Surface dipoles,surface charges and negative steady-state resistance in biological membranes

A theoretical expression for the steady-state current-voltage characteristic of biological membranes is given, justifying various assumptions which are usually made in the framework of the electrodiffusion theory, and taking into account the effect of surface charges and surface dipoles. It is shown that the orientation of the dipoles can be treated by a two-state model. But a comparison with the experimental curves of Gilbert and Ehrenstein leads to the conclusion that the observed negative resistances cannot be explained by a reorientation of the dipoles alone. An additional modification of the surface charges could be sufficient. Some features can be well explained by an absorption of divalent cations on the “outside” surface.     

Surface dielectric constant,surface hydrophobicity and membrane fusion

Summary Membrane fusion induced by ions and its associated membrane property, surface dielectric constant, were studied with the use of acidic and neutral phospholipid vesicles. The fusion of vesicles was monitored by utilizing two fluorescence fusion assays: fluorescence content mixing method and fluorescence labelled membrane component dilution method. For the surface dielectric constant measurements, a fluorescence method was used which detected the environmental effect on the membrane surface upon the addition of various fusogenic cations. Also, the effects of poly-(ethylene glycol) on both fusion and surface dielectric properties were examined. It was found that the extent of fusion correlated well with the degree of lowering in the dielectric constant of the surface membrane, which corresponds to the increase in hydrophobicity of the membrane surface. This agrees with the previously obtained experimental results that the increase in interfacial tension of the membrane, which also corresponds to the increase in surface hydrophobicity, correlates with the extent of membrane fusion.     

Surface charge near the cardiac inward-rectifier channel measured from single-channel conductance

Summary The conductance of a channel to permeable ions depends on the number of ions near the mouth of the pore. Surface charge controls the local concentration, and impermeable cations can modify this charge. Correlating channel conductance with the concentration of impermeable cations therefore determines the local charge near the open pore. This paper presents data from cell-attached patches on embryonic chick ventricle cells, and it uses the conductance of inward-rectifier channels in the patch (in 100mm K, with various concentrations of Na, Ca, Ba, and Mg) to estimate the local surface potential. The results indicate the presence of ionized residues near the mouth of the channel. Using the Boltzmann equation and the Gouy-Chapman relation, the surface potential due to these residues (in 100K/33Na/0Ca/0Ba/0Mg) is –40 mV, and the charge density is –0.25e/nm².     

Fluctuation of surface charge in membrane pores

Surface charge in track-etched polyethylene terephthalate (PET) membranes with narrow pores has been probed with a fluorescent cationic dye (3,3'-diethyloxacarbocyanine iodide (diO-C2-(3))) using confocal microscopy. Staining of negatively charged PET membranes with diO-C2-(3) is a useful measure of surface charge for the following reasons: 1) the dye inhibits K(+) currents through the pores and reduces their selectivity for cations; 2) it inhibits [3H]-choline+ transport and promotes 36Cl- transport across the membrane in a pH- and ionic-strength-dependent fashion; and 3) staining of pores by diO-C2-(3) is reduced by low pH and by the presence of divalent cations such as Ca2+ and Zn2+. Measurement of the time dependence of cyanine staining of pores shows fluctuations of fluorescence intensity that occur on the same time scale as do fluctuations of ionic current in such pores. These data support our earlier proposal that fluctuations in ionic current across pores in synthetic and biological membranes reflect fluctuations in the surface charge of the pore walls in addition to molecular changes in pore proteins.     

