Topology of amino-phospholipids in the red cell membrane

The red cell membrane has an asymmetric arrangement of phospholipids. The amino-phospholipids are localized primarily on the inner surface of the membrane and the choline phospholipids are localized to a large extent on the outer surface of the membrane. Evidence is presented based on the use of covalent chemical probes in sequence that the red cell membrane contains heterogeneous domains of PE and PS and that the transport systems for Pi and K⁺ are asymmetrically arranged. Certain amino groups of PE, PS, and/or protein localized on the outer membrane surface are involved in Pi transport and certain amino groups of PE, PS, and/or protein localized on the inner surface of the membrane are involved in K⁺ transport. Cross-linking studies with DFDNB show that the cross-linked PE-PE molecules are rich in plasmalogens. This suggests that clusters of plasmalogen forms of PE occur in the membrane. Both PE and PS are cross-linked to membrane protein. These PE and PS molecules contain 24–28% 16:0 and 18:0 fatty acids and 12% fatty aldehydes. PE and PS molecules are cross-linked to a spectrin-rich fraction. It is proposed that the binding of spectrin to membrane PE and PS may help anchor spectrin to the inner surface of the membrane and regulate shape changes in the cell. K⁺-valinomycin forms a complex with TNBS and converts it from a non-penetrating proble to a penetrating probe. Valinomycin enhances K⁺ leak and Pi leak in the red cells. SITS inhibits completely the valinomycin-induced Pi leak and inhibits partially the valinomycin induced K⁺ leak. Valinomycin and IAA have additive effects on Pi leak. Ouabin has no effect on basal or valino-mycin-induced Pi leak. These data suggest that Pi leak and K⁺ leak occur by separate transport systems. In summary, the amino-phospholipids in the red cell membrane are asymmetrically arranged; some occur in clusters and some are closely associated with membrane proteins. Amino-phospholipids also are believed to bind spectrin to the inner surface of the membrane and also may play a role in cation and anion leak.     

Bilayer orientation of membrane-bound NH2 groups across microsomal vesicles and their role in the function of gastric K+-stimulated adenosine triphosphatase

The transversal distribution of the free NH₂ groups associated with phosphatidyl ethanolamine and the intrinsic membrane proteins of the purified pig gastric microsomes was quantitated and their relations to the function of the gastric K⁺-stimulated ATPase was investigated. Three different chemical probes such as 2,4,6-trinitrobenzene sulfonic acid (TNBS), 1-fluoro-2,4-dinitrobenzene (FDNB), and 2-methoxy-2,4-diphenyl-3(2H)-furanone (MDPF) were used for the study. The structure-function relationship of the membrane NH₂ groups was studied after modification with the probes under various conditions and relating the inhibition of the K⁺-stimulated ATPase to the ATPase-dependent H⁺ accumulation by the gastric microsomal vesicles. TNBS (2 mm) inhibits nearly completely the K⁺-stimulated ATPase and the vesicular dye accumulation, both in presence and absence of valinomycin plus K⁺. Both the K⁺-ATPase and dye uptake were largely (about 50%) protected against TNBS inhibition if the treatment with TNBS was carried out in presence of 2 mm ATP. TNBS and FDNB labeled 70% of the total microsomal PE; the intra- and extravesicular orientation being 48 and 22%, respectively. The presence or absence of ATP did not have any effect on the TNBS labeling of microsomal PE. ATP, however, significantly (P < 0.05) reduced the labeling of protein-bound NH₂ groups of gastric microsomes by TNBS. The intra- and extravesicular orientation of the protein NH₂ groups were 60 and 40%, respectively. Eighteen percent of the total protein-NH₂ appeared to be associated with the K⁺-stimulated ATPase; the rest being associated with non-ATPase proteins of the microsomes. About half (50%) of the total free NH₂ groups of the K⁺-stimulated ATPase were exposed to the vesicle exterior and were found to play critical roles in gastric ATPase function. The generation of florescence after MDPF conjugation of gastric microsomes was largely (50%) inhibited by ATP. ATP also protected completely the MDPF inhibition of gastric K⁺-stimulated ATPase and dye uptake.     

