Membrane surface potential of Spiroplasma floricola

Anionic charges, cytochemically identified as lipid phosphate groups, cover the outer membrane surface of Spiroplasma floricola. They induce a negative membrane surface potential which affects the distribution of ions, including protons. Accordingly, the pH at the interface differs from the bulk pH. By using the fluorescent lipoid pH indicator 4-heptadecyl-7-hydroxycoumarin, the pH at the membrane surface was determined. From the difference of the bulk and the interfacial pH the membrane surface potential of S. floricola was calculated to be phi = -118 mV.     

Proton transfer dynamics at the membrane/water interface: dependence on the fixed and mobile pH buffers, on the size and form of membrane particles, and on the interfacial potential barrier

Crossing the membrane/water interface is an indispensable step in the transmembrane proton transfer. Elsewhere we have shown that the low dielectric permittivity of the surface water gives rise to a potential barrier for ions, so that the surface pH can deviate from that in the bulk water at steady operation of proton pumps. Here we addressed the retardation in the pulsed proton transfer across the interface as observed when light-triggered membrane proton pumps ejected or captured protons. By solving the system of diffusion equations we analyzed how the proton relaxation depends on the concentration of mobile pH buffers, on the surface buffer capacity, on the form and size of membrane particles, and on the height of the potential barrier. The fit of experimental data on proton relaxation in chromatophore vesicles from phototropic bacteria and in bacteriorhodopsin-containing membranes yielded estimates for the interfacial potential barrier for H(+)/OH(-) ions of approximately 120 meV. We analyzed published data on the acceleration of proton equilibration by anionic pH buffers and found that the height of the interfacial barrier correlated with their electric charge ranging from 90 to 120 meV for the singly charged species to >360 meV for the tetra-charged pyranine.     

Surface potential of mycoplasma membranes

Abstract The outer membrane surfaces of several mycoplasma species carry a dense layer of anionic charges, i.e., lipid phosphate groups. They induce a negative surface potential ψ at the membrane-aqueous phase interface. This surface potential strongly affects the distribution of ions including protons. Accordingly, the pH at the interface differs from the bulk pH. By using the fluorescent lipoid pH indicator 4-heptadecyl-7-hydroxycoumarin the pH at the membrane surface was determined. From the difference of the bulk and the interfacial pH the membrane surface potential of Mycoplasma mycoides subsp. capri was calculated to be ψ = −68 mV.     

Probing biological interfaces by tracing proton passage across them.

The properties of water at the surface, especially at an electrically charged one, differ essentially from those in the bulk phase. Here we survey the traits of surface water as inferred from proton pulse experiments with membrane enzymes. In such experiments, protons that are ejected (or captured) by light-triggered enzymes are traced on their way between the membrane surface and the bulk aqueous phase. In several laboratories it has been shown that proton exchange between the membrane surface and the bulk aqueous phase takes as much as about 1 ms, but could be accelerated by added mobile pH-buffers. Since the accelerating capacity of the latter decreased with increase in their electric charge, it was suggested that the membrane surface is separated from the bulk aqueous phase by a barrier of electrostatic nature. In terms of ordinary electrostatics, the barrier could be ascribed to dielectric saturation of water at a charged surface. In terms of nonlocal electrostatics, the barrier could result from the dielectric overscreening in the surface water layers. It is discussed how the interfacial potential barrier can affect the reactions at interface, especially those coupled with biological energy conversion and membrane transport.     

A model for the stimulation of taste receptor cells by salt.

A taste cell mucosal surface is regarded as a planar region containing bound anionic sites and openings to ionic channels. It is assumed that the bulk aqueous properties of the exterior phase are not continuous with the surface but terminate at a plane near the surface. The region between the (Stern) plane and the membrane is regarded as having a lower dielectric constant than bulk water. This fact admits the possibility of ion pair formation between fixed sites and mobile cations. Mobile ion pairs entering the region may also bind to a fixed anionic site. Thus, it is assumed that mobile cations and ion pairs are potential determining species at the surface. Binding cations neutralizes surface charges, whereas binding mobile ion pairs does not. This competition accounts for the observed anion effect on stimulation of tast receptors by sodium salts. The potential profile is constructed by superimposing the phase boundary potentials with an ionic diffusion potential across the membrane. The model accounts for the anion effect on receptor potential, pH effects, the reversal of polarity when cells are treated with FeCl3, and the so-called "water reponse," depolarization of the taste cell upon dilution of the stimulant solution below a critical lower limit. The proposed model does not require both bound cationic and anionic receptors, and further suggests that limited access to a Stern-like region continuous with membrane channels may generally serve to control transport of ions.     

