Effects of monovalent anions of the hofmeister series on DPPC lipid bilayers Part II: modeling the perpendicular and lateral equation-of-state

The effects of Hofmeister anions on the perpendicular and lateral equation-of-state (EOS) of the dipalmitoylphosphatidylcholine lamellar phase discussed in the companion article are here examined using appropriate free energy models for the intra- and interbilayer interactions. Minimizing the free energy with respect to the two basic geometrical parameters of the lamellar phase, which are the interbilayer water thickness, d(w), and the lipid headgroup area, a(L), provides the perpendicular (osmotic pressure balance) and lateral EOS. Standard models were used for the hydration, undulation, and Van der Waals attractive force between the bilayers in the presence of electrolytes whereas two alternative treatments of electrostatic interactions were used to obtain "binding" or "partitioning" constants of anions to the lipid bilayers both in the absence and in the presence of sodium binding. The computed binding constants depend on anion type and follow the Hofmeister series, but were found to increase with electrolyte concentration, implying that the local binding approximation cannot fit bilayer repulsion data. The partitioning model was also found inadequate at high electrolyte concentrations. The fitting attempts revealed two additional features worthy of future investigation. First, at maximum swelling in the presence of electrolytes the osmotic pressure of the bilayer system cannot be set equal to zero. Second, at high salt concentrations an additional repulsion appears to come into effect in the presence of strongly adsorbing anions such as I(-) or SCN(-). Both these phenomena may reflect an inconsistent treatment of the ion-surface interactions, which have an impact on the osmotic pressure. Alternatively, they may arise from bulk solution nonidealities that cannot be handled by the classical Poisson-Boltzmann formalism. The inability of current models to explain the "lateral" EOS by fitting the area per lipid headgroup as a function of salt type and concentration shows that current understanding of phospholipid-ion interactions is still very incomplete.     

Thermal stability of lysozyme as a function of ion concentration: A reappraisal of the relationship between the Hofmeister series and protein stability

Anion and cation effects on the structural stability of lysozyme were investigated using differential scanning calorimetry. At low concentrations (<5 mM) anions and cations alter the stability of lysozyme but they do not follow the Hofmeister (or inverse Hofmeister) series. At higher concentrations protein stabilization follows the well‐established Hofmeister series. Our hypothesis is that there are three mechanisms at work. At low concentrations the anions interact with charged side chains where the presence of the ion can alter the structural stability of the protein. At higher concentrations the low charge density anions perchlorate and iodide interact weakly with the protein. Their presence however reduces the Gibbs free energy required to hydrate the core of the protein that is exposed during unfolding therefore destabilizing the structure. At higher concentrations the high charge density anions phosphate and sulfate compete for water with the protein as it unfolds increasing the Gibbs free energy required to hydrate the newly exposed core of the protein therefore stabilizing the structure.     

Investigation of anion binding to neutral lipid membranes using 2H NMR.

The binding of aqueous anions (ClO4-, SCN-, I-, and NO3-) to lipid bilayer membranes composed of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) was investigated using deuterium (2H) and phosphorus-31 (31P) nuclear magnetic resonance (NMR) spectroscopy. The ability of these anions to influence the 2H NMR quadrupole splittings of POPC, specifically labeled at the alpha or beta position of the choline head group, increased in the order NO3- much less than I- less than SCN- less than ClO4-. In the presence of these chaotropic anions, the quadrupole splitting increased for alpha-deuterated POPC and decreased for beta-deuterated POPC, indicating a progressive accumulation of negative charge at the membrane surface. Calibration of the 2H NMR quadrupole splittings with the amount of membrane-bound anion permitted binding isotherms to be generated for perchlorate, thiocyanate, and iodide, up to concentrations of 100 mM. The binding isotherms were analyzed by considering electrostatic contributions, according to the Gouy-Chapman theory, as well as chemical equilibrium contributions. For neutral POPC membranes, we obtained ion association constants of 32, 80, and 115 M-1 for iodide, thiocyanate, and perchlorate, respectively. These values increase in the order expected for a Hofmeister series of anions. We conclude that the factor determining whether a particular anion will bind to lipid bilayers is the ease with which that anion loses its hydration shell.(ABSTRACT TRUNCATED AT 250 WORDS)     

