, rac1 GTP-Binding Protein metabolism

Abstract

The focal adhesion (FA) is an integrin-based structure built in/on the plasma membrane (PM), linking the extracellular matrix to the actin stress-fibers, working as cell migration scaffolds. Previously, we proposed the archipelago architecture of the FA, in which FA largely consists of fluid membrane, dotted with small islands accumulating FA proteins: membrane molecules enter the inter-island channels in the FA zone rather freely, and the integrins in the FA-protein islands rapidly exchanges with those in the bulk membrane. Here, we examined how Rac1, a small G-protein regulating FA formation, and its activators αPIX and βPIX, are recruited to the FA zones. PIX molecules are recruited from the cytoplasm to the FA zones directly. In contrast, majorities of Rac1 molecules first arrive from the cytoplasm on the general inner PM surface, and then enter the FA zones via lateral diffusion on the PM, which is possible due to rapid Rac1 diffusion even within the FA zones, slowed only by a factor of two to four compared with that outside. The constitutively-active Rac1 mutant exhibited temporary and all-time immobilizations in the FA zone, suggesting that upon PIX-induced Rac1 activation at the FA-protein islands, Rac1 tends to be immobilized at the FA-protein islands., (Copyright © 2013 Wiley Periodicals, Inc.)

Published

2013

8. Single-molecule imaging of receptor-receptor interactions.

Author

Suzuki KG, Kasai RS, Fujiwara TK, and Kusumi A

Subjects

Acyl Carrier Protein chemistry, Acyl Carrier Protein genetics, Acyl Carrier Protein metabolism, Animals, CD59 Antigens chemistry, CD59 Antigens genetics, CHO Cells, Cell Line, Tumor, Cell Membrane chemistry, Chemotactic Factors chemistry, Chemotactic Factors genetics, Cricetulus, Fluorescent Dyes chemistry, Gene Expression, Humans, Immunoglobulin Fab Fragments chemistry, Immunoglobulin Fab Fragments metabolism, Kinetics, Microscopy, Fluorescence, Molecular Imaging methods, Peptides chemistry, Peptides genetics, Protein Binding, Protein Multimerization, CD59 Antigens metabolism, Cell Membrane metabolism, Chemotactic Factors metabolism, Fluorescent Antibody Technique methods, Peptides metabolism, Staining and Labeling methods

Abstract

Single-molecule imaging is a powerful tool for the study of dynamic molecular interactions in living cell plasma membranes. Herein, we describe a single-molecule imaging microscopy technique that can be used to measure lifetimes and densities of receptor dimers and oligomers. This method can be performed using a total internal reflection fluorescent microscope equipped with one or two high-sensitivity cameras. For dual-color observation, two images obtained synchronously in different colors are spatially corrected and then overlaid. Receptors must be expressed at low density in cell plasma membranes because high-density expression (>2 molecules/μm(2)) creates difficulty for tracking individual fluorescent spots. In addition, the receptors should be labeled with highly photostable fluorophores at high efficiency because short photobleaching lifetimes and low labeling efficiency of receptors reduce the probability of detecting dimers and oligomers. In this chapter, we describe methods for observing and detecting colocalization of the individual fluorescent spots of receptors labeled with fluorophores via small tags and the estimation of true dimer and oligomer lifetimes after correction with photobleaching lifetimes of fluorophores., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2013

9. Archipelago architecture of the focal adhesion: membrane molecules freely enter and exit from the focal adhesion zone.

Author

Shibata AC, Fujiwara TK, Chen L, Suzuki KG, Ishikawa Y, Nemoto YL, Miwa Y, Kalay Z, Chadda R, Naruse K, and Kusumi A

Subjects

Animals, Biological Transport, Diffusion, HeLa Cells, Humans, Integrin beta3 metabolism, Models, Biological, Rats, Receptors, Transferrin metabolism, Thy-1 Antigens metabolism, Time Factors, Cell Membrane metabolism, Focal Adhesions metabolism, Proteins metabolism