The effect of imidoesters,fluorodinitrobenzene and trinitrobenzenesulfonate on ion transport in human erythrocytes

Several amino-reactive chemical probes which differ in hydrophobicity and charge and in their ability to penetrate the red cell membrane were tested for their ability to modify K⁺ leak and inorganic phosphate (Pi) leak in intact human red cells. Methyl picolinimidate (MP), ethyl acetimidate (EA), methyl acetimidate (MA) are hydrophilic penetrating probes whereas isethionylacetimidate (IA) is a hydrophilic non-penetrating probe. The order of their effectiveness in inhibiting Pi leak was found to be MP>EA>MA>IA. This order is in decreasing hydrophobicity and suggests that some penetration into the bilayer or into hydrophobic domains of the anion transport protein is required to modify an amino group required for Pi permeability through the membrane. These imidoesters have little or no effect on K⁺ leak in the red cell.Trinitrobenzenesulfonate (TNBS) a relatively non-penetrating hydrophobic anionic probe and fluorodinitrobenzene (FDNB) a penetrating hydrophobic neutral probe have markedly different effects on K⁺ and Pi leak. TNBS has little effect on K⁺ leak but markedly inhibits Pi leak. The effect of TNBS on Pi leak is not blocked by prior treatment with IA suggesting that these probes sense different populations of amino groups in the membrane. FDNB nearly completely blocks Pi leak and markedly increases K⁺ leak. The results with TNBS and FDNB indicate an asymmetric arrangement of amino groups on the red cell membrane. Certain amino groups on the outer surface of the membrane regulate Pi permeability whereas certain amino groups on the inner surface of the membrane regulate K⁺ permeabilty. The data also suggest that these amino groups are in a hydrophobic domain.     

The reaction of chemical probes with the erythrocyte membrane

Summary Trinitrobenzenesulfonate (TNBS), fluorodinitrobenzene (FDNB) and suberimidate have been reacted with intact human erythrocytes. TNBS does not penetrate the cell membrane significantly at 23 °C in bicarbonate-NaCl buffer, pH 8.6, as estimated by the labeling of the N-terminal valine of hemoglobin. Hence, under these conditions it can be used as a vectorial probe. However, at 37 °C, especially in phosphate buffer, at pH 8.6, TNBS does penetrate the cell membrane. FDNB and suberimidate both penetrate the erythrocyte membrane. The time course reaction of TNBS with intact erythrocytes over a 24-hr period at 23 °C is complex and shows transition zones for both membrane phosphatidylethanolamine (PE) and membrane proteins. No significant cell lysis occurs up to 10 hr. The fraction of total PE or phosphatidylserine (PS) which reacts with TNBS by this time period can be considered to be located on the outer surface of the cell membrane. Under these conditions it can be shown that 10 to 20% of the total PE and no PS is located on the outer surface of the membrane and hence these amino phospholipids are asymmetrically arranged. The pH gradient between the inside and outside of the cell in our system is 0.4 pH units. Nigericin has no effect on the extent of labeling of PE or PS by TNBS. Isotonic sucrose gives a slight enhancement of the labeling of PE by TNBS. Hence, the inability of PE and PS to react with the TNBS is considered not due to the inside of the cell having a lower pH. The extent of reaction of TNBS with PE is not influenced by changing the osmolarity of the medium or by treatment of cells with pronase, trypsin, phospholipase A or phospholipase D. However, bovine serum albumin (BSA) does protect some of the PE molecules from reacting with TNBS.Cells treated with suberimidate were suspended in either isotonic NaCl or in distilled water. In both cases the suberimidate-treated cells became refractory to hypotonic lysis. Pretreatment of cells with TNBS did not prevent them from interacting with suberimidate and becoming refractory to lysis. However, pretreatment of cells with the penetrating probe FDNB abolished the suberimidate, effect. Electron-microscopic analysis of the cells showed a continuous membrane in the case of cells suspended in isotonic saline. The cells suspended in water did not lyse but their membranes had many large holes, sufficient to let the hemoglobin leak out. Since the hemoglobin did not leak out we know that the hemoglobin is cross-linked into a large supramolecular aggregate.     

Interaction of manganese (II) with valinomycin: observation of mixed complexes

The interaction of antibiotic valinomycin with manganese (II) has been studied using circular dichroism, electron spin resonance and infrared techniques. Results show that Mn(II) forms complexes with valinomycin in both 2:1 (valinomycin-ion-valinomycin sandwich) and 1:1 (equimolar) stoichiometries. The 1:1 type observed here is very different from the well known K⁺-valinomycin bracelet conformation.     