Probing tubulin-blocked state of VDAC by varying membrane surface charge

Reversible blockage of the voltage-dependent anion channel (VDAC) of the mitochondrial outer membrane by dimeric tubulin is being recognized as a potent regulator of mitochondrial respiration. The tubulin-blocked state of VDAC is impermeant for ATP but only partially closed for small ions. This residual conductance allows studying the nature of the tubulin-blocked state in single-channel reconstitution experiments. Here we probe this state by changing lipid bilayer charge from positive to neutral to negative. We find that voltage sensitivity of the tubulin-VDAC blockage practically does not depend on the lipid charge and salt concentration with the effective gating charge staying within the range of 10-14 elementary charges. At physiologically relevant low salt concentrations, the conductance of the tubulin-blocked state is decreased by positive and increased by negative charge of the lipids, whereas the conductance of the open channel is much less sensitive to this parameter. Such a behavior supports the model in which tubulin's negatively charged tail enters the VDAC pore, inverting its anionic selectivity to cationic and increasing proximity of ion pathways to the nearest lipid charges as compared with the open state of the channel.     

Autocatalytic membrane conductance and memory

A basic characteristic of biological memory is that it has a graded duration, which, even for socalled short-term memory, can vary from minutes to days (i.e. over about three orders of magnitude), depending on the training protocol, which one can think of as determining the “strength” of the memory. Furthermore, the molecular analysis of simple learning in invertebrates has revealed many examples where “learning” is produced by adecrease in an appropriate membrane conductance. This paper provides a quantitative analysis of a simple kinetic scheme where by a conductance decrease can be produced by repetitive nerve impulses, with a duration that varies with stimulus frequency. The simplest model considered is based on the actual kinetics of the naturally-occurring ionophore Monazomycin. This model yields durations ranging only over a factor of about 10, for reasonable parameter values. However, a simple modification of the model yields memory durations ranging over three or more orders of magnitude. We also show that Monazomycin-like kinetics can appear as the result of a combination of simple uni- and bi-molecular reactions, thus making more plausible the possibility that the effects described here may operate in actual biological systems.     

Membrane conductance and surface potential

The specific conductances of black lipid membranes of lecithin, glycerylmonooleate and lecithin and cholesterol in aqueous solutions of KCl + nonactin have been measured. The relative conductances of the lecithin and the glycerylmonooleate membranes are accurately accounted for by the difference in their surface potentials. The large effect of cholesterol in depressing the conductance of the lecithin membranes is, however, not accounted for by changes in the surface potential and it is necessary to invoke either changes in the membrane solubility of the nonactin-K⁺ complex, or changes in the membrane viscosity (as experiences by the ionophore in transit), or both.The surface potentials which, in all the present membranes, arise solely from layers of oriented molecular dipoles, are not affected by the KCl concentration.     

Alamethicin channel conductance modified by lipid charge

The membrane surface charge modifies the conductance of ion channels by changing the electric potential and redistributing the ionic composition in their vicinity. We have studied the effects of lipid charge on the conductance of a multi-state channel formed in planar lipid bilayers by the peptide antibiotic alamethicin. The channel conductance was measured in two lipids: in a neutral dioleoylphosphatidylethanolamine (DOPE) and a negatively charged dioleoylphosphatidylserine (DOPS). The charge state of DOPS was manipulated by the pH of the membrane-bathing solution. We find that at high salt concentrations (e.g., 2 M NaCl) the effect of the lipid charge is below the accuracy of our measurements. However, when the salt concentration in the membrane-bathing solution is decreased, the surface charge manifests itself as an increase in the conductance of the first two channel levels that correspond to the smallest conductive alamethicin aggregates. Our analysis shows that both the salt and pH dependence of the surface charge effect can be rationalized within the nonlinear Poisson-Boltzmann approach. Given channel conductance in neutral lipids, we use different procedures to account for the surface charge (e.g., introduce averaging over the channel aperture and take into account Na+ adsorption to DOPS heads), but only one adjustable parameter: an effective distance from the nearest lipid charge to the channel mouth center. We show that this distance varies by 0.3-0.4 nm upon channel transition from the minimal conducting aggregate (level L0) to the next larger one (level L1). This conclusion is in accord with a simple geometrical model of alamethicin aggregation.     

