Tetrodotoxin-sensitive protein in the extracts from excitable tissues

The sodium permeability of liposomes preincubated with the soluble fraction of brain and heart muscle homogenates was increased veratrine. The veratrine increment was decreased by tetrodotoxin. The effect was specific for the extracts from excitable tissues. Bovine serum and soluble fraction of liver homogenate induced neither veratrine- nor tetrodotoxin-sensitivity of the liposomes. Treatment of the excitable tissue extracts by pronase and heat denaturation caused their complete inactivation. Tetrodotoxin-sensitive factor could be fractionated by ammonium sulfate precipitation and by DEAE-Servacel chromatography. On a column of Sephadex G-200 it was eluted with the void volume. It is suggested that the tetrodotoxin-sensitive factor is a protein which could be a soluble precursor of the voltage-dependent sodium channels.     

Interaction of tetrodotoxin-sensitive structures of soluble cardiac muscle proteins with liposomes

It is studied how conditions of soluble myocardium proteins interaction with liposomes provide formation of the channel-like structures with tetrodotoxin- and veratrine-dependent sodium permeability. The temperature is shown to influence the formation rate of neurotoxin-sensitive proteoliposomes. The veratrine effect on sodium permeability of proteoliposomes intensifies with the rise of temperature. Pretreatment of liposomes by veratrine prevents formation of tetrodotoxin sensitivity in proteoliposomes.     

Dependence of inhibition by levorin of amino acid incorporation into protoplasts and subcellular proteins of Candida albicans on the change of endocellular potassium concentration]

Levorin is found to decrease more efficiently potassium concentration in C. albicans protoplasts under their incubation in the presence of sodium than in the medium containing the equivalent amount of potassium. Minimal inhibitory concentration of levorin for resistant C. albicans cells incubated on potassium-depeleted medium was in 4 times lower than for cells incubated in potassium-enriched medium. The decrease of membrane permeability for 14C-amino acids and their incorporation into membrane, ribosomal and soluble proteins under the effect of levorin was more pronounced when protoplasts were cultivated in sodium-containing medium than in potassium-containing one. In both media the inhibition of 14C-amino acid incorporation by levorin into ribosomal and cytosol proteins was more efficient than into membrane proteins, but these differences were less pronounced in case of potassium-containing medium.     

Effects of local anesthetics on properties of tetrodotoxin-sensitive protein reconstituted into liposomes

The effects of some local anesthetics on properties of tetrodotoxin (TTX)-sensitive protein reconstituted into liposomes in such a manner that its TTX-sensitive center is located at the internal surface of the liposome membrane were studied. It was shown that tetracaine, lidocaine and its derivative QX-314 decreased the rate of efflux of radioactive sodium from the²²Na-preloaded proteoliposomes with the same efficiency as TTX acted from the inside of liposomes. The results confirm our earlier suggestion that TTX-sensitive protein is a soluble precursor of the protein forming voltage-dependent sodium channels.Neirofiziologiya/Neurophysiology, Vol. 27, No. 4, pp. 299–302, July–August, 1995.     

Reconstitution of respiratory oxidases in membrane nanodiscs for investigation of proton-coupled electron transfer

The function of membrane-bound transporters is commonly affected by the milieu of the hydrophobic, membrane-spanning part of the transmembrane protein. Consequently, functional studies of these proteins often involve incorporation into a native-like bilayer where the lipid components of the membrane can be controlled. The classical approach is to reconstitute the purified protein into liposomes. Even though the use of such liposomes is essential for studies of transmembrane transport processes in general, functional studies of the transporters themselves in liposomes suffer from several disadvantages. For example, transmembrane proteins can adopt two different orientations when reconstituted into liposomes, and one of these populations may be inaccessible to ligands, to changes in pH or ion concentration in the external solution. Furthermore, optical studies of proteins reconstituted in liposomes suffer from significant light scattering, which diminishes the signal-to-noise value of the measurements. One attractive approach to circumvent these problems is to use nanodiscs, which are phospholipid bilayers encircled by a stabilizing amphipathic helical membrane scaffold protein. These membrane nanodiscs are stable, soluble in aqueous solution without detergent and do not scatter light significantly. In the present study, we have developed a protocol for reconstitution of the aa(3)- and ba(3)-type cytochrome c oxidases into nanodiscs. Furthermore, we studied proton-coupled electron-transfer reactions in these enzymes with microsecond time resolution. The data show that the nanodisc membrane environment accelerates proton uptake in both oxidases.     

Frequency domain analysis of asymmetry current in squid axon membrane.