Abstract

The focal adhesion (FA) is an integrin-based structure built in/on the plasma membrane, mechanically linking the extracellular matrix with the termini of actin stress fibers, providing key scaffolds for the cells to migrate in tissues. The FA was considered as a micron-scale, massive assembly of various proteins, although its formation and decomposition occur quickly in several to several 10 s of minutes. The mechanism of rapid FA regulation has been a major mystery in cell biology. Here, using fast single fluorescent-molecule imaging, we found that transferrin receptor and Thy1, non-FA membrane proteins, readily enter the FA zone, diffuse rapidly there, and exit into the bulk plasma membrane. Integrin β3 also readily enters the FA zone, and repeatedly undergoes temporary immobilization and diffusion in the FA zone, whereas approximately one-third of integrin β3 is immobilized there. These results are consistent with the archipelago architecture of the FA, which consists of many integrin islands: the membrane molecules enter the inter-island channels rather freely, and the integrins in the integrin islands can be rapidly exchanged with those in the bulk membrane. Such an archipelago architecture would allow rapid FA formation and disintegration, and might be applicable to other large protein domains in the plasma membrane., (Copyright © 2012 Wiley Periodicals, Inc.)

Published

2012

10. Membrane mechanisms for signal transduction: the coupling of the meso-scale raft domains to membrane-skeleton-induced compartments and dynamic protein complexes.

Author

Kusumi A, Fujiwara TK, Morone N, Yoshida KJ, Chadda R, Xie M, Kasai RS, and Suzuki KG

Subjects

Actin Cytoskeleton chemistry, Cell Membrane physiology, Cell Membrane ultrastructure, Cell Membrane Permeability, Cholesterol chemistry, Diffusion, Membranes, Artificial, Microscopy, Electron, Models, Biological, Protein Interaction Mapping, Cell Membrane chemistry, Membrane Microdomains chemistry, Membrane Proteins chemistry, Multiprotein Complexes chemistry, Signal Transduction

Abstract

Virtually all biological membranes on earth share the basic structure of a two-dimensional liquid. Such universality and peculiarity are comparable to those of the double helical structure of DNA, strongly suggesting the possibility that the fundamental mechanisms for the various functions of the plasma membrane could essentially be understood by a set of simple organizing principles, developed during the course of evolution. As an initial effort toward the development of such understanding, in this review, we present the concept of the cooperative action of the hierarchical three-tiered meso-scale (2-300 nm) domains in the plasma membrane: (1) actin membrane-skeleton-induced compartments (40-300 nm), (2) raft domains (2-20 nm), and (3) dynamic protein complex domains (3-10nm). Special attention is paid to the concept of meso-scale domains, where both thermal fluctuations and weak cooperativity play critical roles, and the coupling of the raft domains to the membrane-skeleton-induced compartments as well as dynamic protein complexes. The three-tiered meso-domain architecture of the plasma membrane provides an excellent perspective for understanding the membrane mechanisms of signal transduction., (Copyright © 2012. Published by Elsevier Ltd.)

Published

2012

11. Confining domains lead to reaction bursts: reaction kinetics in the plasma membrane.

Author

Kalay Z, Fujiwara TK, and Kusumi A

Subjects

Cell Membrane chemistry, Computer Simulation, Diffusion, Kinetics, Membrane Lipids metabolism, Membrane Microdomains chemistry, Membrane Proteins metabolism, Time Factors, Algorithms, Cell Membrane metabolism, Membrane Microdomains metabolism, Models, Biological

Abstract

Confinement of molecules in specific small volumes and areas within a cell is likely to be a general strategy that is developed during evolution for regulating the interactions and functions of biomolecules. The cellular plasma membrane, which is the outermost membrane that surrounds the entire cell, was considered to be a continuous two-dimensional liquid, but it is becoming clear that it consists of numerous nano-meso-scale domains with various lifetimes, such as raft domains and cytoskeleton-induced compartments, and membrane molecules are dynamically trapped in these domains. In this article, we give a theoretical account on the effects of molecular confinement on reversible bimolecular reactions in a partitioned surface such as the plasma membrane. By performing simulations based on a lattice-based model of diffusion and reaction, we found that in the presence of membrane partitioning, bimolecular reactions that occur in each compartment proceed in bursts during which the reaction rate is sharply and briefly increased even though the asymptotic reaction rate remains the same. We characterized the time between reaction bursts and the burst amplitude as a function of the model parameters, and discussed the biological significance of the reaction bursts in the presence of strong inhibitor activity.