The reaction of chemical probes with the erythrocyte membrane.

Trinitrobenzenesulfonate (TNBS), fluorodinitrobenzene (FDNB) and suberimidate have been reacted with intact human erythrocytes. TNBS does not penetrate the cell membrane significantly at 23 degrees C in bicarbonate-NaCl buffer, pH 8.6, as estimated by the labeling of the N-terminal valine of hemoglobin. Hence, under these conditions it can be used as a vectorial probe. However, at 37 degrees C, especially in phosphate buffer, at pH 8.6, TNBS does penetrate the cell membrane. FDNB and suberimidate both penetrate the erythrocyte membrane. The time course reaction of TNBS with intact erythrocytes over a 24-hr period at 23 degrees C is complex and shows transition zones for both membrane phosphatidylethanolamine (PE) and membrane proteins. No significant cell lysis occurs up to 10 hr. The fraction of total PE or phosphatidylserine (PS) which reacts with TNBS by this time period can be considered to be located on the outer surface of the cell membrane. Under these conditions it can be located on the outer surface of the cell membrane. Under these conditions it can be shown that 10 to 20% of the total PE and no PS is located on the outer surface of the membrane and hence these amino phospholipids are asymmetrically arranged. The pH gradient between the inside and outside of the cell in our system is 0.4 pH units. Nigericin has no effect on the extent of labeling of PE or PS by TNBS. Isotonic sucrose gives a slight enhancement of the labeling of PE by TNBS. Hence, the inability of PE and PS to react with the TNBS is considered not due to the inside of the cell having a lower pH. The extent of reaction of TNBS with PE is not influenced by changing the osmolarity of the medium or by treatment of cells with pronase, trypsin, phospholipase A or phospholipase D. However, bovine serum albumin (BSA) does protect some of the PE molecules from reacting with TNBS. Cels treated with suberimidate were suspended in either isotonic NaCl or in distilled water. In both cases the suberimidate-treated cells became refractory to hypotonic lysis. Pretreatment of cells with TNBS did not prevent them from interacting with suberimidate and becoming refractory to lysis. However, pretreatment of cells with the penetrating probe FDNB abolished the suberimidate effect. Electron-microscopic analysis of the cells showed a continuous membrane in the case of cells suspended in isotonic saline. The cells suspended in water did not lyse but their membranes had many large holes, sufficient to let the hemoglobin leak out. Since the hemoglobin did not leak out we know that the hemoglobin is cross-linked into a large supramolecular aggregate.     

Retardation of electron donation to Photosystem I in aged cyanobacteria and its reversal by metal cations

The dark reduction of photooxidized P-700 in the cyanobacterium Anacystis nidulans becomes slower as a consequence of aging. In cells, of which the envelope has been enzymatically permeabilized to electrolytes, the reduction of P-700 by endogenous electron donors is accelerated by KCl plus valinomycin, but not by KCl alone. The K⁺-valinomycin system is ineffective, however, in the case of aged but unpermeabilized cells. These results suggest that a consequence of aging in Anacystis is an increase in the negative electric potential at the inner thylakoid surface, which makes electron donation to P-700 by acidic donors (cytochrome c-553 and plastocyanin) less probable. This situation is reversed by the permeant K⁺-valinomycin system, which suppresses the inner surface potential and collapses the inside-outside potential difference, but not by K⁺ alone, since the thylakoid membrane is impermeable to it.     

Differential reaction of cell membrane phospholipids and proteins with chemical probes.

