Investigation by focused laser beam scanning of the photoelectric activity of bacteriorhodopsin-containing lipid bilayers.

The photoelectric activity of different parts of lipid bilayer containing bacteriorhodopsin was investigated by moving a small actinic light spot across the Plateau-Gibbs border and the bimolecular part of this reconstituted model membrane. The results give direct evidence that bacteriorhodopsin incorporated into the bimolecular region of the lipid membrane is responsible for the photoelectric activity of this system. A technique for scanning the photoelectric activity of a modified bimolecular lipid membrane is described in detail.     

The diffusion of glycine and N-substituted glycines across bimolecular lipid membranes

Free glycine was shown to diffuse very slowly across synthetic bimolecular lipid membranes, whereas several N-substituted derivatives of glycine were found to penetrate the membranes more readily. Pyridoxal, formaldehyde and acetaldehyde were shown to enhance the diffusion of glycine across the membranes, presumably the result of imine formation between the aldehyde and the α-amino group of glycine. Several N-substituted glycines were synthesized and their rates of efflux from liposomes were found to be related to their water-chloroform partition coefficients. This is the first demonstration of carrier-mediated diffusion of amino acids across bimolecular lipid membrane.     

The Nature of the Negative Resistance in Bimolecular Lipid Membranes Containing Excitability-Inducing Material

When sufficiently small amounts of excitability-inducing material (EIM) are added to a bimolecular lipid membrane, the conductance is limited to a few discrete levels and changes abruptly from one level to another. From our study of these fluctuations, we have concluded that the EIM-doped bilayer contains ion-conducting channels capable of undergoing transitions between two states of different conductance. The difference in current between the "open" and "closed" states is directly proportional to the applied membrane potential, and corresponds to a conductance of about 3 x 10^-10 ohm^-1. The fraction of the total number of channels that is open varies from unity to zero as a function of potential. The voltage-dependent opening and closing of channels explains the negative resistance observed for bimolecular lipid membranes treated with greater amounts of EIM.     

Problems and paradigms: Dynamic lipid-bilayer heterogeneity: A mesoscopic vehicle for membrane function?

The lipid-bilayer component of cell membranes is an aqueous bimolecular aggregate characterized by a heterogeneous lateral organization of its molecular constituents. The heterogeneity may be sustained statically as well as dynamically. On the basis of recent experimental and theoretical progress in the study of the physical properties of lipid-bilayer membranes, it is proposed that the dynamically heterogeneous membrane states are important for membrane functions such as transport of matter across the membrane and enzymatic activity. The heterogeneous membrane states undergo significant structural changes in response to changes in compositional, thermodynamic, and environmental conditions. The diverse effects of a variety of molecular compounds interacting with membranes, such as cholesterol and drugs like anaesthetics, may be understood in terms of the ability of these compounds to affect and modulate the dynamic membrane heterogeneity.     

Dependence of photosensitivity of bileaflet lipid membranes upon the chlorophyll and carotenoid content.

Bileaflet lipid membranes were formed from solutions containing lecithin, chlorophyll and carotene in various concentrations. If all the above components were present at sufficient concentrations the membranes were photosensitive; i.e., a photocurrent was produced if a redox potential gradient was present across the membranes. The presence of chlorophyll and carotene were essential for the photosensitivity of the membranes. Photoresponse could be elicited by illuminating the membrane with light which did not excite carotene. On the other hand, elimination of the part of the light spectrum which excites chlorophyll led to the abolition of the photoresponse. The findings of this study are consistent with the assumption that the excited chlorophyll chromophores allow electron exchange at the membrane-water interface while the presence of carotene allows electron movement across the "bulk" lipid membrane.     

Transport of Na+ by monensin across bimolecular lipid membranes

Transmembrane ²²Na fluxes across bimolecular lipid membranes are measured under two different experimental conditions: (a) the pH is the same in the two bulk aqueous solutions on either side of the membrane while the concentrations of Na⁺ are different; (b) the concentrations of Na⁺ are identical but pH of the two solutions are different. In this latter case, the transport of Na⁺ occurs in the opposite direction to the difference of the proton concentration. In both cases, the electrical charge flux is negligible. A transport model is proposed to account for the experimental data.     

