Effects of cyclosporin A on model lipid membranes

Cyclosporin A (CSA) is a widely used immunosuppressant drug for transplant therapy, however its limitation is its toxicity. The effect of CSA on model membranes such as dimyristoyl phosphatidylcholine (DMPC) bilayers was studied using small-angle X-ray diffraction and differential scanning calorimetry (DSC). CSA abolishes the pretransition and affects the transition of DMPC model membranes in a concentration-related manner as is shown by DSC. CSA induces a second peak at the high temperature side of the main transition, which is interpreted as a phase separation between areas rich and poor in CSA concentration. Small angle X-ray diffraction shows that the repeat distance of the DMPC bilayers in the lamellar Lalpha state increases as a function of concentration up to 10 mol% and remains constant thereafter. Furthermore, CSA affects the fatty acyl chains of the bilayer, especially the part of the chain proximal to the head group. In conclusion, CSA, as both small-angle X-ray diffraction and DSC show, affects in a concentration-wise manner the DMPC model membranes and perturbs the bilayer, in particular the acyl chain region.     

Structure of sarcoplasmic reticulum membranes at low resolution (17A)

Vesicles of fragmented sarcoplasmic reticulum membranes have been prepared and centrifuged into a multilayered form suitable for analysis by X-ray diffraction. X-ray diffraction has been recorded from a regular stacking of flattened vesicles in the presence of excess fluid. Discrete orders of a lamellar repeat distance ranging from 220 to 270 Å have been recorded. The diffraction data extend out to a minimum Bragg spacing of 33 Å. An electron density profile at a resolution of 17 Å has been derived using direct methods of structure analysis. The membrane has a bilayer construction (similar to nerve myelin and retina at low resolution) but the profile is markedly asymmetrical. The protein molecules are predominantly on the inside of the vesicle. A striking resemblance between the disc membranes in retina and the sarcoplasmic reticulum membranes has been noted and is described. X-ray diffraction has been recorded from the protein molecules in the surface of the sarcoplasmic reticulum membrane. The protein molecules are not in an ordered array but appear to have a liquid-like ordering. The observation that vesicles can be prepared in a suitable form for X-ray analysis has importance for membrane research for many different membranes form vesicles and it follows that these membranes can now be profitably studied by X-ray diffraction using a similar method.     

Molecular structure of fd (f1, M13) filamentous bacteriophage refined with respect to X-ray fibre diffraction and solid-state NMR data supports specific models of phage assembly at the bacterial membrane

Filamentous bacteriophage (Inovirus) is a simple and well-characterized model system. The phage particle, or virion, is about 60 angstroms in diameter and several thousand angstrom units long. The virions are assembled at the bacterial membrane as they extrude out of the host without killing it, an example of specific transport of nucleoprotein assemblages across membranes. The Ff group (fd, f1 and M13) has been especially widely studied. Models of virion assembly have been proposed based on a molecular model of the fd virion derived by X-ray fibre diffraction. A somewhat different model of the fd virion using solid-state NMR data has been proposed, not consistent with these models of assembly nor with the X-ray diffraction data. Here we show that reinterpreted NMR data are also consistent with the model derived from X-ray fibre diffraction studies, and discuss models of virion assembly.     

X-ray diffraction studies on photosystem I fragments from a blue-green alga, Anabaena variabilis, and spinach

Photosystem I fragments were prepared from thylakoid membranes of a blue-green alga (Anabaena variabilis) and spinach by treatment with a detergent, Triton X-100. Equatorial X-ray diffraction patterns were recorded on films for oriented specimens of thylakoid membranes and photosystem I fragments. The thylakoid membranes and photosystem I fragments gave essentially the same equatorial diffraction patterns in both Anabaena variabilis and spinach, indicating that the major X-ray scatterers in these thylakoid membranes are the molecular assembly of photosystem I. The equatorial X-ray diffraction from the photosystem I fragments of Anabaena variabilis and spinach extends to the reciprocal space of 1/7 A-1. The diffraction pattern exhibits six to nine distinct maxima though they are diffuse, indicating that the arrangement of the constituent molecules in photosystem I has a definite geometrical regularity. The radial autocorrelation functions indicate that the maximal sizes of photosystem I in these thylakoid membranes are about 100 A, and the geometrical regularity does not correspond to a crystalline order. The X-ray diffraction patterns from photosystem I fragments from Anabaena variabilis and spinach are quite similar to each other, suggesting the possibility that the molecular structures of photosystem I in Anabaena variabilis and spinach have a fundamental similarity. These diffraction patterns, however, are different from that of the chromatophore obtained from a photosynthetic bacterium, Rhodospirillum rubrum.     