The major aims of this study were to determine the degree of phospholipid asymmetry and the neighbor analysis of phospholipids in different types of cell membranes. For this study a penetrating probe (FDNB), a non-penetrating probe (TNBS) and a cross-linking probe (DFDNB) were used. The reaction of hemoglobin, membrane protein and membrane PE and PS of erythrocytes with DFNB and TNBS was studied over a concentration range of 0.5 to 10 mM probe. TNBS reacts to an extremely small extend with hemoglobin over the concentration range 0.4 to 4 mM whereas FDNB reacts with hemoglobin to a very large extent (50 fold more than TNBS). The reaction of membrane protein of intact erythrocytes reaches a sharp plateau at 1 mM TNBS whereas the reaction of membrane protein goes to a much larger extent with FDNB with no plateau seen up to 4 mM FDNB. This data shows that TNBS does not significantly penetrate into the cell under our conditions whereas FDNB does penetrate into the cell. The results show that there are four fold more reactive sites on proteins localized on the inner surface of the erythrocyte membrane as compared to the outer surface. TNBS at 0.5 to 2 mM concentration does not label membrane PS and labels membrane PE to a small extent. The reaction of PE with TNBS shows an initial plateau at 2 mM probe and a second slightly higher plateau between 4 to 10 mM probe. TNBS from 0.5-2.0 mM does not react with PS, but between 3 to 10 mM concentration, a very small amount of PS reacts with TNBS. Hence above 2 mM TNBS or FDNB a perturbation occurs in the membrane such that more PE and PS are exposed and react with these probes. These results demonstrate that essentially no PS is localized on the outer surface of the membrane and only 5% of the total membrane PE is localized on the outer surface of the erythrocyte membrane. TNBS and FDNB were reacted with yeast, E. coli, and Acholeplasma cells. With yeast cells, FDNB reacts to a much larger extent with PE than does TNBS, indicating that FDNB penetrates into the cell and labels more PE molecules. With E. coli, but not with erythrocytes or yeast cells, phospholipase A activity was very pronounced at pH 8.5 giving rise to a large amount of DNP-GPE from DNP-PE. A phosphodiesterase was also present which hydrolyized DNP-GPE to DNP-ethanolamine. The multilayered structure of the E. coli cell envelop did not permit a definitive interpretation of the results. It is clear, however, that TNBS and FDNB react to a different extent with PE in this cell. The Acholeplasma membrane had no detectable PE or PS but contains amino acid esters of phosphatidylglycerol. The reaction of these components with TNBS and FDNB indicate that these aminoacyl-PG are localized on both surfaces of the membrane, with 31% being on the outer surface and 69% on the inner surface...     

Neurite formation and membrane changes of mouse neuroblastoma cells induced by valinomycin

A clonal cell line of mouse neuroblastoma cells was found to undergo morphological differentiation in the presence of a K⁺ ionophore, valinomycin, in the assay medium. This effect was blocked by increasing the concentration of KCl of the medium, suggesting that the changes in resting membrane potential and ion fluxes may be involved in the mechanism of the formation of neurites. No enhancement of the neurite formation was observed in salines containing high concentrations of KCl in the absence of valinomycin. Depolarizing agents including veratridine, gramicidin and ouabain did not stimulate the outgrowth of neurites. Neither electrophoretic mobility of the cells nor molecular anisotropy of fluorescence probes in the membranes was modified by the treatment of valinomycin. Instead, it modified the slow binding phase in kinetics of the interaction of 1-anilinonaphthalene-8-sulfonate (ANS) with the cells, which is related to the penetration process of the probe into membranes. Valinomycin also enhanced the fluorescence intensity of ANS by increasing the binding sites in neuroblastoma cells.     

Use of 1-anilino-8-naphthalene-sulfonate as a probe of gastric vesicle transport

Summary The interaction of 1-anilino-8-naphthalene-sulfonate (ANS) with vesicles derived from hog fundic mucosa was studied in the presence of valinomycin and with the addition of ATP. Evidence was found for two classes of sites, those rapidly accessible to ANS with aK _D of 7.5 m and those slowly accessible, but rapidly accessed in the presence of valinomycin with aK _D of 2.5 m. ATP transiently increases the quantum yield of the latter ANS binding sites only in the presence of valinomycin, but does not alter the number ofK _D of those sites. The time course of this increase correlates with H⁺ uptake and Rb⁺ extrusion by those vesicles and H⁺ carriers such as tetrachlorsalicylanilide or nigericin abolish the ATP response. With ATP addition in the presence of SC¹⁴N and valinomycin there is transient uptake of SCN^–. It is concluded that ANS is acting as a probe of a structural change dependent on a potential and H⁺ gradient.     