Published

2012

12. Hierarchical organization of the plasma membrane: investigations by single-molecule tracking vs. fluorescence correlation spectroscopy.

Author

Kusumi A, Shirai YM, Koyama-Honda I, Suzuki KG, and Fujiwara TK

Subjects

Animals, Cell Membrane metabolism, Diffusion, Fluorescent Antibody Technique methods, Humans, Membrane Lipids chemistry, Membrane Lipids metabolism, Membrane Microdomains chemistry, Membrane Microdomains metabolism, Membrane Microdomains physiology, Membrane Proteins chemistry, Membrane Proteins metabolism, Microscopy, Fluorescence methods, Models, Biological, Models, Molecular, Protein Multimerization physiology, Spectrometry, Fluorescence methods, Cell Membrane chemistry

Abstract

Single-molecule tracking and fluorescence correlation spectroscopy (FCS) applied to the plasma membrane in living cells have allowed a number of unprecedented observations, thus fostering a new basic understanding of molecular diffusion, interaction, and signal transduction in the plasma membrane. It is becoming clear that the plasma membrane is a heterogeneous entity, containing diverse structures on nano-meso-scales (2-200 nm) with a variety of lifetimes, where certain membrane molecules stay together for limited durations. Molecular interactions occur in the time-dependent inhomogeneous two-dimensional liquid of the plasma membrane, which might be a key for plasma membrane functions., (Copyright 2010 Federation of European Biochemical Societies. Published by Elsevier B.V. All rights reserved.)

Published

2010

13. Three-dimensional reconstruction of the membrane skeleton at the plasma membrane interface by electron tomography.

Author

Morone N, Fujiwara T, Murase K, Kasai RS, Ike H, Yuasa S, Usukura J, and Kusumi A

Subjects

Actin Cytoskeleton metabolism, Animals, Cell Compartmentation physiology, Cell Line, Cell Membrane metabolism, Cell Membrane Permeability physiology, Cytoskeleton metabolism, Diffusion, Fibroblasts metabolism, Fibroblasts ultrastructure, Immunohistochemistry, Keratinocytes metabolism, Keratinocytes ultrastructure, Microfilament Proteins metabolism, Models, Biological, Rats, Actin Cytoskeleton ultrastructure, Cell Membrane ultrastructure, Cytoskeleton ultrastructure, Microscopy, Electron methods

Abstract

Three-dimensional images of the undercoat structure on the cytoplasmic surface of the upper cell membrane of normal rat kidney fibroblast (NRK) cells and fetal rat skin keratinocytes were reconstructed by electron tomography, with 0.85-nm-thick consecutive sections made approximately 100 nm from the cytoplasmic surface using rapidly frozen, deeply etched, platinum-replicated plasma membranes. The membrane skeleton (MSK) primarily consists of actin filaments and associated proteins. The MSK covers the entire cytoplasmic surface and is closely linked to clathrin-coated pits and caveolae. The actin filaments that are closely apposed to the cytoplasmic surface of the plasma membrane (within 10.2 nm) are likely to form the boundaries of the membrane compartments responsible for the temporary confinement of membrane molecules, thus partitioning the plasma membrane with regard to their lateral diffusion. The distribution of the MSK mesh size as determined by electron tomography and that of the compartment size as determined from high speed single-particle tracking of phospholipid diffusion agree well in both cell types, supporting the MSK fence and MSK-anchored protein picket models.

Published

2006

14. Rapid hop diffusion of a G-protein-coupled receptor in the plasma membrane as revealed by single-molecule techniques.