Glutamate overcomes the salt inhibition of DNA polymerase III holoenzyme

Even though Escherichia coli can grow in media containing up to 1 M NaCl, one-fifth that amount of NaCl will completely inhibit the in vitro activity of DNA polymerase III holoenzyme. It has been established that the major intracellular ionic osmolytes are potassium and glutamate (Richey, B., Cayley, D. S., Mossing, M. C., Kolka, C., Anderson, C. F., Farrar, T. C., and Record, M. T., Jr. (1987) J. Biol. Chem. 262, 7157-7164). We have found that holoenzyme catalyzes replication efficiently in vitro in up to 1 M potassium glutamate. Two salt effects on the replication of single-stranded DNA were observed. At low salt replicative activity was enhanced and at high salt there was anion-specific inhibition. We have found that DNA polymerase III holoenzyme tolerated 10-fold higher concentrations of glutamate than chloride. The ability of various anions to extend the useful range of salt concentrations followed the order: phosphate less than chloride less than N-Ac-glutamate less than acetate less than glycine less than aspartate less than glutamate. With the exception of phosphate, this order followed the Hofmeister series indicating that the anion-specific effects were due to anions interacting at the protein-water interface at weak anion binding sites. Glutamate did not reverse the inhibition by chloride. The low salt enhancement and high salt inhibition effects were additive for the two anions indicating that they competed for common anion binding sites. The major salt-sensitive step was holoenzyme binding to template rather than the subsequent elongation reaction.     

Changes in phosphatidylcholine headgroup tilt and water order induced by monovalent salts: molecular dynamics simulations

The association between monovalent salts and neutral lipid bilayers is known to influence global bilayer structural properties such as headgroup conformational fluctuations and the dipole potential. The local influence of the ions, however, has been unknown due to limited structural resolution of experimental methods. Molecular dynamics simulations are used here to elucidate local structural rearrangements upon association of a series of monovalent Na(+) salts to a palmitoyl-oleoyl-phosphatidylcholine bilayer. We observe association of all ion types in the interfacial region. Larger anions, which are meant to rationalize data regarding a Hofmeister series of anions, bind more deeply within the bilayer than either Cl(-) or Na(+). Although the simulations are able to reproduce experimentally measured quantities, the analysis is focused on local properties currently invisible to experiments, which may be critical to biological systems. As such, for all ion types, including Cl(-), we show local ion-induced perturbations to headgroup tilt, the extent and direction of which is sensitive to ion charge and size. Additionally, we report salt-induced ordering of the water well beyond the interfacial region, which may be significant in terms of hydration repulsion between stacked bilayers.     

Chaotropic ions and multivalent ions activate sperm in the viviparous fish guppy Poecilia reticulata

The control system of sperm motility in the fishes with internal fertilization still remains to be studied. In the present study, we examined the sperm activation in the viviparous fish guppy Poecilia reticulata as a function of solute composition. The degree of sperm activation by inorganic and organic solutes correlated well with the lyotropic or Hofmeister series. The solutes that induced sperm activation corresponded to those that have been termed "chaotropes" or macromolecule-destabilizing solutes. In addition to this Hofmeister rule, multivalent cations and anions had valency-dependent activating effects at low concentrations. We investigated the cell signaling triggered by chaotropes and divalent cations and found an intracellular cAMP concentration increase upon the activation of sperm motility. From the present findings, we propose a novel regulation mechanism of sperm motility in the viviparous fish.     

The effects of high concentrations of salts on photosynthetic electron transport in spinach (Spinacia oleracea) chloroplasts.

