Electrophoretic mobility of bimolecular lipid membranes

The floating membrane vesicle is fixed by the counter solution flow in different points along the radius of a cylinder electrophoretic chamber, which permits to measure the vesicle electrophoretic mobility (EM). Close state condition of the chamber is provided for by the capillary system successively connected with the chamber. Relationship between EM of bimolecular lipid membranes (BLM) and pH and ionic concentration of aqueous solution qualitatively coincides with similar relationship for liposomes. The EM value of BLM essentially decreases in solution containing polyene antibiotics nystatine and levorin when derivative of cholesterol having 3betaOH-groups is present in the membrane.     

Conformation and stability of the anion transport protein of human erythrocyte membranes

The conformation and stability of purified preparations of band 3, the anion transport protein of human erythrocyte membranes, and its constituent proteolytic subfragments have been studied by circular dichroism. Band 3, purified in the presence of the nonionic detergent n-dodecyl octaethylene glycol monoether (C12E8), had an alpha-helical content of 46%. Denaturation of purified band 3 with guanidine hydrochloride occurred in two phases, one reflecting much more resistance to denaturation than the other. Band 3 can be separated into two domains by limited in situ proteolytic cleavage. The carboxyl-terminal membrane-associated domain (Mr 55 000) purified in C12E8 contained 58% alpha-helix and was very resistant to denaturation by guanidine hydrochloride. The purified amino-terminal, cytoplasmic domain (Mr 41 000) contained 27% alpha-helix and was completely converted to a random-coil conformation by 3 M guanidine hydrochloride. The two phases of denaturation observed for intact band 3 corresponded to the two domains of the protein. Irreversible heat denaturation of purified band 3 occurred with half-maximal change in theta 222.5 at 48 degrees C. Covalent attachment of the anion transport inhibitor 4,4'-diisothiocyanostilbene-2,2'-disulfonate to band 3 had little effect on the circular dichroism spectra of band 3 or the membrane-associated domain but resulted in stabilization of band 3 to heat denaturation (half-maximal change in theta 222.5 = 61 degrees C). Circular dichroism studies of membranes that had been digested extensively with proteolytic enzymes and stripped of all extrinsic fragments revealed that the portions of red cell membrane proteins that are embedded in the lipid bilayer contain a very high (86-94%) content of alpha-helix.     

Rotational decoupling between the hydrophilic and hydrophobic regions in lipid membranes

Cells use homeostatic mechanisms to ensure an optimal composition of distinct types of lipids in cellular membranes. The hydrophilic region of biological lipid membranes is mainly composed of several types of phospholipid headgroups that interact with incoming molecules, nanoparticles, and viruses, whereas the hydrophobic region consists of a distribution of acyl chains and sterols affecting membrane fluidity/rigidity related properties and forming an environment for membrane-bound molecules such as transmembrane proteins. A fundamental open question is to what extent the motions of these regions are coupled and, consequently, how strongly the interactions of phospholipid headgroups with other molecules depend on the properties and composition of the membrane hydrophobic core. We combine advanced solid-state nuclear magnetic resonance spectroscopy with high-fidelity molecular dynamics simulations to demonstrate how the rotational dynamics of choline headgroups remain nearly unchanged (slightly faster) with incorporation of cholesterol into a phospholipid membrane, contrasting the well-known extreme slowdown of the other phospholipid segments. Notably, our results suggest a new paradigm in which phospholipid dipole headgroups interact as quasi-freely rotating flexible dipoles at the interface, independent of the properties in the hydrophobic region.     

Molecular transport and organization in supported lipid membranes

The mechanism by which vesicles spontaneously form supported lipid bilayer membranes on glass surfaces is becoming better understood and this knowledge is the basis of a technology of patterning membrane arrays and controlling composition. Controlled interactions between supported membranes and cells, particularly from the immune system, provide direct insight into cell-cell surface interactions.     