Proton-linked transport systems as sensors of changes in the membrane surface potential

The kinetic properties of proton linked transport systems and their relation to the membrane surface potential were studied in yeast cells. (1) The negative surface potential of cells rich in anionic phospholipids was found to be 2-times higher than that of control cells; in agreement with their 2-fold increase in the anionic/zwitterionic phospholipid ratio (A/Z). (2) At low external concentration of substrates (high-affinity systems), higher uptake activities were observed for the anions, glutamate, aspartate and phosphate; the zwitterion glycine and the cations lysine and arginine, in both phosphatidylserine and phosphatidylinositol rich cells when compared to control cells. (3) On the other hand, at high external concentration of substrates (low-affinity systems), lower uptake activities were observed for glutamate, aspartate, phosphate and glycine in the cells rich in anionic phospholipids. (4) A decrease in Km without significant alteration in Vmax was found in the high-affinity transport systems that can be explained by the increase in proton concentration at the interface caused by the enhancement in negative surface charge of the cells rich in anionic phospholipids. (5) The mechanisms of the high-affinity proton linked transport systems are compatible with a model which is necessarily ordered, protons before anions. The low-affinity transport systems, on the other hand, follow a random order of binding. The transport systems studied behave as sensors of the changes in surface potential. The reduction of the surface potential reversed the transport alterations with the following sequence: monovalent cations less than divalent cations less than cationic local anesthetics.     

Phosphoinositides provide a regulatory mechanism of surface charge and active transport

Yeast cells, when grown in the presence of arsenate, are capable of accumulating phosphoinositides (PI) at the expense of inhibiting their degradation more than their synthesis. PI levels return to normal when the cells are cultured or exposed to media without arsenate. These reversible changes are employed as a tool to test the effect of inositide accumulation and dynamics on several membrane properties. In the PI-rich cells, phosphate and arsenate transport from low external concentrations (high affinity systems), as well as the transport of glycine, which enter the cells accompanied by protons, were increased. The proton ejection energized by glucose is also enhanced in the PI-rich cells that show a more efficient potassium inflow at pH 4.0-4.5. The membrane surface potential of the PI-rich cells was found to be 2-times higher than that of the normal cells, in agreement with the 2-fold increment in the PI. All the above mentioned alterations in membrane properties are reverted when the PI content of the PI-rich cells is reduced to the level of normal cells. The results show the participation of the phosphoinositides in the formation, maintenance and regulation of the membrane surface potential and their possible influence upon transport mechanisms.     

Both acidic and basic amino acids in an amphitropic enzyme,CTP:phosphocholine cytidylyltransferase,dictate its selectivity for anionic membranes

Amphitropic proteins are regulated by reversible membrane interaction. Anionic phospholipids generally promote membrane binding of such proteins via electrostatics between the negatively charged lipid headgroups and clusters of basic groups on the proteins. In this study of one amphitropic protein, a cytidylyltransferase (CT) that regulates phosphatidylcholine synthesis, we found that substitution of lysines to glutamine along both interfacial strips of the membrane-binding amphipathic helix eliminated electrostatic binding. Unexpectedly, three glutamates also participate in the selectivity for anionic membrane surfaces. These glutamates become protonated in the low pH milieu at the surface of anionic, but not zwitterionic membranes, increasing protein positive charge and hydrophobicity. The binding and insertion into lipid vesicles of a synthetic peptide containing the three glutamates was pH-dependent with an apparent pK(a) that varied with anionic lipid content. Glutamate to glutamine substitution eliminated the pH dependence of the membrane interaction, and reduced anionic membrane selectivity of both the peptide and the whole CT enzyme examined in cells. Thus anionic lipids, working via surface-localized pH effects, can promote membrane binding by modifying protein charge and hydrophobicity, and this novel mechanism contributes to the membrane selectivity of CT in vivo.     

Cyanine dye as monitor of membrane potentials in Escherichia coli cells and membrane vesicles.