Author

Suzuki K, Ritchie K, Kajikawa E, Fujiwara T, and Kusumi A

Subjects

Actins chemistry, Animals, Bridged Bicyclo Compounds, Heterocyclic chemistry, CHO Cells, Cell Line, Colloids chemistry, Cricetinae, Diffusion, Green Fluorescent Proteins metabolism, Kidney metabolism, Membrane Proteins metabolism, Microscopy, Video, Models, Biological, Models, Molecular, Models, Statistical, Rats, Temperature, Thiazoles chemistry, Thiazolidines, Time Factors, Biophysics methods, Cell Membrane metabolism, Cell Membrane physiology, Receptors, G-Protein-Coupled chemistry

Abstract

Diffusion of a G-protein coupled receptor, mu-opioid receptor (muOR), in the plasma membrane was tracked by single-fluorescent molecule video imaging and high-speed single-particle tracking. At variance with a previous publication, where gold-tagged muOR was found to be totally confined within a domain, which in turn underwent very slow diffusion itself, we found that muOR undergoes rapid hop diffusion over membrane compartments (210-nm and 730-nm nested double compartments in the case of normal rat kidney cell line), which are likely delimited by the actin-based membrane-skeleton "fence or corrals" and its associated transmembrane protein "pickets", at a rate comparable to that for transferrin receptor (every 45 and 760 ms on average, respectively), suggesting that the fence and picket models may also be applicable to G-protein coupled receptors. Further, we found that strong confinement of gold-labeled muOR could be induced by the prolonged on-ice preincubation of the gold probe with the cells, showing that this procedure should be avoided in future single-particle tracking experiments. Based on the dense, long trajectories of muOR obtained by high-speed single-particle tracking, the membrane compartments apposed and adjoined to each other could be defined that are delimited by rather straight boundaries, consistent with the involvement of actin filaments in membrane compartmentalization.

Published

2005

15. Detection of non-Brownian diffusion in the cell membrane in single molecule tracking.

Author

Ritchie K, Shan XY, Kondo J, Iwasawa K, Fujiwara T, and Kusumi A

Subjects

Animals, Cell Membrane ultrastructure, Computer Simulation, Diffusion, Dipodomys, Kidney ultrastructure, Microscopy, Fluorescence, Microscopy, Video, Models, Chemical, Receptors, Transferrin ultrastructure, Cell Membrane chemistry, Cell Membrane metabolism, Kidney chemistry, Kidney metabolism, Models, Biological, Protein Transport physiology, Receptors, Transferrin chemistry, Receptors, Transferrin metabolism

Abstract

Molecules undergo non-Brownian diffusion in the plasma membrane, but the mechanism behind this anomalous diffusion is controversial. To characterize the anomalous diffusion in the complex system of the plasma membrane and to understand its underlying mechanism, single-molecule/particle methods that allow researchers to avoid ensemble averaging have turned out to be highly effective. However, the intrinsic problems of time-averaging (resolution) and the frequency of the observations have not been explored. These would not matter for the observations of simple Brownian particles, but they do strongly affect the observation of molecules undergoing anomalous diffusion. We examined these effects on the apparent motion of molecules undergoing simple, totally confined, or hop diffusion, using Monte Carlo simulations of particles undergoing short-term confined diffusion within a compartment and long-term hop diffusion between these compartments, explicitly including the effects of time-averaging during a single frame of the camera (exposure time) and the frequency of observations (frame rate). The intricate relationships of these time-related experimental parameters with the intrinsic diffusion parameters have been clarified, which indicated that by systematically varying the frame time and rate, the anomalous diffusion can be clearly detected and characterized. Based on these results, single-particle tracking of transferrin receptor in the plasma membrane of live PtK2 cells were carried out, varying the frame time between 0.025 and 33 ms (0.03-40 kHz), which revealed the hop diffusion of the receptor between 47-nm (average) compartments with an average residency time of 1.7 ms, with the aid of single fluorescent-molecule video imaging.

Published

2005

16. Paradigm shift of the plasma membrane concept from the two-dimensional continuum fluid to the partitioned fluid: high-speed single-molecule tracking of membrane molecules.