The effect of surface charge density on valinomycin-K+ complex formation in model membranes

The model membrane approach was used to investigate the surface charge effect on the ion-antibiotic complexation process. Mixed monolayers of valinomycin and lipids were spread on subphases containing K⁺ or Na⁺. The surface charge density was modified by spreading ionizable valinomycin analogs on aqueous subphases of different pH or by changing the nature of the lipid (neutral, negatively charged) in the mixed film. Surface pressure and surface potential measurements demonstrated that a neutral lipid (phosphatidylcholine) or positively charged valinomycin analogs didn't enhance the antibiotic complexing capacity. However, a maximal complexation is reached for a critical lipid concentration in the valinomycin-phosphatidylserine mixed film. The role of the surface charge on the valinomycin complexing properties was examined in terms of the Gouy-Chapman theory. As a consequence of the negative charge of the lipid monolayer, the K⁺ concentration near the surface is larger than the bulk concentration, by a Boltzmann factor. A good agreement was observed between the experimental results and the theoretical predictions. Conductance measurements of asymmetric bilayers containing a neutral lipid (egg lecithin) on one side and a negatively charged lipid (phosphatidylserine) on the other, confirm the role of the surface charge. Indeed, addition of K⁺ to the neutral side of the bilayer containing valinomycin had no effect on the conductance whereas addition of K⁺ to the charged side of the bilayer caused a 80-fold conductance increase.     

Quantitation of corneal endothelial potentials using a carbocyanine dye

The carbocyanine dye, diS-C₃-(5) was used to quantitate the plasma membrane potential of the bullfrog corneal endothelium. It was shown that valinomycin hyperpolarized the endothelial cell and that in the presence of the ionophore the membrane potential largely reflected the K⁺ equilibrium potential. Using calibration curves constructed by changing medium K⁺ concentration in the presence of valinomycin, and nigericin and ouabain to abolish ion gradients and electrogenic pump activity, the cell membrane potential was calculated to be 28.6 ± 4.2 mV. The major source of this potential was a K⁺ diffusion potential, and the membrane Na⁺ conductance reduced the cell potential to less than the apparent K⁺ equilibrium potential of 51.5 ± 5.1 mV. About 20% of the cell potential could be ascribed to the rheogenic (Na⁺+K⁺)-ATPase.     

Chemical Modification of Membranes : 1. Effects of sulfhydryl and amino reactive reagents on anion and cation permeability of the human red blood cell

Four different amino-reactive reagents, 4-acetamido-4'-isothiocyano-stilbene-2,2'-disulfonic acid (SITS),¹ 1-fluoro-2,4-dinitrobenzene (FDNB), 2,4,6-trinitrobenzene sulfonic acid (TNBS), and 2-methoxy-5-nitrotropone (MNT) decrease the anion permeability of the human red blood cell, as measured by sulfate fluxes, whereas the sulfhydryl agent, parachloromercuriphenyl sulfonic acid (PCMBS), does not. In contrast, PCMBS increases the cation permeability as measured by K⁺ leakage, whereas SITS does not. Of the other agents, FDNB increases the cation permeability to the same extent as PCMBS but MNT and TNBS produce smaller increases. PCMBS does not protect against FDNB as it does against other sulfhydryl agents (X-irradiation) and the FDNB effect on cations is attributed to amino groups. Studies of the binding of SITS indicate that it does not penetrate into the membrane and its failure to influence cation permeability is attributed to its inability to reach an internal population of amino groups. It is concluded that two ion permeability barriers, both involving proteins, are present in the red blood cell. The more superficial barrier contains amino groups and controls anion flow; the more internal barrier contains sulfhydryl and amino groups and controls cation flow. The amino groups contribute to the control of permeability by virtue of their positive charges, but the role of sulfhydryl groups is not clear. Only a small fraction of the membrane protein amino and sulfhydryl is involved in the barriers.     