The change in capacity of squid axon membrane during hyper- and depolarizations was investigated in the absence of ionic currents after the membrane was treated with pronase. In the presence of the inactivation process (h parameter), failure to observe the gating current in the frequency domain was attributed to the rapid attenuation of the possible capacity change during depolarizations, which is likely to be due to the sodium activation process. Elimination of the h process would therefore enable us to observe the gating current in the frequency domain as the change in the capacitance component of membrane admittance. However, even after the inactivation process was abolished by pronase, the capacity of the axon membrane remained constant when ionic currents were blocked by external tetrodotoxin and internal Cs+ ion. Actually capacity was observed to decrease slightly with depolarization, contrary to the prediction based on the magnitude of gating currents.     

n-Alkanols potentiate sodium channel inactivation in squid giant axons.

The effects of n-octanol and n-decanol on nerve membrane sodium channels were examined in internally perfused, voltage-clamped squid giant axons. Both n-octanol and n-decanol almost completely eliminated the residual sodium conductance at the end of 8-ms voltage steps. In contrast, peak sodium conductance was only partially reduced. This block of peak and residual sodium conductance was very reversible and seen with both internal and external alkanol application. The differential sensitivity of peak and residual conductance to alkanol treatment was eliminated after internal pronase treatment, suggesting that n-octanol and n-decanol enhance the normal inactivation mechanism rather than directly blocking channels in a time-dependent manner.     

Na+-Ca2+ exchanger in the soluble fraction of crayfish striated muscle

Proteins with Na+-Ca2+ exchange activity from the soluble fraction of crayfish striated muscle were inserted into asolectin proteoliposomes. A pH dependent calcium uptake with an optimum at the alkaline side and inhibition in the presence of sodium or strontium ions in the external medium was observed. When expressed per tissue wet weight the capacity for Na+-Ca2+ exchange of proteoliposomes with inserted soluble proteins was by one half higher than that of the membrane fraction and more than twice higher in comparison with the reconstituted membrane bound exchanger. Using polyacrylamide gel electrophoresis two most prominent proteins with Mr over 200 and 43 kDa could be detected in proteoliposomes with the highest Na+-Ca2+ exchange. It is assumed that protein(s) with Mr 43 kDa could represent the soluble Na+-Ca2+ exchanger in crayfish striated muscle soluble fraction.     

Liposomes expressing IL 1 biological activity

We determined the activity of IL 1, obtained from various human monocyte subcellular compartments, when associated with liposomes. Soluble IL 1, bound to the outer surface of lyophilized liposomes, stimulated responsive target cells. However, this activity was not preserved when soluble IL 1 was incorporated into the inner chambers of classical liposomes. In contrast, monocyte plasma membranes that exhibited IL 1 activity had the same level of activity when presented on lyophilized liposomes and when incorporated inside the classical liposomes. However, monocyte plasma membranes bound to the outer surface of the liposomes exhibited greater activity than the monocyte membrane IL 1 itself in its soluble form. This suggests that membrane IL 1 is an integral membrane protein, readily integrated into the lipid bilayers. Like soluble IL 1, the expression of IL 1 activity present in the cytosol of activated monocytes was decreased by incorporation into liposomes, but was high and active when presented on lyophilized liposomes. The best artificial cell reconstitution was obtained with lyophilized liposomes in association with monocyte cytosol and plasma membranes. When an unactivated monocyte compartment was mixed with one from an activated monocyte, the signal was equal to that of the activated cell compartment alone. The IL 1 activity of activated cell fractions associated with lyophilized liposomes was determined, and an increase of IL 1 activity for both plasma membranes and cytosol was observed, whereas a decrease of the signal was obtained for the lysosomal compartment. Endoplasmic reticulum showed no IL 1 activity, even after trypsin treatment. The highest activity after trypsin treatment was recovered in the cytosol associated with lyophilized liposomes, suggesting that molecules obtained after this treatment were able to bind tightly to the lipid bilayers.     

Inhibitory effect of cholesterol on interaction between cytoplasmic actin and liposomes, and restorative effect of high osmotic pressure

Although cholesterol is one of the major components of plasma membranes in eukaryotic cells, very little is known about its role in biological membranes. We reported previously (Okimasu et al., Cell Struct. Funct. 11, 273-283, 1986) that introduction of cholesterol into the liposomal membrane caused a decrease in membrane permeability, especially by the binding of cytoplasmic proteins to the liposomal membrane. The present study was carried out to further clarify the biochemical function of cholesterol in the membrane-protein interactions, especially under high osmotic pressure. The association of membranes with cytoplasmic proteins and their permeability were decreased by the introduction of cholesterol, but its effects were diminished in a hypertonic medium. The protein species associated with cholesterol-containing liposomes vary depending on the sort of hypertonic condition. It was suggested that since the degree of lipid packing by the cholesterol was reduced by the locally increased curvature in the lipid bilayer under high osmotic pressure, some cytoplasmic proteins can penetrate into the liposomal membrane.     

