[Transport of large organic ions through syringomycin channels in the membranes containing dipole modifiers].

The effect of the membrane dipole potential (Phid) on a conductance and a steady-state number of functioning channels formed by cyclic lipodepsipeptide syringomycin E (SRE) in bilayer lipid membranes made from phosphocholine and bathed in 0.4 M solution of sodium salts of aspartate, gluconate and chloride was shown. The magnitude of Phid was varied with the introduction to membrane bathing solutions of phloretin, which reduces the Phid, and RH 421, increasing the Phid. It was established that in all studied systems the increase in the membrane dipole potential cause a decrease in the steady-state number of open channels. In the systems containing sodium salts of aspartate (Asp) or gluconate (Glc), changes in the number of functioning channels are in an order of magnitude smaller than in systems containing sodium chloride. At the same time, the conductance (g) of single SRE-channels on the membranes bathed in NaCI solution increases with the increase in Phid, and in the systems containing NaAsp or NaGlc the conductance of single channels does not depend on the Phid. The latter is due to the lack of cation/anion selectivity of the SRE-channels in these systems. The different channel-forming activity of SRE in the experimental systems is defined by the gating charge of the channel and the partition coefficient of the dipole modifiers between the lipid and aqueous phases.

Voltage-dependent synchronization of gating of syringomycin E ion channels.

Antifungal lipodepsipeptide syringomycin E (SRE) forms two major conductive states in lipid bilayers: "small" and "large". Large SRE channels are cluster of several small ones, demonstrating synchronous opening and closure. To get insight into the mechanism of such synchronization we investigated how transmembrane potential, membrane surface charge, and ionic strength affect the number of small SRE channels synchronously functioning in the cluster. Here, we report that the large SRE channels can be presented as 3-8 simultaneously gating small channels. The increase in the absolute value of the transmembrane potential (from 50 to 200 mV) decreases the number of synchronously gated channels in the clusters. Voltage-dependence of channel synchronization was influenced by the ionic strength of the bathing solution, but not by membrane surface charge. We propose a mechanism for the voltage-dependent cluster behavior that involves a voltage-induced reorientation of lipid dipoles associated with the channel pores.

[Kinetic parameters of single ion channels and stationary conductivities of phytotoxin modified lipid bilayers].

As shown earlier, phytotoxins produced by Pseudomonas syringae pv. syringae form ion channels of "small" and "large" conductance when incorporated into planar lipid membranes. The multilevel conductance is due to cluster organization of the channels (Kaulin et al., 1998; Gurnev et al., 2002). In this study the kinetic parameters of syringomycin E (SRE) and syringostatin A (SSA) channels in negatively charged bilayer lipid membranes were estimated. The average time of open state of the small channels (t(s)(open)) did not depend on transmembrane voltage (in the range of +/- 200 mV). The channel characteristics differed between two phytotoxins: the t(s)(open) for the SRE-channels was much larger than that for SSA-channels. An energetic diagram with two non-conducting states illustrating the formation of the small channel is proposed to explain the voltage independence of the kinetic parameters. The probability for synchronous functioning of small channels with SSA was higher than that with SRE. To analyse the role of the clusters in the biological activities of SRE and SSA, we estimated the cluster contribution to a net transmembrane currents to be 60 and 90%, respectively.

[Interaction between filamentous actin and lipid bilayer causes the increase of syringomycin E channel-forming activity]. / Vzaimodeistvie fibrilliarnogo aktina s lipidnym bisloem vyzyvaet uvelichenie kanaloformennoi aktivnosti siringomitsina E.

The effect of filamentous (F) actin on the channel-forming activity of syringomycin E (SRE) in negatively charged and uncharged bilayer lipid membranes (BLM) was studied. F-actin did not affect the membrane conductance in the absence of SRE. No changes in SRE-induced membrane conductance were observed when the above agents were added to the same side of BLM. However, the opposite side addition of F-actin and SRE provokes a multiple increase in membrane conductance. The similar voltage dependence of membrane conductance, equal values of single channel conductance and the effective gating charge of the channels upon F-actin action suggests that the actin-dependent increase in BLM conductance may result from an increase in the number of opened SRE-channels. BLM conductance kinetics depends on the sequence of SRE and F-actin addition, suggesting that actin-dependent rise of conductance may be induced by BLM structural changes that follow F-actin adsorption. F-actin exerted similar effect on membrane conductance of both negatively charged and uncharged bilayers, as well as on conductance of BLM with high ionic strength bathing solution, suggesting the major role for hydrophobic interactions in F-actin adsorption on lipid bilayer.