The influence of electrochemical gradients of Na+ and K+ upon the membrane binding and pore forming activity of the terminal complement proteins

Summary The hemolytic activity of the terminal complement proteins (C5b-9) towards erythrocytes containing high potassium concentration has been reported to be dramatically increased when extracellular Na⁺ is substituted isotonically by K⁺ (Dalmasso, A.P., et al., 1975,J. Immunol. 115:63–68). This phenomenon was now further investigated using resealed human erythrocyte ghosts (ghosts), which can be maintained at a nonlytic osmotic steady state subsequent to C5b-9 binding: (1) The functional state of C5b-9-treated ghosts was studied from their ability to retain trapped [¹⁴C]-sucrose or [³H]-inulin when suspended either in the presence of Na⁺ or K⁺. A dramatic increase in the permeability of the ghost membrane to both nonelectrolytes-in the absence of significant hemoglobin release-was observed for C5b-9 assembly in the presence of external K⁺. (2) The physical binding of the individual¹²⁵I-labeled terminal complement proteins to ghost membranes was directly measured as a function of intra- and extracellular K⁺ and Na⁺. The uptake of¹²⁵I-C7,¹²⁵I-C8, and¹²⁵I-C9 into membrane C5b-9 was unaltered by substitution of Na⁺ by K⁺. (3) The binding of the terminal complement proteins to ghosts subjected to a transient membrane potential generated by the K⁺-ionophore valinomycin (in the presence of K⁺ concentration gradients) was measured. No significant change in membrane binding of any of the C5b-9 proteins was detected under the influence of both depolarizing and hyperpolarizing membrane potentials. It can be concluded that the differential effect of Na⁺ versus K⁺ upon the erythrocyte membrane isnot due to an effect upon the binding of the complement proteins to the membraneper se, but upon the functional properties of the assembled C5b-9 pore site.     

Optical study of active ion transport in lipid vesicles containing reconstituted Na,K-ATPase

Summary A fluorescence method is described for the measurement of ATP-driven ion fluxes in lipid vesicles containing purified Na,K-ATPase. The membrane voltage of enzyme containing vesicles was measured by using a voltage-sensitive indocyanine dye. By addition of valinomycin the vesicle membrane is made selectively permeable to K⁺ so that the membrane voltage approaches the Nernst potential for K⁺. With constant external K⁺ concentration, the time course of internal K⁺ concentration can be continuously measured as change of the fluorescence signal after activation of the pump. The optical method has a higher time resolution than tracer-flux experiments and allows an accurate determination of initial flux rates. From the temperature dependence of active K⁺ transport its activation energy was determined to be 115 kJ/mol. ATP-stimulated electrogenic pumping can be measured as a fast fluorescence change when the membrane conductance is low (i.e., at low or zero valinomycin concentration). In accordance with expectation, the amplitude of the fast signal change increases with decreasing passive ion permeability of the vesicle membrane. The resolution of the charge movement is so high that a few pump turnovers can be easily detected.     

Effects of valinomycin on lymphocytes independent of potassium permeability

10^?7 M valinomycin affects human lymphocytes in the following manner: (1) it is non-toxic; (2) it inhibits mitogenesis; (3) it causes a reduction in cell ATP; and (4) it causes a marked increase in steady-state Na⁺ exchange. However, it has a minimal effect on cell ion (K⁺, Na⁺, Ca²⁺, Mg²⁺) contents and no effect whatever on K⁺ exchange. Neither the fast nor the slow fraction of steady-state K⁺ exchange is affected by 10^?7 M valinomycin. The various reported effects of valinomycin on lymphocyte functions cannot be assumed to be due to changes in plasma membrane K⁺ permeability. The mechanism of the increase in steady-state Na⁺ exchange, and whether or not it is related to inhibition of mitogenesis, are unsettled issues.     

Valinomycin pulse-induced phosphorylation of ADP in dark anaerobic cells of the cyanobacteriumAnacystis nidulans

Addition of valinomycin to dark anaerobic suspensions ofAnacystis nidulans resulted in a transient hyperpolarization of the electrical potential across the cell membrane ( _CM) and seen from anilinonaphthalenesulfonate (ANS) fluorescence quenching and from distribution ratios of³H-tetraphenylphosphonium (TPP⁺) and¹⁴C-thiocyanate (SCN^–). At the same time a similar transient increase of intracellular ATP levels was observed, which was paralleled by decreasing ADP levels and eliminated by the uncoupler carbonyl cyanide m-chlorophenylhydrazone (CCCP) and the F₀F₁-ATPase inhibitors dicyclohexylcarbodiimide (DCCD) and 7-chloro-4-nitrobenz-2-oxa-1,3-diazole (NBD), and in the presence of K⁺ in the medium. Since the steady-state concentration of K⁺ in dark anaerobic cells was around 150 mM, it is concluded that a valinomycin-induced K⁺ diffusion potential across the cell membrane can serve as an energy source for ATP synthesis by a reversible H⁺-ATPase present in the membrane.     