1. Photosynthetic electron transport from water to lipophilic Photosystem II acceptors was stimulated 3--5-fold by high concentrations (greater than or equal to 1 M) of salts containing anions such as citrate, succinate and phosphate that are high in the Hofmeister series. 2. In trypsin-treated chloroplasts, K3Fe(CN)6 reduction insensitive to 3-(3,4-dichlorophenyl)-1,1-dimethylurea was strongly stimulated by high concentrations of potassium citrate, but there was much less stimulation of 2,6-dichloroindophenol reduction in Tris-treated chloroplasts supplied with 1,5-diphenylcarbazide as artificial donor. The results suggest that the main site of action of citrate was the O2-evolving complex of Photosystem II. 3. Photosystem I partial reactions were also stimulated by intermediate concentrations of citrate (up to 2-fold stimulation by 0.6--0.8 M-citrate), but were inhibited at the highest concentrations. The observed stimulation may have been caused by stabilizaton of plastocyanin that was complexed with the Photosystem I reaction centre, 4. At 1 M, potassium citrate protected O2 evolution against denaturation by heat or by the chaotropic agent NaNO3. 5. It is suggested that anions high in the Hofmeister series stimulated and stabilized electron transport by enhancing water structure around the protein complexes in the thylakoid membrane.     

Effect of ethylene oxide and propylene oxide block copolymers on the permeability of bilayer lipid membranes to small solutes including doxorubicin

The effects of ethylene oxide and propylene oxide block copolymers (pluronics) on the permeability of several weak acids and bases through bilayer lipid membranes have been studied by the methods of monitoring (1) pH shifts near planar bilayers, (2) doxorubicin fluorescence quenching inside liposomes, and (3) current transients in the presence of hydrophobic anions. It has been shown that pluronics facilitate the permeation of comparatively large molecules (such as 2-n-undecylmalonic acid and doxorubicin) across lipid bilayers, while the permeation of small solutes (such as ammonium and acetic acid) remains unaffected. Pluronics also accelerate the translocation of large hydrophobic anions (tetraphenylborate). The effect of pluronics correlates with the content of propylene oxide units: it is enhanced when the portion of polypropylene oxide block in the copolymer is increased. The action of the pluronic on lipid membrane permeability differs from the effect of the conventional detergent Triton X-100, which does not affect doxorubicin transport if added at concentrations similar to those used for pluronics. It has been proposed that pluronics accelerate the processes of solute diffusion within lipid bilayers (in a structure-dependent manner) rather than influencing the rate of solute adsorption/desorption on the membrane surface. We suppose that the effect of pluronics on doxorubicin permeation across lipid bilayers along with the known effect on the multidrug resistance protein determines its influence on the therapeutic activity of anthracycline drugs.     

The effect of electrolyte on the morphology of vesicles composed of the dialkyl polyoxyethylene ether surfactant 2C18E12

Small-angle neutron-scattering (SANS) studies were performed on vesicles composed of 1,2-di-O-octadecyl-rac-glyceryl-3-(omega-methoxydodecaethylene glycol), in deuterium oxide (D2O) solutions with various ionic strengths of LiCl, NaCl and NaI. Gross vesicle morphologies, examined using freeze-fracture electron microscopy, showed that NaCl promoted the formation of multilamellar vesicles. Model fitting of the SANS data showed changes in bilayer parameters such as thickness and repeat spacings, in response to the presence of ions in the bulk solution. 2C18E12 vesicles in D2O are shown to exist as predominantly unilamellar structures with a bilayer thickness of approximately 51 A. Vesicles in increasing concentrations of LiCl and NaCl exhibit decreased layer thickness and increased lamelarity. Little change was observed for vesicles formed in NaI solutions. We suggest that these changes result from intrusion of E12 headgroups into the alkyl chain region of the vesicle bilayers, in response to the increase in concentration of ions present and their charge density.     

Effect of the chaotropic anions thiocyanate and perchlorate on the entry of ricin into Vero cells.

The effect of different anions on the sensitivity of Vero cells to ricin was investigated. The cells were equally sensitive to ricin when NaCl was replaced by NaBr, NaI, Na2SO4 or with iso-osmotic concentrations of mannitol. In contrast, NaSCN and NaClO4 strongly protected against ricin at pH 7.2, but not at pH 7.6. The possibility that the protective effect is due to the ability of chaotropic anions to decrease the pH close to the membrane is discussed.     

Modulation of activity of NADH oxidase from Thermus thermophilus through change in flexibility in the enzyme active site induced by Hofmeister series anions.