The molecular organization of bimolecular lipid membranes. A study of the low frequency Maxwell-Wagner impedance dispersion

Theoretical considerations show that the presence of the polar group regions in bimolecular lipid membranes will produce a small (2–3%) dispersion of the bimolecular lipid membrane capacitance at low frequencies (0.1–100 Hz).A dispersion in conductance will also result. Calculations are given of the resolution of phase angle and impendance amplitude required to detect this dispersion and a new measuring technique is described which can achieve this. From the experimental result presented for lecithin bimolecular lipid membranes a determination was made of the individual capacitances and conductances of both the hydrocarbon and polar groups regions. The polar group conductance was found to vary from 700 μΩ^?1 · cm^?2 (in 1 mM KCl) to 2000 μΩ^?1 · cm^?2 (in 1 M KCl).The polar group capacitances were found to be approx.30 μF · cm^?2 and not systematically dependent on the concentration of the external electrolyte.     

Absence of kinetic barrier for transfer of protons from aqueous phase to membrane-water interface

The kinetics of interfacial proton transfer reaction is an important factor in proton transport across membranes. The following experimental system was designed in order to measure this kinetics. Sonicated liposomes having the protonophore SF6847 was suspended in Tris buffer. Application of a temperature jump (in ∼ 3 μs) caused a drop in the aqueous phase pH which was subsequently sensed by the membrane-bound SF6847. The kinetics of this interfacial proton transfer reaction was monitored on μs timescales. The estimated bimolecular rate constant of 2×10¹¹ M⁻¹ s_#x2212;1 for this process show that there is no kinetic barrier for the transfer of protons from the aqueous phase to the membrane-water interface.     

Structure of planar membrane formed from liposomes

Lipid vesicles with incorporated ion channels from polyene antibiotic amphotericin B were used to investigate structures of planar membranes formed by Shindler's techniques. A planar membrane assembled on the aperture in a lavsan film from two layers generated at the air-aqueous liposome suspension interface is not a simple bilayer but a bimolecular membrane containing numerous partly fused liposomes. A complete fusion of liposomal membranes with the planar bilayer is an unlikely event during membrane formation. A planar bimolecular lipid membrane without incorporated liposomes can be made by a method consisting of three stages: formation of a lipid layer on the air-water interface of a suspension containing liposomes, transfer of this layer along the surface of the solution into a chamber containing a solution without liposomes where a lipid monomolecular layer forms gradually (within about 20 min) at the air-water interface, assembling of the planar bilayer membrane from this monolayer. The knowledge of the planar membrane structure may be useful in experiments on incorporation of membrane proteins into a planar lipid bilayer.     

The stimulation of diffusion of adenine nucleotides across bimolecular lipid membranes by divalent metal ions

The diffusion rates of [³H] adenine nucleotides across bimolecular lipid membranes were shown to be directly related to their organic/water partition coefficients, the order being ATP > ADP > AMP. Nucleotide diffusion was stimulated by divalent metal ions with the order of stimulation being Cu⁺² ? Zn⁺² > Mg⁺². The ability of a divalent metal ion to stimulate diffusion appears to be related to its ability to bind to the N-7 of the adenine ring. The divalent metal ions increase adenine nucleotide diffusion both by complexing with the nucleotide thus decreasing the charge on the nucleotide and by increasing the permeability of the lipid bilayer.     

Electrolyte permeability and electromotive action of mosaic membranes composed of porous and liquid parts of high ionic selectivity for ions of opposite signs

Summary A theory is presented of the electromotive and ion permeability properties of membranes which consist of a mosaic of highly ion selectiveporous membrane areas of ion exchanger nature and of areas of highly ion selectiveliquid ion exchanger membranes, the two types of areas being exclusively permeable to ions of opposite sign. It is demonstrated that, with properly chosen membranes, the preferential permeability of such porous-liquid mosaic membranes for ions of one sign of charge will be the opposite of that apparently indicated by their electromotive action.The theory is based on the fact that the movement of ions across the porous membranes occurs in the dissociated state and in most instances is quantitatively linked to the resistance according to the Nernst-Einstein equation. The penetration of ions across liquid ion exchanger membranes, however, takes place essentially in a nondissociated state, and, as determined by self-exchange studies with radioactive tracers and stirred membranes, occurs at rates far in excess of those across porous membranes of the same resistance.For the theoretical treatment the simplest case, two-membrane macro-model concentration cells, is discussed in detail. Qualitatively, it is evident that the ratio of the permeability of anions and cations across such porous-liquid mosaic membranes ordinarily will be strongly in favor of the ions which penetrate across its liquid parts; contrariwise, the electromotive actions of the mosaic membranes ordinarily are dominated by its porous parts.Electric currents flow through all mosaic membranes; the strenghth of the current in a model cell may be calculated from the concentration potentials arising separately across the two membranes, and the resistances of the membranes and of the two solutions. From the strength of the current, the sign and the magnitude of the concentration potential arising in the model cell may be computed; in many instances it should closely approach the concentration potential across the porous membrane.For the test of this theory with two-membrane macro-mosaic models, the electrolyte of choice for experimental reasons was RbSCN, tagged with⁸⁶Rb⁺ and S¹⁴CN^–. The porous membranes were polystyrene sulfonic acid collodion matrix membranes; the liquid membranes consisted of 0.02m trioctyl propyl ammonium thiocyanate in 1-decanol. The ratios of the permeabilities across the model mosaic membranes determined by conventional rate of self-exchange measurements showed, as expected, that the permeability of the SCN^– ions is larger, up to 3600 times larger, than that of the Rb⁺ ions. The potentials arising in these models agreed within the limits of experimental error with those predicted by theory, closely approaching that arising at the cation selective porous membranes.     