Author

Kusumi A, Nakada C, Ritchie K, Murase K, Suzuki K, Murakoshi H, Kasai RS, Kondo J, and Fujiwara T

Subjects

Actins chemistry, Cholesterol metabolism, Cytoskeleton metabolism, Diffusion, Lipid Metabolism, Liposomes metabolism, Membranes, Artificial, Models, Biological, Models, Molecular, Neurons metabolism, Time Factors, Biophysics methods, Cell Membrane metabolism, Microscopy, Video methods

Abstract

Recent advancements in single-molecule tracking methods with nanometer-level precision now allow researchers to observe the movement, recruitment, and activation of single molecules in the plasma membrane in living cells. In particular, on the basis of the observations by high-speed single-particle tracking at a frame rate of 40,000 frames s(1), the partitioning of the fluid plasma membrane into submicron compartments throughout the cell membrane and the hop diffusion of virtually all the molecules have been proposed. This could explain why the diffusion coefficients in the plasma membrane are considerably smaller than those in artificial membranes, and why the diffusion coefficient is reduced upon molecular complex formation (oligomerization-induced trapping). In this review, we first describe the high-speed single-molecule tracking methods, and then we critically review a new model of a partitioned fluid plasma membrane and the involvement of the actin-based membrane-skeleton "fences" and anchored-transmembrane protein "pickets" in the formation of compartment boundaries.

Published

2005

17. Ultrafine membrane compartments for molecular diffusion as revealed by single molecule techniques.

Author

Murase K, Fujiwara T, Umemura Y, Suzuki K, Iino R, Yamashita H, Saito M, Murakoshi H, Ritchie K, and Kusumi A

Subjects

Animals, CHO Cells, Cells, Cultured, Cholesterol chemistry, Cricetinae, Cricetulus, Extracellular Matrix metabolism, Fluorescent Dyes chemistry, HeLa Cells, Humans, Rats, Cell Compartmentation physiology, Cell Membrane metabolism, Cytoskeleton metabolism, Models, Theoretical, Phosphatidylethanolamines chemistry

Abstract

Plasma membrane compartments, delimited by transmembrane proteins anchored to the membrane skeleton (anchored-protein picket model), would provide the membrane with fundamental mosaicism because they would affect the movement of practically all molecules incorporated in the cell membrane. Understanding such basic compartmentalized structures of the cell membrane is critical for further studies of a variety of membrane functions. Here, using both high temporal-resolution single particle tracking and single fluorescent molecule video imaging of an unsaturated phospholipid, DOPE, we found that plasma membrane compartments generally exist in various cell types, including CHO, HEPA-OVA, PtK2, FRSK, HEK293, HeLa, T24 (ECV304), and NRK cells. The compartment size varies from 30 to 230 nm, whereas the average hop rate of DOPE crossing the boundaries between two adjacent compartments ranges between 1 and 17 ms. The probability of passing a compartment barrier when DOPE is already at the boundary is also cell-type dependent, with an overall variation by a factor of approximately 7. These results strongly indicate the necessity for the paradigm shift of the concept on the plasma membrane: from the two-dimensional fluid continuum model to the compartmentalized membrane model in which its constituent molecules undergo hop diffusion over the compartments.

Published

2004

18. Accumulation of anchored proteins forms membrane diffusion barriers during neuronal polarization.

Author

Nakada C, Ritchie K, Oba Y, Nakamura M, Hotta Y, Iino R, Kasai RS, Yamaguchi K, Fujiwara T, and Kusumi A

Subjects

Actin Cytoskeleton metabolism, Aging metabolism, Animals, Animals, Newborn, Axons ultrastructure, CHO Cells, Cell Differentiation physiology, Cricetinae, Dendrites ultrastructure, Diffusion, Hippocampus cytology, Hippocampus metabolism, Membrane Lipids metabolism, Phospholipids metabolism, Rats, Rats, Wistar, Axons metabolism, Cell Membrane metabolism, Cell Polarity physiology, Dendrites metabolism, Hippocampus growth & development, Membrane Proteins metabolism