[Activity of toxins produced by Pseudomonas syringae pv. syringae in model and cell membranes]. / Aktivnost' toksinov, produtsiruemykh bacteriiami Pseudomonas syringae pv. syringae, v model'nykh i kletochnykh membranakh.

We studied effects of toxins produced by a bacterium Pseudomonas syringae pv. syringae on the conductance of bilayer lipid membranes (BLM). The used toxins were as follows: syringopeptin 22A (SP22A), syringomycin E (SPE), syringostatin A (SSA), syringotoxin B (STB), and methylated syringomycin E (CH3-SRE). All toxins demonstrated channel-forming activity. The threshold sequence for toxin activity was SP22A > SRE approximately equal to SSA > STB > CH3-SRE, and this sequence was independent of lipid membrane composition, and NaCl concentration (pH 6) in the membrane bathing solution (in the range of 0.1-1.0 M). This sequence correlated with relative bioactivities of toxins. In addition, SRE demonstrated a more potent antifungal activity than CH3-SRE. These findings suggest that ion channel formation may underlie the bioactivities of the above toxins. The properties of single ion channels formed by the toxins in BLMs were found to be similar, which points to the similarity in the channel structures. In negatively charged membranes, bathed with diluted electrolyte solutions (0.1 M NaCl), the channels were seen to open with positive transmembrane potentials (V) (from the side of toxin addition), and close with negative potentials. In uncharged membranes the opposite response to a voltage sign was observed. Increasing the NaCl concentration up to 1 M unified the voltage sensitivity of channels in charged and uncharged membranes: channels opened with negative V, and closed with positive V. With all systems, the voltage current curves of single channels were similarly superlinear in the applied voltage and asymmetric in its sign. It was found that the single channel conductance of STB and SSA was higher than that of other toxin channels. All the toxins formed at least two types of ion channels that were multiple by a factor of either 6 or 4 in their conductance. The results are discussed in terms of the structural features of toxin molecules.

Kinetics of opening and closure of syringomycin E channels formed in lipid bilayers.

A cyclic lipodepsipeptide, syringomycin E (SME), incorporated into planar lipid membranes forms two types of channels ("small" and "large") different in their conductance by approximately a factor of six (Biophys. J. 74:2918-2925 (1998)). We analysed the dynamics of the SME-induced transmembrane current under voltage-clamp conditions to clarify the mechanisms of formation of these channels. The voltage-dependent opening/closure of SME channels in lipid bilayers are interpreted in terms of transitions between three types of clusters including 6-7 SME molecules and some lipid molecules. The initial cluster, the precursor of the other two, was in equilibrium with SME monomer molecules at the membrane surface. The other two types of clusters (State 1 and State 2) were formed from the precursor and also during their interconversions (the consecutive-parallel mechanism of transitions). State 1 was a non-conducting state in equilibrium with small channels, which partially determined the ionic conductance of lipid bilayers modified by SME. State 2 corresponded to large SME channels, major contributors to the conductance of a bilayer. The results of the theoretical analysis based on the chemical kinetics concepts were consistent with experimental observations. Such properties of the SME-induced channels as cluster organisation, voltage dependence and the existence of a non-conducting state are all features shared by many ion channels in biological membranes. This makes it possible to use SME channels as a model to study naturally occurring ion channels.

The role of actin cytoskeleton in the generation of surface oscillations of red blood cell ghosts.

We have studied the effects of three compounds on surface oscillations of human red blood cell ghosts: the P-ATPase inhibitor, suramin; the fluorescent dye of a similar structure, 1,8-anilinonaphthalene sulfonate (ANS); and subfragment 1 of skeletal muscle myosin (S1). It has been found that suramin (10 microM), ANS (100 microM) and S1 (2 mg/ml) suppress the surface oscillations reversibly. The shape of the ghosts remains unchanged. We have also found that suramin and ANS inhibit the ghosts' non-transport (presumably, F-actin-associated) ATPase. The results of the present study suggest the important role of actin ATPase in the generation of cell surface oscillations. The effect of S1, the protein which increases the torsional, but not the bending, rigidity of F-actin upon binding to filaments, favours the possibility that just the torsional dynamics of actin protofilaments leads to the observed oscillations of the ghosts' surface.

Correlation between the oscillatory and adhesion activities in erythroid cells.

