Your search keyword '"liquid-ordered"' showing total 9 results

1. Role of ceramide in membrane protein organization investigated by combined AFM and FCS

Author

Chiantia, Salvatore, Ries, Jonas, Chwastek, Grzegorz, Carrer, Dolores, Li, Zaiguo, Bittman, Robert, and Schwille, Petra

Subjects

*CERAMIDES, *MEMBRANE proteins, *CELL death, *SCANNING probe microscopy

Abstract

Abstract: Ceramide-induced alterations in the lateral organization of membrane proteins can be involved in several biological contexts, ranging from apoptosis to viral infections. In order to investigate such alterations in a simple model, we used a combined approach of atomic force microscopy, scanning fluorescence correlation spectroscopy and confocal fluorescence imaging to study the partitioning of different membrane components in sphingomyelin/dioleoyl-phosphatidylcholine/cholesterol/ceramide supported bilayers. Such model membranes exhibit coexistence of liquid-disordered, liquid-ordered (raft-like) and ceramide-rich lipid phases. Our results show that components with poor affinity toward the liquid-ordered phase, such as several fluorescent lipid analogues or the synaptic protein Synaptobrevin 2, are excluded from ceramide-rich domains. Conversely, we show for the first time that the raft-associated protein placental alkaline phosphatase (GPI-PLAP) and the ganglioside GM1 are enriched in such domains, while exhibiting a strong decrease in lateral diffusion. Analogue modulation of the local concentration and dynamics of membrane proteins/receptors by ceramide can be of crucial importance for the biological functions of cell membranes. [Copyright &y& Elsevier]

Published

2008

2. Seeing spots: Complex phase behavior in simple membranes

Author

Veatch, Sarah L. and Keller, Sarah L.

Subjects

*BILAYER lipid membranes, *CELL membranes, *MAGNETIC fields, *CHOLESTEROL

Abstract

Abstract: Liquid domains in model lipid bilayers are frequently studied as models of raft domains in cell plasma membranes. Micron-scale liquid domains are easily produced in vesicles composed of ternary mixtures of a high melting temperature lipid, a low melting temperature lipid, and cholesterol. Here, we describe the rich phase behavior observed in binary and ternary systems. We then discuss experimental challenges inherent in mapping phase diagrams of even simple lipid systems. For example, miscibility behavior varies with lipid type, lipid ratio, lipid oxidation, and level of impurity. Liquid domains are often circular, but can become noncircular when membranes are near critical points. Finally, we reflect on applications of phase diagrams in model systems to rafts in cell membranes. [Copyright &y& Elsevier]

Published

2005

3. Thermodynamics of membrane domains

Author

Almeida, Paulo F.F., Pokorny, Antje, and Hinderliter, Anne

Subjects

*GREEN fluorescent protein, *ISOPENTENOIDS, *LOW-cholesterol diet, *STEROLS

Abstract

Abstract: The concept of lipid rafts and the intense work toward their characterization in biological membranes has spurred a renewed interest in the understanding of domain formation, particularly in the case of cholesterol-containing membranes. The thermodynamic principles underlying formation of domains, rafts, or cholesterol/phospholipid complexes are reviewed here, along with recent work in model and biological membranes. A major motivation for this review was to present those concepts in a way appropriate for the broad readership that has been drawn to the field. Evidence from a number of different techniques points to the conclusion that lipid–lipid interactions are generally weak; therefore, in most cases, massive phase separations are not to be expected in membranes. On the contrary, small, dynamic lipid domains, possibly stabilized by proteins are the most likely outcome. The results on mixed lipid bilayers are used to discuss recent experiments in biological membranes. The clear indication is that proteins partition preferentially into fluid, disordered lipid domains, which is contrary to their localization in ordered, cholesterol/sphingomyelin rafts inferred from detergent extraction experiments on cell membranes. Globally, the evidence appears most consistent with a membrane model in which the majority of the lipid is in a liquid-ordered phase, with dispersed, small, liquid-disordered domains, where most proteins reside. Co-clustering of proteins and their concentration in some membrane areas may occur because of similar preferences for a particular domain but also because of simultaneous exclusion from other lipid phases. Specialized structures, such as caveolae, which contain high concentrations of cholesterol and caveolin are not necessarily similar to bulk liquid-ordered phase. [Copyright &y& Elsevier]

Published

2005

4. The molecular face of lipid rafts in model membranes

Author

Siewert J. Marrink, H. Jelger Risselada, Groningen Biomolecular Sciences and Biotechnology, Zernike Institute for Advanced Materials, Molecular Dynamics, and Faculty of Science and Engineering

Subjects

Models, Molecular, polyunsaturated, VESICLES, Cell membrane, Molecular dynamics, Membrane Microdomains, COARSE-GRAINED MODEL, Phase (matter), Monolayer, coarse-grained, medicine, Computer Simulation, FIELD, Lipid raft, Multidisciplinary, DOMAIN FORMATION, Chemistry, Vesicle, CHOLESTEROL, FLUORESCENCE MICROSCOPY, liquid-ordered, PHASE-FORMATION, Raft, Biological Sciences, molecular dynamics, NMR, Crystallography, Membrane, medicine.anatomical_structure, Chemical physics, SIMULATION, MIXED BILAYERS