Asymmetrical Lipid Bilayer Structure for Biological Membranes

IT is generally accepted that the matrix of cellular membranes is a bimolecular leaflet of phospholipid molecules in which the phospholipids are oriented so that their polar heads reside on the outer surfaces of the bilayer, in contact with the aqueous environment, the interior of the sandwich being composed of hydrophobic lipid chains^1–5. To this basic structure proteins cholesterol, glycolipids and other molecules are usually inserted in such a way as to confer on the bilayer the functional properties appropriate for the particular membrane.     

Effects of Light on the Membrane Potential of Protoplasts from Samanea saman Pulvini : Involvement of K Channels and the H -ATPase

Rhythmic light-sensitive movements of the leaflets of Samanea saman depend upon ion fluxes across the plasma membrane of extensor and flexor cells in opposing regions of the leaf-movement organ (pulvinus). We have isolated protoplasts from the extensor and flexor regions of S. saman pulvini and have examined the effects of brief 30-second exposures to white, blue, or red light on the relative membrane potential using the fluorescent dye, 3,3′-dipropylthiadicarbocyanine iodide. White and blue light induced transient membrane hyperpolarization of both extensor and flexor protoplasts; red light had no effect. Following white or blue light-induced hyperpolarization, the addition of 200 millimolar K⁺ resulted in a rapid depolarization of extensor, but not of flexor protoplasts. In contrast, addition of K⁺ following red light or in darkness resulted in a rapid depolarization of flexor, but not of extensor protoplasts. In both flexor and extensor protoplasts, depolarization was completely inhibited by tetraethylammonium, implicating channel-mediated movement of K⁺ ions. These results suggest that K⁺ channels are closed in extensor plasma membranes and open in flexor plasma membranes in darkness and that white and blue light, but not red light, close the channels in flexor plasma membranes and open them in extensor plasma membranes. Vanadate treatment inhibited hyperpolarization in response to blue or white light, but did not affect K⁺ -induced depolarization. This suggests that white or blue light-induced hyperpolarization results from activation of the H⁺ -ATPase, but this hyperpolarization is not the sole factor controlling the opening of K⁺ channels.     

Millisecond Delayed Light as an Indicator of Electrical Gradients across Chloroplast Thylakoids

DELAYED light emission from photosynthetic organisms was discovered by Strehler and Arnold¹. The emitted light has a spectrum similar to that of chlorophyll a fluorescence and can often persist for minutes after terminating the illumination. In recent years it has been found that the intensity of emission during the first few milliseconds of the decay is sensitive to the high energy state of the chloroplasts². Wraight and Crofts³ have suggested that this sensitivity is due to the establishment of electrical and pH gradients across the thylakoids during the illumination stage. The linking of the high energy state with these gradients is an essential feature of Mitchell's chemiosmotic hypothesis⁴. Wraight and Crofts³ have argued that the light-induced pH and electrical gradients act in such a way as to decrease the activation energy necessary to lift electrons from the metastable state, created during the preillumination, to the first singlet of chlorophyll. If this hypothesis is correct, the establishment of an electrical gradient across the thylakoid membranes by some means other than light-induced electron transport should change the intensity of millisecond delayed light emission. One possible way to create membrane potentials is to subject chloroplasts to salt gradients. The magnitude of the potentials developed will be a function of the concentration gradients and the relative rates of penetration of the ions across the thylakoid membranes^5,6.     

RECONSTITUTION OF A MEMBRANE-LIKE STRUCTURE WITH STRUCTURAL PROTEINS AND LIPIDS ISOLATED FROM TOBACCO THYLAKOID MEMBRANES

Structural proteins and lipids were extracted from thylakoid membranes and were dissolved separately with sodium dodecyl sulfate. Dissolved structural proteins reaggregated into spherical clumps, and lipids into globules composed of alternating light and dark bands, upon dialysis against dilute beta-buffer containing 20 mM Mg⁺⁺. The reaggregates of the mixture of structural proteins and lipids formed membranous structures. The appearance and thickness of the reconstituted membranes are similar to those of thylakoid membranes prepared from sonicated chloroplasts.     