The attachment kinetics of erythroid cells, such as human erythrocytes, their saponin ghosts, and erythroleukemic cells K562 to a glass surface has been studied in the presence of substances inhibiting spontaneous fluctuations of cell membranes. It has been shown that wheat germ agglutinin (WGA) slows down the attachment kinetics of K562 cells, as is the case in intact erythrocytes. Concanavalin A (Con A), which inhibits the attachment of erythrocytes to glass does not affect the adhesion of K562 cells to glass due to the absence of band 3 proteins in the membranes of K562 cells. Both lectins slow down the adhesion rate of saponin ghosts of human erythrocytes, as it takes place in intact erythrocytes. Suramin and the anionic dye ANS bind specifically to the actin protofilaments of the erythrocyte skeleton and also inhibit cell adhesion to glass. At the same time, these substances do not affect the oscillatory and adhesion activities of intact erythrocytes due to the impermeability of erythrocyte membranes for these drugs. The results obtained allow the conclusion that inhibition of erythrocyte adhesion by lectins is due to lectin binding to different constituents of the erythrocyte membrane--sialic acid moieties of glycophorin in the case of WGA and band 3 proteins in the case of Con A. The most probable mechanism of erythrocyte and K562 cell attachment to glass is the formation of the so-called local contacts between cells and the glass surface. It is also suggested that the cell surface oscillations facilitate the formation of cell contacts.

Cluster organization of ion channels formed by the antibiotic syringomycin E in bilayer lipid membranes.

The cyclic lipodepsipeptide, syringomycin E, when incorporated into planar lipid bilayer membranes, forms two types of channels (small and large) that are different in conductance by a factor of sixfold. To discriminate between a cluster organization-type channel structure and other possible different structures for the two channel types, their ionic selectivity and pore size were determined. Pore size was assessed using water-soluble polymers. Ion selectivity was found to be essentially the same for both the small and large channels. Their reversal (zero current) potentials with the sign corresponding to anionic selectivity did not differ by more than 3 mV at a twofold electrolyte gradient across the bilayer. Reduction in the single-channel conductance induced by poly(ethylene glycol)s of different molecular weights demonstrated that the aqueous pore sizes of the small and large channels did not differ by more than 2% and were close to 1 nm. Based on their virtually identical selectivity and size, we conclude that large syringomycin E channels are clusters of small ones exhibiting synchronous opening and closing.

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.

[The attachment of erythroid cells to solid supports in the presence of lectins]. / Prikreplenie éritroidnykh kletok k tverdym podlozhkam v prisutstvii lektinov.

A comparative influence of lectins on the attachment kinetics of erythroid cells (human erythrocytes and erythroleukemia cells K562) to glass formvar has been studied. It is shown that the inhibiting effect of wheat germ agglutinin (WGA) on the adhesion to glass is the same for both types of cells under study, whereas concanavalin A (Con-A) inhibits the erythrocyte adhesion to glass only but it is ineffective for adhesion of K562 cells. Plasmatic membranes of K562 cells are free from band 3 protein contrary to the erythrocyte ones. It is concluded that the inhibition of erythrocyte adhesion by lectins results from their binding to different components of cell membranes; sialic acid residues of glycophorin (WGA) or band 3 protein (Con-A). This conclusion is confirmed by the inhibiting effect of WGA towards attachment of cells K562 to glass and the absence of such an effect of Con-A towards the same cells which do not contain this protein. The most probable form of both cell type attachment to glass is the occurrence of so-called focal contacts. The latter can be easily observed in the case of K562 cells. The intact erythrocyte attachment to formvar occurs slower than to glass. At the same time, the above lectins accelerate the erythrocyte attachment to formvar.

Interfacial models of nerve fiber cytoskeleton.

A new approach, basing on a resemblance between cytoskeleton structures associated with plasma membranes and interfacial layers of coexisting phases, is proposed. In particular, a lattice model, similar to those of the theory of surface properties of pure liquids and nonelectrolyte solutions (Ono, S., and S. Kondo. 1960. Handbuch der Physik.), has been developed to describe nerve fiber cytoskeleton. The preliminary consideration of the model shows the existence of submembrane cytoskeleton having increased peripheral densities of microtubules (compared with the bulk density) which is in qualitative agreement with the data in literature. Some additional possibilities of the approach proposed are briefly discussed.