The fluorescence response of a positively charged cyanine dye: 3,3'-dimethylindodicarbocyanine iodide can be specifically related to the generation in Escherichia coli cells and E. coli membrane vesicles of an electrical membrane potential induced either by substrate oxidation or by an artificially imposed potassium diffusion gradient. The energy-dependent quenching of the dye fluorescence correlates well with the known effect on delta phi of: oxidation of various energy sources, external pH and solute accumulation. Thus, in the vesicles, the fluorescence quenching of the dye increases from succinate to D-lactate, to ascorbate/phenazine methosulfate and parallels the increasing ability of these electron donors to generate a delta phi. In the vesicles, delta phi is only weakly dependent on external pH, whereas in the cells, delta phi increases with increasing external pH. Lactose accumulation in the vesicles results in the partial utilization of delta phi. A calibration of the dye fluorescence in terms of delta phi has been determined using valinomycin-induced potassium diffusion potential.     

Electrostatic interactions at charged lipid membranes. Measurement of surface pH with fluorescent lipoid pH indicators.

The 5-dimethylaminonapthalene-1-sulfonyl (dansyl) chromophore attached to the polar head groups of lipids has been used as a fluorescent lipoid pH indicator to evaluate the interfacial pH in lipid-water lamellar systems prepared from negatively charged lipids. The pH in the vicinity of the charged lipid bilayers is different from the pH of the bulk aqueous phase and the difference is a function of the electrolyte concentration in the aqueous phase and of the lipid packing in the bilayer. At a fixed electrolyte concentration in the aqueous phase, the observed interfacial pH is 0.6 to 0.7 pH units lower above the thermal phase transition of the lipid than it is below this temperature. A quantitative interpretation of the results is given on the basis of the Gouy-Chapman theory. The results indicate that the dansyl chromophore is located in front of the charged surface and its distance from this surface increases with a decrease in lipid packing.     

Surface potential changes on energization of mycoplasma cell membranes

The membrane surface potential of mycoplasma cells was measured by changes in the partition between the membrane and the aqueous environment of the impermeable cationic amphipatic spin probe 4-(N,N-dimethyl-N-nonyl)ammonium-2,2,6,6-tetramethylpiperidine-1-oxyl (CAT9). Upon energization of glycolyzing mycoplasma cells, the outer surface of these membranes becomes more negatively charged. The effects of uncouplers further indicate that this change in surface potential appear to be dependent on the existence of a delta pH across the membranes.     

Na(+)-dependent transport of anionic amino acids by preimplantation mouse blastocysts.

Negatively charged amino acids, such as aspartate and glutamate, were selected as substrates by low- and high-Km components of mediated Na(+)-dependent transport in preimplantation mouse blastocysts. These and other relatively small anionic amino acids with two carbon atoms between the negatively charged groups (or up to three carbon atoms when the groups were both carboxyl groups) interacted strongly with the low-Km component of transport, whereas larger anionic amino acids interacted weakly or not at all. The low-Km system was also stereoselective except in the case of aspartate. Moreover, transport was Cl(-)-dependent and slower at pH values outside the range 5.6-7.4. L-Aspartate, D-aspartate and L-glutamate each interacted strongly with the low-Km component of transport with Km values for transport nearly equal to their Ki values for inhibition of transport of one of the other amino acids. By these criteria, the low-Km component of transport of anionic amino acids in blastocysts appears to be the same as the familiar system X-AG that is present in other types of mammalian cells. In contrast, the high-Km component of transport in blastocysts preferred L-aspartate to L-glutamate, whereas the reverse is true for fibroblasts. Therefore, transport of anionic amino acids in blastocysts may occur via at least one process that has not been described in other types of cells. Roughly half of mediated glutamate and aspartate transport in blastocysts may occur via the high-Km component of transport at the concentrations of these amino acids that may be present in uterine secretions.     

Anionic phospholipids in the control of the membrane surface potential in Escherichia coli: their influence on transport mechanisms.

1. Phosphatidylserine (PS)-rich Escherichia coli cells were utilized to investigate the role of anionic phospholipids on membrane surface potential and their effect upon active transport mechanisms. 2. It was found that: 3. The transport of inorganic phosphate and glutamate, which depends upon cations, was increased (Km decreases) in PS-rich cells as compared to normal cells. 4. The reduction of the negative surface potential by MgCl2 or by the cationic local anesthetic procaine, brought about a decrement in the uptake of both substrates. 5. When the negative surface potential of the PS-rich cells was reduced, the Km returned back to the values found in normal cells. 6. A direct correlation between the ratio anionic/zwitterionic phospholipids, negative surface potential and increment in the initial rate of transport was found.     