Abstract

The formation and maintenance of polarized distributions of membrane proteins in the cell membrane are key to the function of polarized cells. In polarized neurons, various membrane proteins are localized to the somatodendritic domain or the axon. Neurons control polarized delivery of membrane proteins to each domain, and in addition, they must also block diffusional mixing of proteins between these domains. However, the presence of a diffusion barrier in the cell membrane of the axonal initial segment (IS), which separates these two domains, has been controversial: it is difficult to conceive barrier mechanisms by which an even diffusion of phospholipids could be blocked. Here, by observing the dynamics of individual phospholipid molecules in the plasma membrane of developing hippocampal neurons in culture, we found that their diffusion was blocked in the IS membrane. We also found that the diffusion barrier is formed in neurons 7-10 days after birth through the accumulation of various transmembrane proteins that are anchored to the dense actin-based membrane skeleton meshes being formed under the IS membrane. We conclude that various membrane proteins anchored to the dense membrane skeleton function as rows of pickets, which even stop the overall diffusion of phospholipids, and may represent a universal mechanism for formation of diffusion barriers in the cell membrane.

Published

2003

19. The fence and picket structure of the plasma membrane of live cells as revealed by single molecule techniques (Review).

Author

Ritchie K, Iino R, Fujiwara T, Murase K, and Kusumi A

Subjects

Animals, Cell Membrane metabolism, Diffusion, Humans, Membrane Lipids chemistry, Membrane Lipids metabolism, Membrane Proteins chemistry, Membrane Proteins metabolism, Cell Membrane chemistry, Models, Biological, Models, Structural, Molecular Biology methods

Abstract

Models of the organization of the plasma membrane of live cells as discovered through diffusion measurements of integral membrane molecules (transmembrane and GPI-anchored proteins, and lipid) at the single molecule level are discussed. Diffusion of transmembrane protein and, indeed, even lipid is anomalous in that the molecules tend to diffuse freely in limited size compartments, with infrequent intercompartment transitions. This average residency time in a compartment is dependent on the diffusing species and on its state of oligomerization, becoming completely confined to a single compartment upon sufficient oligomerization. This will be of great importance in determining cellular mechanisms for controlling the random diffusive motion of membrane molecules and in understanding signalling processes.

Published

2003

20. Phospholipids undergo hop diffusion in compartmentalized cell membrane.

Author

Fujiwara T, Ritchie K, Murakoshi H, Jacobson K, and Kusumi A

Subjects

Actins metabolism, Animals, Bridged Bicyclo Compounds, Heterocyclic pharmacology, Cell Compartmentation, Cell Line, Cell Membrane drug effects, Diffusion drug effects, Fibroblasts cytology, Fibroblasts metabolism, Gold Colloid metabolism, Kidney cytology, Marine Toxins pharmacology, Models, Biological, Peptides, Cyclic pharmacology, Phospholipids chemistry, Rats, Receptors, Transferrin metabolism, Thiazoles pharmacology, Thiazolidines, Time Factors, Trypsin pharmacology, Cell Membrane metabolism, Depsipeptides, Phospholipids metabolism

Abstract

The diffusion rate of lipids in the cell membrane is reduced by a factor of 5-100 from that in artificial bilayers. This slowing mechanism has puzzled cell biologists for the last 25 yr. Here we address this issue by studying the movement of unsaturated phospholipids in rat kidney fibroblasts at the single molecule level at the temporal resolution of 25 micros. The cell membrane was found to be compartmentalized: phospholipids are confined within 230-nm-diameter (phi) compartments for 11 ms on average before hopping to adjacent compartments. These 230-nm compartments exist within greater 750-nm-phi compartments where these phospholipids are confined for 0.33 s on average. The diffusion rate within 230-nm compartments is 5.4 microm2/s, which is nearly as fast as that in large unilamellar vesicles, indicating that the diffusion in the cell membrane is reduced not because diffusion per se is slow, but because the cell membrane is compartmentalized with regard to lateral diffusion of phospholipids. Such compartmentalization depends on the actin-based membrane skeleton, but not on the extracellular matrix, extracellular domains of membrane proteins, or cholesterol-enriched rafts. We propose that various transmembrane proteins anchored to the actin-based membrane skeleton meshwork act as rows of pickets that temporarily confine phospholipids.

Published

2002