On the structure of agglutinated sheep red blood cell membranes.

Specimens of isolated sheep red blood cell membranes are prepared by an agglutination technique in which membranes are stacked in regular arrays. X-ray diffraction patterns are recorded from such specimens which show meridional and equatorial diffraction phenomena. The meridional reflections correspond to single lamellar repeat periods of 160-186 A. It is concluded that two asymmetric membranes are contained in the elementary period. Lipid phases with preferentially oriented hydrocarbon chains are part of the membrane structure. The stacking of the membranes is also demonstrated in the electron microscope. The X-ray scattering curve of intracellular hemoglobin of intact sheep red blood cells is recorded to a spacing of about 8 A-1. The broad diffraction rings of this scattering curve are replaced by a series of rather sharp rings, when the red blood cells are agglutinated and placed in a hypertonic medium. Both the presence of a functioning membrane and the agglutination appear to be essential for the full expression of this phenomenon.     

On the structure of agglutinated sheep red blood cell membranes

Specimens of isolated sheep red blood cell membranes are prepared by an agglutination technique in which membranes are stacked in regular arrays. X-ray diffraction patterns are recorded from such specimens which show meridional and equatorial diffraction phenomena. The meridional reflections correspond to single lamellar repeat periods of 160–186 Å. It is concluded that two asymmetric membranes are contained inthe elementary period. Lipid phases with preferentialyl oriented hydrocarbon chains are part of the membrane structure. The stacking of membranes is also demonstrated in the electron microscope. The X-ray scattering curve of intracellular hemoglobin of intact sheep red blood cells is recorded to a spacing of about 8 Å^?1. The broad diffraction rings of this scattering curve are replaced by a series of rather sharp rings, when the red blood cells are agglutinated and placed in a hypertonic medium. Both the presence of a functioning membrane and the agglutination appear to be essential for the full expression of this phenomenon.     

Structure of Oriented Lipid Bilayers

X-ray diffraction studies show that lipid hydrocarbon chains are uniformly packed in bilayers and oriented so that their free ends are near the centre. This provides a model for biological membranes.     

Structure of the outer mitochondrial membrane analysis of x-ray diffraction from the plant membrane

X-ray diffraction from centrifugally oriented specimens of plant outer mitochondrial membranes suggests that these membranes contain prominent in-plane subunits. The short lamellar repeat which these specimens display (as low as 5.1 nm) points to a predominantly internal localization of the protein components of these membranes. The simplest model for the putative in-plane subunit consistent with autocorrelation analysis of the normal-incidence diffraction data consists of two concentric rings of electron density with diameters of (approx.) 2 and 4 nm. These rings could represent the planar projections of concentric cylindrical shells, aligned normal to the membrane surface.     

Squalane is in the midplane of the lipid bilayer: implications for its function as a proton permeability barrier

A recently proposed model for proton leakage across biological membranes [Prog. Lipid Res. 40 (2001) 299] suggested that hydrocarbons specifically in the center of the lipid bilayer inhibit proton leaks. Since cellular membranes maintain a proton electrochemical gradient as a principal energy transducer, proton leakage unproductively consumes cellular energy. Hydrocarbons in the bilayer are widespread in membranes that sustain such gradients. The alkaliphiles are unique in that they contain up to 40 mol% isoprenes in their membranes including 10-11 mol% squalene [J. Bacteriol. 168 (1986) 334]. Squalene is a polyisoprene hydrocarbon without polar groups. Localizing hydrocarbons in lipid bilayers has not been trivial. A myriad of physical methods including fluorescence spectroscopy, electron-spin resonance, nuclear magnetic resonance as well as X-ray and neutron diffraction have been used to explore this question with various degrees of success and often contradictory results. Seeking unambiguous evidence for the localization of squalene in membranes or lipid bilayers, we employed neutron diffraction. We incorporated 10 mol% perdeuterated or protonated squalane, an isosteric analogue of squalene, into stacked bilayers of dioleoyl phosphatidyl choline (DOPC) doped with dioleoyl phosphatidyl glycerol (DOPG) to simulate the negative charges found on natural membranes. The neutron diffraction data clearly show that the squalane lies predominantly in the bilayer center, parallel to the plane of the membrane.     