Uniport of anionic citrate and proton consumption in citrate metabolism generates a proton motive force in Leuconostoc oenos.

The mechanism and energetics of citrate transport in Leuconostoc oenos were investigated. Resting cells of L. oenos generate both a membrane potential (delta psi) and a pH gradient (delta pH) upon addition of citrate. After a lag time, the internal alkalinization is followed by a continuous alkalinization of the external medium, demonstrating the involvement of proton-consuming reactions in the metabolic breakdown of citrate. Membrane vesicles of L. oenos were prepared and fused to liposomes containing cytochrome c oxidase to study the mechanism of citrate transport. Citrate uptake in the hybrid membranes is inhibited by a membrane potential of physiological polarity, inside negative, and driven by an inverted membrane potential, inside positive. A pH gradient, inside alkaline, leads to the accumulation of citrate inside the membrane vesicles. Kinetic analysis of delta pH-driven citrate uptake over a range of external pHs suggests that the monovalent anionic species (H2cit-) is the transported particle. Together, the data show that the transport of citrate is an electrogenic process in which H2cit- is translocated across the membrane via a uniport mechanism. Homologous exchange (citrate/citrate) was observed, but no evidence for a heterologous antiport mechanism involving products of citrate metabolism (e.g., acetate and pyruvate) was found. It is concluded that the generation of metabolic energy by citrate utilization in L. oenos is a direct consequence of the uptake of the negatively charged citrate anion, yielding a membrane potential, and from H(+)-consuming reactions involved in subsequent citrate metabolism, yielding a pH gradient. The uptake of citrate is driven by its own concentration gradient, which is maintained by efficient metabolic breakdown (metabolic pull).     

Protein chemistry at membrane interfaces: non-additivity of electrostatic and hydrophobic interactions

Non-specific binding of proteins and peptides to charged membrane interfaces depends upon the combined contributions of hydrophobic (DeltaG(HPhi)) and electrostatic (DeltaG(ES)) free energies. If these are simply additive, then the observed free energy of binding (DeltaG(obs)) will be given by DeltaG(obs)=DeltaG(HPhi)+DeltaG(ES), where DeltaG(HPhi)=-sigma(NP)A(NP) and DeltaG(ES)=zFphi. In these expressions, A(NP) is the non-polar accessible area, sigma(NP) the non-polar solvation parameter, z the formal peptide valence, F the Faraday constant, and phi the membrane surface potential. But several lines of evidence suggest that hydrophobic and electrostatic binding free energies of proteins at membrane interfaces, such as those associated with cell signaling, are not simply additive. In order to explore this issue systematically, we have determined the interfacial partitioning free energies of variants of indolicidin, a cationic proline-rich antimicrobial peptide. The synthesized variants of the 13 residue peptide covered a wide range of hydrophobic free energies, which allowed us to examine the effect of hydrophobicity on electrostatic binding to membranes formed from mixtures of neutral and anionic lipids. Although DeltaG(obs) was always a linear function of DeltaG(HPhi), the slope depended upon anionic lipid content: the slope was 1.0 for pure, zwitterionic phosphocholine bilayers and 0.3 for pure phosphoglycerol membranes. DeltaG(obs) also varied linearly with surface potential, but the slope was smaller than the expected value, zF. As observed by others, this suggests an effective peptide valence z(eff) that is smaller than the formal valence z. Because of our systematic approach, we were able to establish a useful rule-of-thumb: z(eff) is reduced relative to z by about 20 % for each 3 kcal mol(-1) (1 kcal=4.184 kJ) favorable increase in DeltaG(HPhi). For neutral phosphocholine interfaces, we found that DeltaG(obs) could be predicted with remarkable accuracy using the Wimley-White experiment-based interfacial hydrophobicity scale.     