[Changes in the amount of 3H-thymidine label in hepatocytes of different ploidies in rat ontogeny after a single administration of the isotope]. / Izmenenie kolichestva 3H-timidinovoi metki v gepatotsitakh raznoi ploidnosti v ontogeneze krys posle odnokratnogo vvedeniia izotopa.

Change of 3H-thymidine quantity in mono- and binuclear rat hepatocytes of different ploidy was investigated during the first 6 weeks after a single injection of isotope to newborn rats. Rates of cell transitions (arbitrary number of cells in the time unit) from one ploidy class to another, and coefficients of the reducing of hepatocyte proliferative activity with increasing the hepatocyte ploidy were calculated on the basis of ideas about the process of autoradiographic label "diluting" in the course of the postnatal development as a result of polyploidization and ordinary mitotic divisions of hepatocytes. The calculated values are close to values of parameters, which were calculated with assistance of the model, which describes the process of polyploidization in the liver, on the basis of data on the change in the arbitrary number of different ploidy hepatocytes.

Thermodynamics, mechanical and electrical properties of biomembranes.

A set of thermodynamic fundamental equations has been derived, including chemical potentials of immobile components of a biomembrane. The results obtained are compatible with those known in the theory of shells, but the approach developed is more general. The influence of an outer electric field on the isotropic tension of a biomembrane has been discussed. The thermodynamic relations derived are used for the treatment of intracellular pressure changes recently observed by Terakawa (1985, J. Physiol. 369, 229) in the squid giant axon at potential variations.

Cooperative binding of primycin and gramicidin on erythrocyte membranes. A cation transport study.

In this paper the authors present a comparative study of the actions of the antibiotics primycin and gramicidin on the erythrocyte membrane permeability. It has been found that both antibiotics have a nonlinear effect on the membrane permeability. Above a threshold antibiotic concentration, which is characteristic of the type of the antibiotic, the cation permeability of the erythrocyte membranes increases sharply. In the range of nonlinearity the transport-kinetic curves level off before achieving the equilibrium radioactive ion distribution between the extra- and intracellular spaces. A stochastic model of the cooperative and aspecific incorporation of antibiotic molecules into the membrane explains the experimental findings. The authors conclude that membrane permeability increases at the places where two or more antibiotic molecules form aggregates in the membrane.

[Analysis of nerve fiber deformation during excitation]. / K analizu deformatsii nervnogo volokna pri vozbuzhdenii.

A description of the potential--dependent strains of the nerve fiber is considered as a problem of finding the velocity and pressure distributions in two liquid volumes which are divided by a thin cylindric shell. The isotropic shell equations were used as the boundary conditions for this problem. The strain amplitude predicted is near to the observed one, but the strain dynamics in the model discussed does not coincide with the one recorded under the experimental conditions.

[Effect of elastic properties of the crab axon sheath on the movement of nerve fibers at the action potential]. / Vliianie uprugikh svoistv obolochki aksona kraba na dvizhenie nervnogo volokna pri potentsiale deistviia.

The shear modulus (nu) of single giant axon of the crab Carcinus maenas was determined by measuring the axon elastic stretching up to 1-10%. The value obtained for nu (5-7 X 10(3) dn X cm) is more than that for sheaths of reptilian and mammalian red blood cells by 10(4)-10(6) times. Proteolysis of the axon sheath by pronase solution (2 mg/ml, 15-20 min) increases the amplitude of axon movement at the action potential by 8-10 times. It is suggested that the collagen fibers, Schwann's and connective cells are passive structures of the axon sheath, and that potential-depend axon movement at the action potential is due to deformation of the axolemma and submembrane layer.

[Effect of temperature on the interaction of gramicidin A and its dimer analog with the muscle fiber membrane]. / Vliianie temperatury na vzaimodeistvie gramitsitina A i ego dimernogo analoga s membranoi myshechnogo volokna.

Potassium conductance of single muscle fibres from Rana esculenta was studied in isotonic K2SO4 solution under constant current conditions using double sucrose gap method. At room temperature the channel formation by gramicidin was much faster than that of the synthetic head to head covalently linked gramicidin dimer. The increase of temperature by 8-10 degrees C resulted in a considerable rise of both dimer- and gramicidin-induced conductances. The effect was much greater than in the case of bilayers indicating a remarkable entropy change in the muscle fibre membrane. The temperature dependence of adsorption was more pronounced than that of desorption: there was no effect on desorption of dimer and only 20% of the temperature-activated desorption of gramicidin irreversibly bound at room temperature.