Arabidopsis chloroplast lipid transport protein TGD2 disrupts membranes and is part of a large complex

In most plants the assembly of the photosynthetic thylakoid membrane requires lipid precursors synthesized at the endoplasmic reticulum (ER). Thus, the transport of lipids from the ER to the chloroplast is essential for biogenesis of the thylakoids. TGD2 is one of four proteins in Arabidopsis required for lipid import into the chloroplast, and was found to bind phosphatidic acid in vitro. However, the significance of phosphatidic acid binding for the function of TGD2 in vivo and TGD2 interaction with membranes remained unclear. Developing three functional assays probing how TGD2 affects lipid bilayers in vitro, we show that it perturbs membranes to the point of fusion, causes liposome leakage and redistributes lipids in the bilayer. By identifying and characterizing five new mutant alleles, we demonstrate that these functions are impaired in specific mutants with lipid phenotypes in vivo. At the structural level, we show that TGD2 is part of a protein complex larger than 500 kDa, the formation of which is disrupted in two mutant alleles, indicative of the biological relevance of this TGD2-containing complex. Based on the data presented, we propose that TGD2, as part of a larger complex, forms a lipid transport conduit between the inner and outer chloroplast envelope membranes, with its N terminus anchored in the inner membrane and its C terminus binding phosphatidic acid in the outer membrane.     

Ionic transport in lipid bilayer membranes.

The current-voltage relationships of model bilayer membranes have been measured in various phospholipid systems, under the influence of both a gradient of potential and an ionic concentration, in order to describe the ion translocation through hydrated transient defects (water channels) across the bilayer formed because of lipid structure fluctuations and induced by temperature. The results have been analyzed in the light of a statistical rate theory for the transport process across a lipid bilayer, recently proposed by Skinner et al. (1993). In order to take into account the observed I-V curves and in particular the deviation from an ohmic behavior observed at high potential values, the original model has been modified, and a new version has been proposed by introducing an additional kinetic process. In this way, a very good agreement with the experimental values has been obtained for all of the systems we have investigated (dimyristoylphosphatidyl ethanolamine bilayers and mixed systems composed by dimyristoylphosphatidyl ethanolamine/dimyristoylphosphatidylcholine mixtures and dimyristoylphosphatidyl ethanolamine/phosphatidic acid dipalmitoyl mixtures). The rate constants governing the reactions at the bilayer interfaces have been evaluated for K+ and Cl- ions, as a function of temperature, from 5 to 35 degrees C and bulk ionic concentrations from 0.02 to 0.2 M. Finally, a comparison between the original model of Skinner and the modified version is presented, and the advantages of this new formulation are briefly discussed.     

Differential stiffness and lipid mobility in the leaflets of purple membranes

Purple membranes (PM) are two-dimensional crystals formed by bacteriorhodopsin and a variety of lipids. The lipid composition and density in the cytoplasmic (CP) leaflet differ from those of the extracellular (EC) leaflet. A new way of differentiating the two sides of such asymmetric membranes using the phase signal in alternate contact atomic force microscopy is presented. This method does not require molecular resolution and is applied to study the stiffness and intertrimer lipid mobility in both leaflets of the PM independently over a broad range of pH and salt concentrations. PM stiffens with increasing salt concentration according to two different regimes. At low salt concentration, the membrane Young's normal modulus grows quickly but differentially for the EC and CP leaflets. At higher salt concentration, both leaflets behave similarly and their stiffness converges toward the native environment value. Changes in pH do not affect PM stiffness; however, the crystal assembly is less pronounced at pH > or = 10. Lipid mobility is high in the CP leaflet, especially at low salt concentration, but negligible in the EC leaflet regardless of pH or salt concentration. An independent lipid mobility study by solid-state NMR confirms and quantifies the atomic force microscopy qualitative observations.     

Molecular dynamics simulation of lipid packing and mobility in bilayer membranes

A model of lipid bilayer membrane in water has been developed. Parameters have been selected that allow molecular dynamics simulation of lipid bilayers in the all-atom approximation. The calculated indices of packing and mobility of lipid molecules for the liquid crystalline state of the bilayer agree well with the experimental data. Based on the model of the liquid crystalline state of the membrane, a system in the gel-like state has been constructed. The gel-state model reproduces well the packing of lipids in real bilayers, whereas the mobility of molecules proves to be overestimated.     

Localization and mobility of coenzyme Q in lipid bilayers and membranes.

We have studied the mobility of coenzyme Q (CoQ) in lipid bilayers and mitochondrial membranes in relation to the control of electron transfer activities. A molecular dynamics computer simulation in the vacuum yielded a folded structure for CoQ10, with a length of only 21 A. Using this information we were able to calculate diffusion coefficients in the range of 10(-6) cm2/s in good agreement with those found experimentally by fluorescence quenching of pyrene derivatives. To investigate if CoQ diffusion may represent the rate-limiting step of electron transfer, we reconstituted complexes I and III and assayed the resulting NADH-cytochrome c reductase activity in presence of different CoQ10 levels and at different distances between complexes; the experimental turnovers were higher than the collision frequencies calculated using diffusion coefficients of 10(-9) cm2/s but compatible with values found by us by fluorescence quenching. Since the experimental turnovers are independent of the distance between complexes, we conclude that CoQ diffusion is not rate-limiting for electron transfer.     