Reversible binding of substance P to artificial lipid membranes studied by capacitance minimization techniques

Interaction of substance P with electrically neutral, planar lipid bilayers prepared from 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine and with anionic bilayers prepared from mixtures of 1,2-dioleoyl-sn-glycero-3-phosphocholine and brain phosphatidylserine was measured using the capacitance minimization method for monitoring the membrane surface potential caused by the positive charges and electric dipole moment of adsorbed peptide. Substance P bound to the electrically neutral bilayers from 9 mM KCl (buffered to pH 5.5 with 2.0 mM 2-(N-morpholino)ethanesulfonate) with a maximal binding density of about 1 x 10(-2) molecules per nm2 and a dissociation constant of about 2 x 10(-4) M. Measurement of the surface potential at different ionic strengths (shielding of surface charges) allowed distinction between the fixed-charge surface potential and a dipole potential. Ascribing this dipole potential to membrane-bound substance P would imply an effective dipole moment normal to the bilayer surface of about 20 Debye per molecule. Magnitude and polarity are consistent with an alpha-helical domain at the C-terminal end of substance P which is oriented normal to the surface of the membrane, and inserted so as to be inaccessible to the aqueous phase. Consistent measurements were obtained with anionic membranes at low substance P concentrations (10(-7)-10(-6) M; pH 7.2). They indicated electrostatic accumulation of the triply charged peptide on the surface of the membrane followed by hydrophobic interaction with the same parameters as for neutral membranes. The results agree with the membrane structure of substance P determined with infrared attenuated total reflection spectroscopy, circular dichroism measurements, and thermodynamic estimations.     

On the role of lipid in colicin pore formation

Insights into the protein-membrane interactions by which the C-terminal pore-forming domain of colicins inserts into membranes and forms voltage-gated channels, and the nature of the colicin channel, are provided by data on: (i) the flexible helix-elongated state of the colicin pore-forming domain in the fluid anionic membrane interfacial layer, the optimum anionic surface charge for channel formation, and voltage-gated translocation of charged regions of the colicin domain across the membrane; (ii) structure-function data on the voltage-gated K(+) channel showing translocation of an arginine-rich helical segment through the membrane; (iii) toroidal channels formed by small peptides that involve local participation of anionic lipids in an inverted phase. It is proposed that translocation of the colicin across the membrane occurs through minimization of the Born charging energy for translocation of positively charged basic residues across the lipid bilayer by neutralization with anionic lipid head groups. The resulting pore structure may consist of somewhat short, ca. 16 residues, trans-membrane helices, in a locally thinned membrane, together with surface elements of inverted phase lipid micelles.     

The effect of pH on the phase transition temperature of dipalmitoylphosphatidylcholine-palmitic acid liposomes

The shift in the gel-liquid crystal phase transition temperature (tm) of dipalmitoylphosphatidylcholine liposomes induced by incorporation of 10 mol% palmitic acid, was measured by 90 degrees light scattering at different bulk pH values. It has been found that the tm shift decreases sigmoidally from 4.7 to -0.3 degrees C as the bulk pH is raised from 5 to 11. Since it is in this range that the carboxyl group of a membrane-bound fatty acid should ionize, our results can be interpreted to mean that there is relationship between the tm shift and the degree of dissociation of palmitic acid, the uncharged fatty acid increasing tm and its conjugate, anionic form, slightly decreasing the transition temperature of dipalmitoylphosphatidylcholine liposomes. The experimental results are fitted by a modified form of the Henderson-Hasselbach equilibrium expression which takes into account the effect of the anionic fatty acid on the surface potential and hence, on the surface pH of liposomes, according to Gouy-Chapman and Boltzmann equations, respectively. Best fit between theory and experiments is found when the intrinsic interfacial pK of palmitic acid is set equal to 7.7. This high pK value can be explained as due to the effect of the lower dielectric constant of the interfacial region, as compared to bulk water, on the acid-base dissociation of the carboxyl group. The results presented here show that upon incorporation of palmitic acid, the phase transition of dipalmitoylphosphatidylcholine bilayers becomes extremely sensitive to changes of pH in the vicinity of the physiological range. This property is not shown by the pure phospholipid bilayers in the same pH range.     

The effect of washing on the surface charge of Mycobacterium bovis BCG vaccine, Tice substrain

The zeta potential of three lots of Tice substrain BCG organisms was measured over a pH range of 2.0 to 11.0 at low electrolyte concentration. For two lots, the cells were cationic at pH 4.2-4.4 and anionic above this isoelectric point. Washing the cells twice with water lowered the isoelectric point to 2.7. The cationic/anionic profile was retained in all three lots, although the third lot had an isoelectric point of 3.0 initially. Cells of the Glaxo substrain, on the other hand, were anionic over the entire pH range and are evidently unaffected by the washing process. It appears that cells of the Glaxo strain have only electronegative phosphate groups at their surface whereas the Tice substrain may possess a loosely adhering cell-surface protein.