The conformational dynamics of NADH oxidase from Thermus thermophilus was modulated by the Hofmeister series of anions (H2PO4-, SO42-, CH3COO-, Cl-, Br-, I-, ClO4-, SCN-) in the concentration range 0-3 M. Both chaotropic and kosmotropic anions, at high concentration, inhibit the enzyme by different mechanisms. Chaotropic anions increase the apparent Michaelis constant and decrease the activation barrier of the reaction. Kosmotropic anions have the opposite effect. Anions from the middle of the Hofmeister series do not significantly affect the enzyme activity even at high concentration. We detected no significant changes in ellipticity of the aromatic region in the presence of the anions studied. There is a decreased Stern-Volmer quenching constant for FAD fluorescence quenching in the presence of kosmotropic anions and an increased quenching constant in the presence of chaotropic anions. All of this indicates that active site flexibility is important in the function of the enzyme. The data demonstrate that both the high rigidity of the active site in the presence of kosmotropic anions, and its high flexibility in the presence of chaotropic anions have a decelerating effect on enzyme activity. The Hofmeister series of anions proved to be suitable agents for altering enzyme activity through changes in flexibility of the polypeptide chain, with potential importance in modulating extremozyme activity at room temperature.     

Assignment of charge movements to electrogenic reaction steps of Na,K-ATPase by analysis of salt effects on the kinetics of charge movements

Na,K-ATPase-enriched membrane fragments adsorbed to lipid bilayers were used to study electrogenic Na+ movements induced by enzyme phosphorylation when ATP was photo-released from inactive caged ATP, and simultaneously by externally applied alternating voltages which allowed the measurement of small ATP-induced membrane admittance changes. A detailed analysis of frequency dependence of the capacitance and conductance increments showed that the observed process consists of more than one electrogenic step. The frequency dependence could be described by the sum of two Lorentzian functions and a constant term. The faster process (approximately 2000 s(-1)) was assigned to the release of the first extracellular Na+ ion. The corner frequency of the slower Lorentzian (about 30 s(-1)) coincided with the reciprocal exponential time constant of the falling phase of the transient current, which can be assigned to the conformational transition. Preferentially, the slower process showed a dependence on the ion concentration of choline salts with different anions. The effectiveness of the used chaotropic anions to decelerate the kinetics decreased in agreement with the Hofmeister series, I- > Br- > Cl-. This observation matches their effect on the partition between two phosphoenzyme states of the Na,K-ATPase, as established previously.     

The effects of salts on the subunit structure and dissociation of Lumbricus terrestris hemoglobin.

The effects of the neutral salts of the Hofmeister series, NaCl, NaClO4, MgCl2, NaI, and also guanidine hydrochloride (Gdn-HCl)on the subunit organization and the state of association of Lumbricus terrestris hemoglobin were examined by light scattering molecular weight measurements. The subunit dissociation of the parent duodecameric structure of 3 x 10(6) molecular weight by various salts is similar in pattern to the sequential splitting of the associated protein to half-molecules of hexamers of 1.5 x 10(6) molecular weight, followed by further dissociation at higher reagent concentration to monomers of 250000 molecular weight. Duodecamer to hexamer dissociation is observed in 0.4 M MgCl2, 1-2 M NaCl, and 1 M Gdn-HCl, while hexamer to monomer dissociation is seen in the presence of 1 M MgCl2. All three species of duodecamers, hexamers, and monomers seem to be present in 1 M NaClO4. Further splitting of the monomers of A subunits to smaller B fragments of one-third to one-quarter molecular weight is observed in 1 M NaI solutions. Optical rotation in the peptide region and absorption measurements in the Soret region indicate the salt dissociation of Lumbricus terrestris hemoglobin is not accompanied by major changes in the folding of the subunits, except in the case of the strong protein denaturant, Gdn-HCl. Relative to the dissociation effects of the urea series of compounds reported in the preceding paper (Herskovits and Harrington, 1975), the neutral salts appear to be much more effective dissociating agents for L. terrestris hemoglobin. This suggests that polar and ionic interactions are relatively more important for the maintenance of the protein than hydrophobic interactions. This conclusion is also supported by calculations of the possible effects of binding of NaClO4, based on the Setschenow constants of the literature describing the interaction of salts with the peptide and hydrophobic alkyl group of the average amino acid found in proteins, on the standard free energy of dissociation of the duodecamer to hexamer.     