A relationship between diffusional transport in lipid membranes and a lipophilic-eutectic parameter

A theoretical model has been developed to relate passive diffusional transport with a parameter termed the lipophilic-eutectic coefficient, Le. Based on this parameter it is proposed that the lipophilicity of a substance can be estimated. The method is based on the melting point lowering of a pure substance in the presence of an impurity of similar structure. Cholesterol was chosen as a model biological lipid because it is a neutral lipid that is found in relatively high concentrations in a variety of membranes. Transdermal absorption in humans and intestinal absorption in the rat both show a high degree of correlation with respect to Le. For our studies, Le appears to be as satisfactory as the partition coefficient for estimating lipophilicity and its determination is less demanding analytically.     

Microviscosity parameters and protein mobility in biological membranes.

A fluorescence polarization technique with 1,6-diphenyl 1,3,5-hexatriene as a probe were employed to determine the microviscosity, n, in liposomes and biological membranes of different cholesterol to phospholipid mol ratio. From the temperature profile of n the flow activation energy, deltaE, and the unit flow volume, V, were derived. The increase of cholesterol/phospholipid ratio in liposomes is followed by a marked increase in n and a decrease in both deltaE and V. Liposomes of the same phospholipid composition as human erythrocyte membranes display in the extreme cases of cholesterol/phospholipid ratios 0 and 1.4 the values of n(25 degrees C) = 1.8 and 9.1 P, and deltaE = 15.0 and 6.5 kcal/mol, respectively. For most membranes studied the fluorescence polarization characteristics and the corresponding n values are similar to those obtained with these liposomes when the cholesterol/phospholipid level of the liposomes and the membranes were the same. However, unlike in liposomes deltaE of all membranes is in the narrow range of 6.5-8.5 kcal/mol, regardless of its cholesterol/phospholipid level. It is plausible that this is a general characteristic of biological membranes which originates from the vertical movement of membrane proteins to an equilibrium position which maintains constant deltaE and V values. This type of movement should affect the interrelation between lipid fluidity and protein mobility. Lipid microviscosity and the degree of rotational mobility of concanavalin A receptor sites in cell membranes were therefore determined. The examined cells were normal and malignant fibroblasts, as an example of cells that form solid tumours in vivo, and normal and malignant lymphocytes, as an example of cells that form ascites tumours in vivo. In both cell systems, opposite correlations between the lipid fluidity and the mobility of concanavalin A receptors were observed. In the fibroblasts the malignant cells possess a lower lipid fluidity but a higher receptor mobility, whereas in the lymphocytes the malignant cells possess a higher lipid fluidity but a lower receptor mobility. Thus, in these cell systems the degree of rotational mobility of concanavalin A receptors increases upon decreasing the lipid fluidity and decreases upon increasing the fluidity of the lipid core. This dynamic feature is in line with the above proposal according to which the concanavalin A receptor sites become more exposed to the aqueous surrounding upon increasing the microviscosity of the lipid layer and vice versa.     

Changes in lipid mobility associated with alamethicin incorporation into membranes

The binding state of the antibiotic peptide alamethicin with phospholipid bilayers was investigated in terms of the changes induced in lipid mobility. Fluorescence anisotropy was used for the study. It was found that an increase in peptide concentration induced different changes in lipid mobility above and below a critical peptide concentration. This concentration was also critical for an increase in the cooperative binding of the peptide, as detected by circular dichroism. Above the critical peptide concentration, the mobility of both lipid regions, around the polar head and hydrocarbon chain, became restricted with an increased peptide concentration. Below the critical level, however, an increased peptide concentration induced a "wobbling" of the lipid hydrocarbon chain. These results show that an increase in the cooperative binding of the peptide is accompanied by a change in the dominant configuration of the binding peptide. When the binding peptide increases, the dominant configuration appears to shift from surface association to deep incorporation within the membrane. This shift in configuration means that in the formation of ion-conductive pores, voltage-driven insertion of the peptide is a prominent step below a critical peptide concentration.     