Surface charge at the cytoplasmic membrane of murine C1300 neuroblastoma cells

Inside-out vesicles (IV, mainly with the cytoplasmic side outermost) were obtained from the plasma membranes of neuroblastoma cells from strain C1300 mice, clone N18. These served as a convenient model for investigating the surface charge of the cytoplasmic side of the cell membrane using microelectrophoretic techniques. Electrophoretic mobility (EM) at a neutral pH and with an external medium of the same ionic strength was found to be 2.7-fold less than that of right-side-out vesicles (RV). Processing vesicles with neuraminidase reduced EM in RV but not in IV, while trypsin did so in both. Treatment with phospholipase C produced the same effect in IV but none in RV. Phospholipase D increases the EM of both types of vesicles. Charged groups at the surface of IV are titrated in relation to a pK of 3.5. The EM of IV is dependent on the Ca²⁺ concentration of the external medium. On the cytoplasmic side of the membrane, Ca²⁺ forms a 11 complex with negatively charged protein and lipid molecules as well as those lipid molecules found with a neutral pH, in the form of a zwitterion with binding constants of 50, 12, and 25 liter/mole respectively.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 20, No. 5, pp. 610–617, September–October, 1988.     

Biofouling in membrane bioreactors: nexus between polyacrylonitrile surface charge and community composition

The influence of membrane surface charge on biofouling community composition during activated sludge filtration in a membrane bioreactor was investigated in this study using polyacrylonitrile-based membranes. Membranes with different surface properties were synthesized by phase inversion followed by a layer-by-layer modification. Various characterization results showed that the membranes differed only in their surface chemical composition and charge, ie two of them were negative, one neutral and one positive. Membrane fouling experiments were performed for 40 days and the biofouling communities were analyzed. PCR-DGGE fingerprinting indicated selective enrichment of bacterial populations from the sludge suspension within the biofilms at any time point. The biofilm community composition seemed to change with time. However, no difference was observed between the biofilm community of differently charged membranes at specific time points. It could be concluded that membrane charges do not play a decisive role in the long-term selection of the key bacterial foulants.     

Contribution of phosphatidylserine to membrane surface charge and protein targeting during phagosome maturation

During phagocytosis, the phosphoinositide content of the activated membrane decreases sharply, as does the associated surface charge, which attracts polycationic proteins. The cytosolic leaflet of the plasma membrane is enriched in phosphatidylserine (PS); however, a lack of suitable probes has precluded investigation of the fate of this phospholipid during phagocytosis. We used a recently developed fluorescent biosensor to monitor the distribution and dynamics of PS during phagosome formation and maturation. Unlike the polyphosphoinositides, PS persists on phagosomes after sealing even when other plasmalemmal components have been depleted. High PS levels are maintained through fusion with endosomes and lysosomes and suffice to attract cationic proteins like c-Src to maturing phagosomes. Phagocytic vacuoles containing the pathogens Legionella pneumophila and Chlamydia trachomatis, which divert maturation away from the endolysosomal pathway, are devoid of PS, have little surface charge, and fail to recruit c-Src. These findings highlight a function for PS in phagosome maturation and microbial killing.     

Evaluation of membrane surface charge density: A discussion of some models

The theory of electrical double layer due to Gouy and Chapman, applied to the experimental data related to shifts of conductance-voltage curve along the voltage axis following changes in the external calcium concentration to derive values for the density of surface charges (σ) present on biomembranes, has been outlined. Similarly, the principal equations of resting membrane potential due to Kobatake and coworkers, also used for the first time by Lakshminarayanaiah to evaluate charges on biomembranes of several tissues, have been given. The values for σ derived by the first method have been considered to indicate the charge density at the channel region through which permeation of Na or K ion occurred. The values for σ derived by the second method are considered to represent the presence of charges smeared out uniformly over the membrane surface. Despite this difference in practical implementation of the concepts of the two theories which initially in their development are based on the assumption of charges covering the membrane surface uniformly, the ultimate values for σ derived by the two methods agree. The significance of this result in relation to different membrane models for surface charges is briefly discussed. Presented at the Society for Mathematical Biology Meeting, University of Pennsylvania, Philadelphia, August 19–21, 1976.     