Mechanism of ion transport through lipid bilayer-membranes mediated by peptide cyclo-(d-Val-l-Pro-l-Val-d-Pro)3

The cyclic dodecapeptide PV, cyclo-(d-Val-l-Pro-l-Val-d-Pro)₃, a structural analogue of the ion-carier valinomycin, increase the cation permeability of lipid bilayer membranes. This paper reports the results of two types of relaxation experiments, namely relaxation of the membrane current after a voltage jump and decay of the membrane voltage after a charge pulse in lipid bilayer membranes exposed to PV. From the relaxation data, the rate constant for the translocation of the ion carrier complex across the membrane, as well as the partition coefficient of the complex between water and membrane solution interface were computed and found to be about one order of magnitude less than the comparable values for valinomycin (Val). Furthermore, the dependence of the initial membrane conductivity on ion concentration was used to evaluate the equilibrium constant, K, of complexation between PV and some monovalent cations in water. The values of K yield the following selectivity sequence of PV: Na⁺ < NH₄⁺ < K⁺ < Cs⁺ < Rb⁺. These and earlier results are consistent with the idea that PV promotes cation movement across membranes by the solution complexation mechanism which involves complexation between ion and carrier in the aqueous phase and transport of the carrier across the membrane. In the particular form of the solution complexation mechanism operating here, the PV present in the PV-cation complex carrying charge across the membrane derives from the side from which the current is flowing (cis-mechanism). As shown previously, valinomycin, in contrast to PV, acts by an interfacial complexation mechanism in which the Val in the Val-cation complex derives from the side toward which current is flowing (trans-mechanims). The comparison of the kinetic properties of these two closely related compounds yields interesting insights into the relationship between chemical structure and function of ion carriers.     

RAPID EFFECTS OF VERATRIDINE, TETRODOTOXIN, GRAMICIDIN D, VALINOMYCIN AND NaCN ON THE NA+, K+ AND ATP CONTENTS OF SYNAPTOSOMES

Abstract— The effects of brief exposures of a number of depolarizing agents on ²⁴Na⁺ influx and on the Na⁺, K⁺ and ATP contents of synaptosomes were studied using a Millipore filtration technique to terminate the reaction. When synaptosomes were incubated in normal medium, there was a rapid influx of ²⁴Na⁺ and a gain in Na’contents; neither the ²⁴Na⁺ influx nor the Na⁺ gain were blocked by tetrodotoxin suggesting that this Na⁺ entry did not involve Na⁺-channels. Veratridine markedly increased the rate of ²⁴Na⁺ influx into synaptosomes and also increased the Na⁺ content and decreased the K⁺ content of synaptosomes within the first 10s of exposure. The normal ion contents were reversed by 1 min. The effects of veratridine on Na⁺ influx and on synaptosomal ion contents were prevented by tetrodotoxin and required Na⁺ in the medium. The ionophores gramicidin D and valinomycin also rapidly reversed the Na⁺ and K⁺ contents of synaptosomes, but these effects could not be blocked by tetrodotoxin. The reducing effect of gramicidin D on synaptosomal K⁺ content required Na’in the medium, whereas valinomycin caused a fall in the K⁺ content of synaptosomes in a Na⁺-free medium. Veratridine and gramicidin D, at concentrations known to reverse the synaptosomal ion contents, did not affect synaptosomal ATP levels. In contrast, valinomycin and NaCN caused an abrupt fall in synaptosomal ATP levels. The above findings suggest that veratridine quickly alters synaptosomal Na⁺ and K⁺ contents by opening Na ⁺-channels in the presynaptic membrane, and provide direct evidence for the existence of Na⁺-channels in synaptosomes. In contrast, gramicidin D and valinomycin appear to act independently of Na ⁺-channels, possibly by their ionophoric effects and, in the case of valinomycin, by diminishing synaptosomal ATP contents and hence diminishing Na⁺-pump activity. The rapid reversals of Na⁺ and K⁺ contents by these drugs could affect the resting membrane potentials, Na⁺-Ca²⁺ exchange across the synaptosomal membrane, and the release, synthesis and uptake of neurotransmitters by synaptosomes.