Properties of ionic channels formed by the antibiotic syringomycin E in lipid bilayers: dependence on the electrolyte concentration in the bathing solution.

Using the planar lipid bilayer technique, organization of ionic channels formed by the lipodepsipeptide antibiotic syringomycin E applied to one (cis) side of a lipid bilayer was studied. Low concentrations of NaCl (0.01-0.1 M) induced the opening and closing of two types of channels - "small" and "large". The large channels had single channel conductances approximately six times greater than those of the small channels. An increase in the NaCl concentration (0.6-1.0 M) decreased almost completely the chance to reveal the large channels. Although the syringomycin channels exhibited the anion selectivity within the entire range of NaCl concentrations in the bathing solutions (from 0.001 to 1.0 M) whereas the concentration gradients across the bilayers were 2 and 4, the transfer numbers for Cl-decreased with an increase in the mean NaCl concentration (from 0.83 for 0.005 M to 0.70 for 0.5 M). Moreover, at each mean value of NaCl concentration, all conductance levels had the same ion selectivity (identical reversal potential). These results suggest that at low NaCl concentrations the large channels are clusters of small channels which synchronously open and close, while at high electrolyte concentrations the screening of the charged groups responsible for channel interactions prevents the cluster formation. A new theoretical approach for the estimation of the channel radius and the number of elementary charges located at its inner surface (based on the experimental curve of the dependence of transfer number on the NaCl concentration) was developed. Based on this theoretical approach, the channel radius equal to 1 nm and one elementary charge located at its inner surface were obtained.     

Specific Ions Effect on Emulsions, Foams, and Gels of a Seed Protein

A protein concentrate was prepared from the seeds of jack bean (Canavalia ensiformis), and the influence of selected Hofmeister salts on functional properties of the protein concentrate was investigated. Results indicated that kosmotropic salts (Na₂SO₄, NaCl, NaBr) improved water absorption capacity and least gelation concentration of the proteins more than chaotropic salts (NaI, NaClO₄, NaSCN) did. The reduction in water absorption capacity followed the Hofmeister trend (Na₂SO₄ > NaCl > NaBr > NaI > NaClO₄ > NaSCN). However, a reverse trend was observed with the foaming and emulsifying properties. These findings are insightful in understanding the structure–property relations of the concentrate.     

Role of protein-water interactions and electrostatics in alpha-synuclein fibril formation

Deposition of misfolded alpha-synuclein is a critical factor in several neurodegenerative disorders. Filamentous alpha-synuclein is the major component of Lewy bodies and Lewy neurites, the intracellular inclusions in the dopaminergic neurons of the substantia nigra, which are considered the pathological hallmark of Parkinson's disease. We show here that anions induce partial folding of alpha-synuclein at neutral pH, forming a critical amyloidogenic intermediate, which leads to significant acceleration of the rate of fibrillation. The magnitude of the accelerating effect generally followed the position of the anions in the Hofmeister series, indicating a major role of protein-water-anion interactions in the process at salt concentrations above 10 mM. Below this concentration, electrostatic effects dominated in the mechanism of anion-induced fibrillation. The acceleration of fibrillation by anions was also dependent on the cation. Moderate concentrations of anions affected both the rates of nucleation and the elongation of alpha-synuclein fibrillation, primarily via their effect on the interaction of the protein with water.     

Flexibility and enzyme activity of NADH oxidase from Thermus thermophilus in the presence of monovalent cations of Hofmeister series