X-ray diffraction from oriented outer mitochondrial membranes. Detection of in-plane subunit structure.

X-ray diffraction patterns from ultracentrifugally oriented specimens of plant outer mitochondrial membranes show five distinct maxima in the equatorial direction. These diffraction maxima arise from in-plane subunits whose dimensions are consistent with those of the features ("pits") seen in electron micrographs of the membranes in negative stain.     

X-ray diffraction from oriented outer mitochondrial membranes: Detection of in-plane subunit structure

X-ray diffraction patterns from ultracentrifugally oriented specimens of plant outer mitochondrial membranes show five distinct maxima in the equatorial direction. These diffraction maxima arise from in-plane subunits whose dimensions are consistent with those of the features (“pits”) seen in electron micrographs of the membranes in negative stain.     

Paramagnetic spin label interactions with the envelope of a group A arbovirus. Lipid organization

Electron paramagnetic resonance observations were made on nitroxide spin-labeled molecules which were bound to the TC-83 vaccine strain of Venezuelan equine encephalomyelitis virus. Paramagnetic resonance parameters derived from the observations and their dependence on sample temperature were similar but not identical to those which have been reported for these labels dissolved in lipid bilayer membranes of mammalian and bacterial origin. The data are consistent with the existence of a bilayer lipid structure in the virion envelope which has a mechanical rigidity substantially greater than that of bilayers in cellular membranes. A model is presented which assumes the location of the lipid bilayer outside the nucleoprotein capsid and inside a spherical layer of envelope proteins. The model is in accord with Harrison's X-ray diffraction results for Sindbis virus. The model is discussed in terms of its implications with respect to the role played by lipid in viral maturation and infectivity.     

Structural and functional features of membranes with different cholesterol content

The paper deals with the present-day ideas of the structure and functions of membranes with different cholesterol content and relative sterols. The data on the molecular bases of lipids and sterols interaction in model systems, monolayers and liposomes, are obtained using 1H-, 13C-, 31P-NMR, EPR-investigations, methods of differential scanning calorimetry and X-ray diffraction. The methods for obtaining biomembranes with the different content of cholesterol and its effect on the membrane structure and functions are discussed. Reasons are analyzed of principal differences in behaviour of biomembranes with different content of cholesterol and respective model systems. The nature of cholesterol binding with phospholipids, proteins and its asymmetric distribution in biomembranes is considered. The cholesterol effect on the erythrocyte membrane charge density and possible changes in structural and functional properties of the membranes are demonstrated through the author's own experimental data. It is concluded that the cholesterol effect on structure and functions of the membranes is determined to a considerable extent by their phospholipid composition, localization and phase behaviour of phospholipids and sometimes depends on the membrane charge density.     

Low-angle x-ray diffraction of the erythrocyte membrane

Using low-angle X-ray diffraction technique it has been shown that preparing procedures can induce the phase separation in red blood cell membranes in the course of which proteins are removed from lipid bilayers. The latter form rather extensive regions and the diffraction pattern of asymmetric type changes to a symmetric one.     