Abstract

Cell membranes contain a large number of different lipid species. Such a multicomponent mixture exhibits a complex phase behavior with regions of structural and compositional heterogeneity. Especially domains formed in ternary mixtures, composed of saturated and unsaturated lipids together with cholesterol, have received a lot of attention as they may resemble raft formation in real cells. Here we apply a simulation model to assess the molecular nature of these domains at the nanoscale, information that has thus far eluded experimental determination. We are able to show the spontaneous separation of a saturated phosphatidylcholine (PC)/unsaturated PC/cholesterol mixture into a liquid-ordered and a liquid-disordered phase with structural and dynamic properties closely matching experimental data. The near-atomic resolution of the simulations reveals remarkable features of both domains and the boundary domain interface. Furthermore, we predict the existence of a small surface tension between the monolayer leaflets that drives registration of the domains. At the level of molecular detail, raft-like lipid mixtures show a surprising face with possible implications for many cell membrane processes.

Published

2008

5. Role of ceramide in membrane protein organization investigated by combined AFM and FCS

Author

Robert Bittman, Salvatore Chiantia, Zaiguo Li, Jonas Ries, Grzegorz Chwastek, Dolores C. Carrer, and Petra Schwille

Subjects

Ceramide, Glycosylphosphatidylinositols, Biophysics, Fluorescence correlation spectroscopy, Ceramides, Microscopy, Atomic Force, Biochemistry, Diffusion, Atomic force microscopy, chemistry.chemical_compound, Phosphatidylcholine, Liquid-ordered, Membrane fluidity, Raft, GPI anchor, Peripheral membrane protein, Membrane Proteins, Cell Biology, Alkaline Phosphatase, Cell biology, Membrane, Spectrometry, Fluorescence, chemistry, Membrane protein, lipids (amino acids, peptides, and proteins), Fluorescence correlations spectroscopy, Sphingomyelin

Abstract

Ceramide-induced alterations in the lateral organization of membrane proteins can be involved in several biological contexts, ranging from apoptosis to viral infections. In order to investigate such alterations in a simple model, we used a combined approach of atomic force microscopy, scanning fluorescence correlation spectroscopy and confocal fluorescence imaging to study the partitioning of different membrane components in sphingomyelin/dioleoyl-phosphatidylcholine/cholesterol/ceramide supported bilayers. Such model membranes exhibit coexistence of liquid-disordered, liquid-ordered (raft-like) and ceramide-rich lipid phases. Our results show that components with poor affinity toward the liquid-ordered phase, such as several fluorescent lipid analogues or the synaptic protein Synaptobrevin 2, are excluded from ceramide-rich domains. Conversely, we show for the first time that the raft-associated protein placental alkaline phosphatase (GPI-PLAP) and the ganglioside GM1 are enriched in such domains, while exhibiting a strong decrease in lateral diffusion. Analogue modulation of the local concentration and dynamics of membrane proteins/receptors by ceramide can be of crucial importance for the biological functions of cell membranes.

Published

2008

6. Lipid rafts and membrane traffic

Author

Michael Hanzal-Bayer and John F. Hancock

Subjects

Biophysics, Biology, Biochemistry, Exocytosis, Rafts, Membrane Microdomains, Structural Biology, Cell Movement, Liquid-ordered, Genetics, Molecular Biology, Lipid raft, Membrane microstructure, Cell Membrane, Cell Biology, Raft, Compartmentalization (psychology), Endocytosis, Cell biology, Pleckstrin homology domain, Transmembrane domain, Protein Transport, Membrane, Förster resonance energy transfer, Signalling, Cholesterol-facilitated, lipids (amino acids, peptides, and proteins)

Abstract

Membrane rafts are regions of increased lipid acyl chain order that differ in their lipid and protein composition from the surrounding membrane. By providing an additional level of compartmentalization they have been proposed to serve many functions in cellular signal transduction and trafficking. We will review their potential involvement in different forms of membrane traffic, explicitly excluding signalling, and discuss select aspects of the raft hypothesis in its current form.

Published

2007

7. Thermodynamics of membrane domains

Author

Paulo F. Almeida, Antje Pokorny, and Anne Hinderliter

Subjects

Liquid ordered phase, Membrane lipids, Peripheral membrane protein, Lipid microdomain, Lipid Bilayers, Biophysics, Phase separation, Protein–lipid interaction, Biological membrane, Cell Biology, Biology, Biochemistry, Cell biology, Membrane Lipids, Membrane Microdomains, Liquid-ordered, Thermodynamics, lipids (amino acids, peptides, and proteins), Lipid bilayer phase behavior, Cholesterol complex, Lipid bilayer, Raft, Lipid–lipid interaction, Elasticity of cell membranes