Increased membrane surface positive charge and altered membrane fluidity leads to cationic antimicrobial peptide resistance in Enterococcus faecalis

To understand the role of cell membrane phospholipids during resistance development to cationic antimicrobial peptides (CAMPs) in Enterococcus faecalis, gradual dose-dependent single exposure pediocin-resistant (Ped^r) mutants of E. faecalis (Efv2.1, Efv3.1, Efv3.2, Efv4.1, Efv4.2, Efv5.1, Efv5.2 and Efv5.3), conferring simultaneous resistance to other CAMPs, selected in previous study were characterized for cell membrane phospholipid head-groups and fatty acid composition. The involvement of phospholipids in resistance acquisition was confirmed by in vitro colorimetric assay using PDA (polydiacetylene)-biomimetic membranes. Estimation of ratio of amino-containing phospholipids to amino-lacking phospholipids suggests that phospholipids in cell membrane of Ped^r mutants loose anionic character. At moderate level of resistance, the cell-membrane becomes neutralized while at further higher level of resistance, the cell-surface acquired positive charge. Increased expression of mprF gene (responsible for lysinylation of phospholipids) was also observed on acquiring resistance to pediocin in Ped^r E. faecalis. Decreased level of branched chain fatty acids in Ped^r mutants might have contributed in enhancing rigidification of cell membrane and contributing towards resistance. The interaction of pediocin with PDA-biomimetic membranes prepared from wild-type and Ped^r mutants was monitored by measuring percent colorimetric response (%CR). Increased %CR of pediocin against PDA-biomimetic membranes prepared from Ped^r mutants confirmed that cell membrane phospholipids are involved in the interactions of pore formation by CAMPs. There was a direct linear relationship between percent colorimetric response and IC₅₀ of CAMPs for wild-type and Ped^r mutants. This relationship further reveals that in vitro colorimetric assay can be used effectively for quantification of resistance to CAMPs.     

Membrane potential and surface charge densities as possible generalized regulators of membrane protein activities

On the basis of experimental evidence accumulated in studies of coupling and other membranes a theoretical discussion of a “breathing” membrane structure dependent upon a changing transmembrane electrical (electrochemical) gradient is presented. In the case of certain membranes difference of electrical potentials across the membrane (Δψ) is considered as one of important driving forces for some membrane protein folding and/or the arrangement of subunits within some oligomeric proteins. Δψ changes may induce synchronous reversible energetically favourable transitions in the three-dimensional architecture of several spatially separated proteins of the biomembrane. A polyfunctional regulation of levels of activities of spatially separated membrane proteins may be achieved; in some cases alterations of Δψ and surface charge densities may fulfil function of a link in the chain of events triggering membrane-bound activities in response to external stimuli.     

Effects of ionic strength,serum protein and surface charge on membrane movements and vesicle production in heated erythrocytes

Morphological changes and fragmentation of human erythrocytes heated at various rates through the spectrin inactivation temperature have been examined by cinephotomicroscopy. Most cells heated in 0.20 ionic strength buffered saline developed a wavy disturbance along the cell rim when heated. Vesicles developed from the crests of the growing waves within 0.3 s of the initiation of a wave when the heating rate was 1°C/s. At an ionic strength of 0.02, only 48% of the cells developed a wave outline. The average number of waves per cell was half that at 0.2 ionic strength. When the cell surface charge was reduced by neuraminidase treatment, only 12% of the cells fragmented. Bovine serum albumin or homologous plasma also reduced fragmentation. The dependence of the wave growth on ionic strength and surface charge was broadly consistent with theoretical predictions for the growth of a displacement instability on a low interfacial tension interface. Attention has been paid to the importance of bending energy in the development of the wave. Where wave development was suppressed, the morphological changes due to heating appeared to involve membrane internalization in the region of the cell dimple.