Reconstitution of SNARE proteins into solid-supported lipid bilayer stacks and X-ray structure analysis

SNAREs are known as an important family of proteins mediating vesicle fusion. For various biophysical studies, they have been reconstituted into supported single bilayers via proteoliposome adsorption and rupture. In this study we extended this method to the reconstitution of SNAREs into supported multilamellar lipid membranes, i.e. oriented multibilayer stacks, as an ideal model system for X-ray structure analysis (X-ray reflectivity and diffraction). The reconstitution was implemented through a pathway of proteomicelle, proteoliposome and multibilayer. To monitor the structural evolution in each step, we used small-angle X-ray scattering for the proteomicelles and proteoliposomes, followed by X-ray reflectivity and grazing-incidence small-angle scattering for the multibilayers. Results show that SNAREs can be successfully reconstituted into supported multibilayers, with high enough orientational alignment for the application of surface sensitive X-ray characterizations. Based on this protocol, we then investigated the effect of SNAREs on the structure and phase diagram of the lipid membranes. Beyond this application, this reconstitution protocol could also be useful for X-ray analysis of many further membrane proteins.     

An X-ray study of the cytoplasmic membranes of two Gram-positive bacteria

X-ray diffraction diagrams of partially disordered one-dimensional lattices of isolated bacterial cytoplasmic membranes are described and they provide a basis for suggesting possible molecular structures of bacterial membranes.Biochemical and electron microscope evidence points towards a lipid bilayer with a high degree of fluidity. The protein molecules are in a disordered configuration in the membrane.     

Paramagnetic spin label interactions with the envelope of a group A arbovirus. Lipid organization.

Electron paramagnetic resonance observations were made on nitroxide spin- labeled molecules which were bound to the TC-83 vaccine strain of Venezuelan equine-encephalomyelitis virus. Paramagnetic resonance parameters derived from the observations and their dependence on sample temperature were similar but not identical to those which have been reported for these labels dissolved in lipid bilayer membranes of mammalian and bacterial origin. The data has a mechanical rigidity substantially greater than that of bilayers in cellular membranes. A model is presented which assumes the location of the lipid bilayer outside the nucleoprotein capsid and inside a spherical layer of envelope proteins. The model is in accord with Harrison's X-ray diffraction results for Sindbis virus. The model is discussed in terms of its implications with respects to the role played by lipid in viral maturation and infectivity.     

Structure of photosynthetic membranes of Euglena using X-ray diffraction

Novel X-ray diffraction results of membranes from chloroplasts of Euglena are presented, together with freeze-etch images obtained concurrently. Conditions were found for sharp lamellar reflections corresponding to ordered stacking of thylakoids. The periodicity measured by diffraction agrees well with that observed by microscopy. Intensities of diffraction were analysed in order to calculate the electron density distributions across the membranes. Some arguments in favour of the preferred phases of the reflection are given. The distributions indicate firstly the presence of 25 Å-wide regions where the hydrocarbon chains of the membrane lipids are concentrated. This result is discussed in terms of structural models for the chloroplast membrane. Comparison with results of freeze-etching indicates where in the density distribution are the regons inside and outside the membrane sacs. Secondly, the density distributions show maxima on the outside of the membranes only, corresponding possibly to an asymmetrical distribution of lipids.     

Location of terbium binding sites on acetylcholine receptor-enriched membranes

Acetylcholine receptor-enriched membranes bind 45 terbium cations per receptor. The Tb(III) X-ray scattering factor changes by as much as 30% over a 50 eV range about the L3 absorption edge. We exploit these changes to modulate the contribution of these ions to the X-ray diffraction pattern of oriented receptor-enriched membranes by varying the incident X-ray energy. Difference Fourier analysis of the meridional diffraction amplitudes at two X-ray energies revealed six localized regions of Tb(III) density across the membrane. Most significant is the finding of 18 Tb(III) ions near the entrance and 11 ions near the exit of the ion channel as well as 4 or 5 Tb(III) ions localized in the channel itself. This evidence strongly suggests the presence of anionic carboxylate side-chains on the channel lining.     

The swelling property of central nervous system nerves using x-ray diffraction.

Low-angle X-ray diffraction patterns have been recorded from cattle and rabbit optic nerves swollen in glycerol solutions. The new X-ray data have a resolution of about 15 to 16 Å. Analysis of the low-angle X-ray data indicates that the myelin layers of optic nerves swell in units of four membranes, that is, two membrane pairs adhere together during the process of swelling. Fourier syntheses of glycerol-treated cattle optic nerves are described. Differences in structure between the normal and swollen membrane pairs are apparent.