Hydrophobic mismatch is a key factor in protein transport across lipid bilayer membranes via the Tat pathway

The twin-arginine translocation (Tat) pathway transports folded proteins across membranes in bacteria, thylakoids, plant mitochondria, and archaea. In most species, the active Tat machinery consists of three independent subunits: TatA, TatB, and TatC. TatA and TatB possess short transmembrane alpha helices (TMHs), both of which are only 15 residues long in Escherichia coli. Such short TMHs cause a hydrophobic mismatch between Tat subunits and the membrane bilayer, although the functional significance of this mismatch is unclear. Here, we sought to address the functional importance of the hydrophobic mismatch in the Tat transport mechanism in E. coli. We conducted three different assays to evaluate the effect of TMH length mutants on Tat activity and observed that the TMHs of TatA and TatB appear to be evolutionarily tuned to 15 amino acids, with activity dropping off following any modification of this length. Surprisingly, TatA and TatB with as few as 11 residues in their TMHs can still insert into the membrane bilayer, albeit with a decline in membrane integrity. These findings support a model of Tat transport utilizing localized toroidal pores that form when the membrane bilayer is thinned to a critical threshold. In this context, we conclude that the 15-residue length of the TatA and TatB TMHs can be seen as a compromise between the need for some hydrophobic mismatch to allow the membrane to reversibly reach the threshold thinness required for toroidal pore formation and the permanently destabilizing effect of placing even shorter helices into these energy-transducing membranes.     

Rotational mobility of the photoreaction center in chromatophore membranes of Rhodospirillum rubrum

We investigated the rotational mobility of the photoreaction center in chromatophores of Rhodospirillum rubrum by studying the photoinduced linear dichroism of absorption changes at 865 nm. The study was carried out in suspensions of chromatophores treated with ferricyanide in order to bleach their antenna bacteriochlorophyll and thus minimize depolarization by energy transfer. Very little depolarization of the photoinduced absorbance change at 865 nm was observed at room temperature for chromatophores immersed in a highly viscous medium over the time range 0–10 ms following an exciting light flash. In the light of independent evidence for transmembrane arrangement of the photoreaction center, we conclude that the photoreaction center protein is immobilized in the chromatophore membrane for at least 10 ms.     

Rotational dynamics of protein and boundary lipid in sarcoplasmic reticulum membrane

We have used spin labels and electron paramagnetic resonance (EPR) to study the correlation between the rotational dynamics of protein and lipid in sarcoplasmic reticulum (SR) membranes. A short-chain maleimide spin label was used to monitor the submillisecond rotational mobility of the Ca-ATPase enzyme (using saturation transfer EPR); a free fatty acid spin label was used to monitor the submicrosecond rotational mobility of the bulk lipid hydrocarbon chains (using conventional EPR); and a fatty acid spin label derivative (long-chain maleimide) attached to the enzyme was used to monitor the mobility of hydrocarbon chains adjacent to the protein (i.e., boundary lipid). In the native SR membranes, the protein was highly mobile (effective correlation time 50 microseconds). The spectra of the hydrocarbon probes both contained at least two components. For the unattached probe, the major component indicated nearly as much mobility as in the absence of protein (effective rotational correlation time 3 ns), while a minor component, corresponding to 25-30% of the total signal, indicated strong immobilization (effective correlation time greater than or equal to 10 ns). For the attached hydrocarbon probe, the major component (approximately 70% of the total) was strongly immobilized, and the mobile component was less mobile than that of the unattached probe. When the lipid-to-protein ratio was reduced 55% by treatment with deoxycholate, protein mobility decreased considerably, suggesting protein aggregation. A concomitant increase was observed in the fraction of immobilized spin labels for both the free and attached hydrocarbon probes. The observed hydrocarbon immobilization probably arises in part from immobilization at the protein-lipid boundary, but protein-protein interactions that trap hydrocarbon chains may also contribute. When protein aggregation was induced by glutaraldehyde crosslinking, submillisecond protein mobility was eliminated, but there was no effect on either hydrocarbon probe. Thus protein aggregation does not necessarily cause hydrocarbon chain immobilization.     

Regulation of protein mobility in cell membranes: a dynamic corral model

We analyze a two-state stochastic corral model for regulation of protein diffusion in a cell membrane. This model could mimic control of protein transport in the membrane by the cytoskeleton. The dynamic corral acts as a gate which when open permits an otherwise trapped protein to escape to a neighboring corral in the cytoskeletal network. We solve for the escape rate over a wide range of parameters of the model, and compare these results with Monte Carlo simulations. Upon introducing measured values of the model parameters for Band 3 in erythrocyte membranes, we are able to estimate the value for one unknown parameter, the average rate at which the corral closes. The ratio of calculated closing rate to measured opening rate is roughly 100:1, consistent with a gating mechanism whereby protein mobility is regulated by dissociation and reassociation of segments of the cytoskeletal network.