Recently, we have shown that anions of Hofmeister series affect the enzyme activity through modulation of flexibility of its active site. The enzyme activity vs. anion position in Hofmeister series showed an unusual bell-shaped dependence. In the present work, six monovalent cations (Na(+), Gdm(+), NH(4)(+), Li(+), K(+) and Cs(+)) of Hofmeister series with chloride as a counterion have been studied in relation to activity and stability of flavoprotein NADH oxidase from Thermus thermophilus (NOX). With the exception of strongly chaotropic guanidinium cation, cations are significantly less effective in promoting the Hofmeister effect than anions mainly due to repulsive interactions of positive charges around the active site. Thermal denaturations of NOX reveal unfavorable electrostatic interaction at the protein surface that may be shielded to different extent by salts. Michaelis-Menten constants for NADH, accessibility of the active site as reflected by Stern-Volmer constants and activity of NOX at high cation concentrations (1-2 M) show bell-shaped dependences on cation position in Hofmeister series. Our analysis indicates that in the presence of kosmotropic cations the enzyme is more stable and possibly more rigid than in the presence of chaotropic cations. Molecular dynamic (MD) simulations of NOX showed that active site switches between open and closed conformations [J. Hritz, G. Zoldak, E. Sedlak, Cofactor assisted gating mechanism in the active site of NADH oxidase from Thermus thermophilus, Proteins 64 (2006) 465-476]. Enzyme activity, as well as substrate binding, can be regulated by the salt mediated perturbation of the balance between open and closed forms. We propose that compensating effect of accessibility and flexibility of the enzyme active site leads to bell-shaped dependence of the investigated parameters.     

The effect of solution electrolytes on the uptake of photosensitizers by liposomal membranes: a salting-out effect

In this study we investigated, spectroscopically, the effect of electrolytes on the partitioning of hematoporphyrin IX (HP) and hypericin (Hy) into non-charged lipid vesicles. Our aim was to assess the salting-out effect of electrolytes on membrane-partitioning. We titrated aqueous solutions of HP and Hy with lecithin liposomes, at different concentrations of several monovalent and divalent electrolytes in the suspension. The partitioning constant of HP to lecithin liposomes increased from 3.3 (mL/mg) in water containing only 5mM buffer to 8.7 (mL/mg) at 0.36M KCl. KF had a similar effect. NaCl caused a 3-fold increase in the partitioning of Hy to liposomes. MgSO(4) and MgCl(2) also increased the partitioning of HP, by a factor of more than 4 and this occurred already at 0.03M concentration. We analyze the comparative effects of the electrolytes in relation to the Hofmeister series. The salting-out effect could be utilized to enhance the uptake of HP and Hy, and possibly other photosensitizers as well, by artificial and natural membranes.     

Phospholipid spherules (liposomes) as a model for biological membranes

This review describes the properties of artificial spherules composed of phospholipids and various long-chain anions or cations. The lipids, which are in the liquid-crystal state, trap aqueous solutes such as cations, anions, glucose, or glycine in aqueous compartments between a series of lipid bilayers. The diffusion of these solutes from the spherules can be studied in the same way that diffusion across biological membranes is studied. The spherules exhibit many of the properties of natural membrane-bounded structures: they are capable of ion-discrimination, osmotic swelling, and response to a variety of physiologic and pharmacologic agents. These agents (steroids, drugs, toxins, antibiotics) accelerate or retard diffusion of ions or molecules from the spherules in a way that qualitatively mimics their action on erythrocytes, lysosomes, or mitochondria. Thus the spherules constitute a valuable model system with which to study the properties of biological membranes that may be dependent on their lipid components.     

Hofmeister effect in ion transport: reversible binding of halide anions to the roflamycoin channel.

We have studied the anion-dependent gating of roflamycoin ion channels using spectral analysis of noise in currents through multichannel planar lipid bilayers. We have found that in addition to low frequency current fluctuations that may be attributed to channel switching between open and closed conformations, roflamycoin channels exhibit a pronounced higher frequency noise indicating that the open channel conductance has substates with short lifetimes. This noise is well described by a Lorentzian spectrum component with a characteristic cutoff frequency that depends on the type of halide anions according to their position in the Hofmeister series. It is suggested that transitions between the substates correspond to a reversible ionization of the channel by a penetrating anion that binds to the channel structure, more chaotropic anions being bound for longer times. Within a framework of a two-substate model, the duration of the substate with reduced electrostatic barrier for cation current varies exponentially with anion electron polarizability. This explains two features of the roflamycoin channel reported earlier: the increase in apparent single-channel conductance along the series F- < Cl- < Br- < I- and the reverse of channel selectivity from anionic for KF to cationic for KI.