Abstract

The concept of lipid rafts and the intense work toward their characterization in biological membranes has spurred a renewed interest in the understanding of domain formation, particularly in the case of cholesterol-containing membranes. The thermodynamic principles underlying formation of domains, rafts, or cholesterol/phospholipid complexes are reviewed here, along with recent work in model and biological membranes. A major motivation for this review was to present those concepts in a way appropriate for the broad readership that has been drawn to the field. Evidence from a number of different techniques points to the conclusion that lipid–lipid interactions are generally weak; therefore, in most cases, massive phase separations are not to be expected in membranes. On the contrary, small, dynamic lipid domains, possibly stabilized by proteins are the most likely outcome. The results on mixed lipid bilayers are used to discuss recent experiments in biological membranes. The clear indication is that proteins partition preferentially into fluid, disordered lipid domains, which is contrary to their localization in ordered, cholesterol/sphingomyelin rafts inferred from detergent extraction experiments on cell membranes. Globally, the evidence appears most consistent with a membrane model in which the majority of the lipid is in a liquid-ordered phase, with dispersed, small, liquid-disordered domains, where most proteins reside. Co-clustering of proteins and their concentration in some membrane areas may occur because of similar preferences for a particular domain but also because of simultaneous exclusion from other lipid phases. Specialized structures, such as caveolae, which contain high concentrations of cholesterol and caveolin are not necessarily similar to bulk liquid-ordered phase.

Published

2005

8. Wide angle x-ray scattering probes chain order and identifies liquid-liquid phase coexistence in oriented lipid membranes

Author

Mills, Thalia Tilden

Subjects

x-ray scattering, oriented lipid membrane, raft, model membrane, phase coexistence, chain-chain correlation, order parameter, liquid-ordered

Abstract

We have used grazing incidence wide-angle x-ray scattering (GIWAXS) on oriented lipid multilayers to measure chain order and to examine liquid-liquid coexistence in the system DOPC/DPPC/cholesterol, a model for the outer leaflet of the cell plasma membrane. Coexistence of liquid-disordered (Ld) and liquid-ordered (Lo) domains is thought to be related to "rafts" in the cell membrane, cholesterol-rich lipid heterogeneities which provide platforms for protein sorting. Many of the methods used for measuring liquid-liquid coexistence in model membranes require a potentially perturbing probe, while x-ray scattering is probe-free. In unoriented (powder) x-ray data, scattering from the Ld and Lo phases looks very similar, whereas in GIWAXS patterns from oriented samples, these phases are easily distinguishable because of the differences in their chain orientational order. By using a simple analytical model to relate the GIWAXS data to the chain orientational distribution, we fit our data to obtain the average chain orientational order parameter, Smol. While this type of analysis has been well-used for liquid crystals, it is not commonly applied to model membrane systems. For DOPC/cholesterol and DPPC/cholesterol mixtures, composition and temperature dependent trends in Smol determined by GIWAXS are consistent with earlier NMR data. Addition of 40% cholesterol to liquid-phase DPPC or DOPC more than doubles Smol. In addition to measuring chain orientational order parameters for binary mixtures of DOPC/cholesterol and DPPC/cholesterol, we have measured GIWAXS for ternary mixtures where fluorescence microscopy and NMR indicate the coexistence of Ld and Lo phases below the miscibility transition temperature, Tmix. In order to fit to the GIWAXS data for these mixtures at low temperature, we required two values of Smol, which we interpret as evidence of coexisting Ld and Lo phases. Our Tmix values based on x-ray work agree reasonably (to within the 5-10 C temperature steps used) with the Tmix values based on the NMR and microscopy work of Veatch et al. (Veatch and Keller, 2003b; Veatch et al., 2004; Veatch et al., 2007b). This approach provides a new method for examining phase coexistence in model membranes without the need to add a potentially perturbing probe.

Published

2007

9. Seeing spots: Complex phase behavior in simple membranes

Author

Sarah L. Keller and Sarah L. Veatch

Subjects

Liquid ordered phase, Membrane Fluidity, Lipid Bilayers, Analytical chemistry, 010402 general chemistry, 01 natural sciences, Phase Transition, 03 medical and health sciences, Membrane Microdomains, Lipid oxidation, Phase (matter), Liquid-ordered, Membrane fluidity, Lipid bilayer phase behavior, Lipid bilayer, Molecular Biology, Raft, 030304 developmental biology, 0303 health sciences, Gel, Chemistry, Lipid microdomain, Cell Membrane, Miscibility, Cell Biology, Lipid, Lipids, 0104 chemical sciences, Phase diagram, Membrane, Cholesterol, Chemical physics, lipids (amino acids, peptides, and proteins)

Abstract

Liquid domains in model lipid bilayers are frequently studied as models of raft domains in cell plasma membranes. Micron-scale liquid domains are easily produced in vesicles composed of ternary mixtures of a high melting temperature lipid, a low melting temperature lipid, and cholesterol. Here, we describe the rich phase behavior observed in binary and ternary systems. We then discuss experimental challenges inherent in mapping phase diagrams of even simple lipid systems. For example, miscibility behavior varies with lipid type, lipid ratio, lipid oxidation, and level of impurity. Liquid domains are often circular, but can become noncircular when membranes are near critical points. Finally, we reflect on applications of phase diagrams in model systems to rafts in cell membranes.