The effect of S100 protein on the plasma membrane function of neurons

The protein S100 markedly increases the net intake of GABA across the plasma membranes of Deiters' neurons which have GABA receptors on their surfaces. This membrane function of S100 was found by using a new microtechnique. Plasma membranes of such cells have been freshly prepared by freehand microsurgery and are tightly fixed over a 30-µm ø hole between two compartments of a microchamber containing 2.0 mM GABA in 7.5 µl and 0.2 mM GABA in 75 µl, respectively. The transport of GABA has been determined after incubation of the membrane for from 30 sec to 10 min at 29°C. GABA is transported at a rate of 145 ng in 3 min over a 700-µm² membrane area. S100 in its calcium form reacts with the membrane and increases GABA transport by 20% which is ATP dependent and inhibited by ouabain and ruthenium red. The kinetics of the transport furthermore prove that GABA transport across the plasma membrane is an active process.     

Membrane adhesion in photosynthetic bacterial membranes. Light harvesting complex I (LHI) appears to be the main adhesion factor

We have reconstituted pigment-protein complexes isolated from Rhodopseudomonas palustris photosynthetic membranes into phospholipid liposomes. The various complexes were tested for their ability to promote adhesion of the liposome membrane in the presence and absence of Mg²⁺ ions. Samples containing a reaction center (RC)/light-harvesting I (LHI) complex appeared to stack in a manner resembling control thylakoids in 2 and 5 mM Mg²⁺. We also tested for the effects of Mg²⁺ on detergent extractablity of pigment-protein complexes from intact membranes. Mg²⁺ sharply reduced the amount of LHI solubilized from membranes, while having little effect on the extractability of the light harvesting II complex (LHII) and the RC. Based on these results we suggest that LHI is the principal adhesion factor of R. palustris thylakoids.Abbreviations LHC light harvesting complex - OG octyl glucoside - RC reaction center This paper is dedicated to Professor G. Drews on the occasion of his 60th birthday     

Isolation, partial chemical and biological characterization of thymone B

A new approach to the study of the molecular arrangements of proteins in membranes is described. Irradiation with visible light of native erythrocytes or washed erythrocyte membranes suspended in buffers containing a) riboflavin, fluorescein or fluorescein coupled to dextran and b) ³H-labelled tryptophan resulted in incorporation of radioactivity into the membrane proteins. Polyacrylamide gel electrophoresis of solubilized membranes followed by radioactivity measurements of the separated membrane proteins revealed that in native erythrocytes the protein components known to be located at the exterior cell surface, Band 3 and the major sialoglycoproteins became specifically labelled, whereas in washed lysed cells all of the major membrane proteins were labelled.     

Simultaneous measurements of optical and electrical properties of artificial membranes composed of mitochondrial lipids and their interaction with cytochromec

Summary A newly constructed cell, which allows simultaneous measurements of optical and electrical properties, was used to study bimolecular black membranes composed of beef heart mitochondrial lipids and their interaction with cytochromec.The results show that these highly charged membranes are stable only in relatively limited ranges of boundary conditions. In 0.1n KCl their maximum direct current (dc) resistance is 7×10⁸ Ohm cm²±10%; the series capacity at 1kHz is 0.43 F/cm²±3%; the entire thickness, determined by optical reflectivity, is 5.8±0.2 nm.The interaction between oxidized cytochromec and these lipid membranes is primarily of electrostatic nature, and dependent on the presence of highly charged phospholipids, such as diphosphatidyl glycerol (cardiolipin) and phosphatidyl ethanolamine. The attachment of cytochromec maximally causes a 2.5-fold increase in reflectivity, without any noticeable change in the capacity. This leads to a subsequent instability of the membrane (i.e., rupture) preceded by a rapid increase of the dc conductivity. This behavior is far less pronounced with reduced cytochromec.     

Influence of pentobarbital on synaptic plasma membrane protein synthesis

The effects of acute and chronic pentobarbital treatment on the incorporation of ³H-lysine into rat brain synaptic plasma membranes (SPM) were examined by means of SDS polyacrylamide gel electrophoresis. The data suggest the major effects of both drug treatments are found in a unique population of SPM derived from a light population of nerve ending particles (NEP). These light NEP preferentially accumulate labelled GABA, suggesting this fraction is enriched in GABA containing nerve terminals.