Molecular organization of glutamate-sensitive chemoexcitable membranes of nerve cells. Function of glutamate-binding proteins of the central nervous system when incorporated into liposomes

The functioning of the glutamate-binding protein of rat brain cortex synaptic membranes was studied by its incorporation into liposomes. The optimal conditions for the receptor protein incorporation were established and the kinetics of 22Na+ and 86Rb+ incorporation into the liposomes in the presence of L-glutamate were analyzed. Modelling of the CNS glutamate receptor functions was found to be dependent on the lipid composition and amount of the incorporated membrane protein. The selective transport of 22Na+ into the liposomes was stimulated in the presence of 10(-4) M glutamate. Addition of monoclonal antibodies against glutamate-binding proteins blocked the incorporation of Na+ into the liposomes. The experimental results are suggestive of the nativity of the liposome-incorporated membrane protein, which is capable of binding glutamate and regulating selective transport of Na+. It was assumed that the glutamate receptor macromolecule represents an integral complex made up of several low molecular weight subunits of glucoprotein nature that form a selective ionic channel.     

Thermal and chemical unfolding and refolding of a eukaryotic sodium channel

Voltage-gated sodium channels are dynamic membrane proteins essential for signaling in nervous and muscular systems. They undergo substantial conformational changes associated with the closed, open and inactivated states. However, little information is available regarding their conformational stability. In this study circular dichroism spectroscopy was used to investigate the changes in secondary structure accompanying chemical and thermal denaturation of detergent-solubilised sodium channels isolated from Electrophorus electricus electroplax. The proteins appear to be remarkably resistant to either type of treatment, with “denatured” channels, retaining significant helical secondary structure even at 77 °C or in 10% SDS. Further retention of helical secondary structure at high temperature was observed in the presence of the channel-blocking tetrodotoxin. It was possible to refold the thermally-denatured (but not chemically-denatured) channels in vitro. The correctly refolded channels were capable of undergoing the toxin-induced conformational change indicative of ligand binding. In addition, flux measurements in liposomes showed that the thermally-denatured (but not chemically-denatured) proteins were able to re-adopt native, active conformations. These studies suggest that whilst sodium channels must be sufficiently flexible to undergo major conformational changes during their functional cycle, the proteins are highly resistant to unfolding, a feature that is important for maintaining structural integrity during dynamic processes.     

Transport of phage P22 DNA across the cytoplasmic membrane

Although a great deal is known about the life cycle of bacteriophage P22, the mechanism of phage DNA transport into Salmonella is poorly understood. P22 DNA is initially ejected into the periplasmic space and subsequently transported into the host cytoplasm. Three phage-encoded proteins (gp16, gp20, and gp7) are coejected with the DNA. To test the hypothesis that one or more of these proteins mediate transport of the DNA across the cytoplasmic membrane, we purified gp16, gp20, and gp7 and analyzed their ability to associate with membranes and to facilitate DNA uptake into membrane vesicles in vitro. Membrane association experiments revealed that gp16 partitioned into the membrane fraction, while gp20 and gp7 remained in the soluble fraction. Moreover, the addition of gp16, but not gp7 or gp20, to liposomes preloaded with a fluorescent dye promoted release of the dye. Transport of ³²P-labeled DNA into liposomes occurred only in the presence of gp16 and an artificially created membrane potential. Taken together, these results suggest that gp16 partitions into the cytoplasmic membrane and mediates the active transport of P22 DNA across the cytoplasmic membrane of Salmonella.     

Selective Reconstitution of the Tonoplast H+-ATPase of the Crassulacean-Acid Metabolism Plant Kalanchoë daigremontiana

IA detergent removal technique was used to reconstitute solubilized tonoplast proteins of mesophyll cells of the CAM plant Kalanchoë daigremontiana into phosphatidylcholine liposomes. The proteoliposomes were able to hydrolyse ATP and to pump protons across the vesicle membrane. Both activities were inhibited by nitrate, an inhibitor of V-type ATPases. Freeze-fracture micrographs confirmed the incorporation of membrane proteins into liposomes. Increase of specific ATP-hydrolysis activity compared to solubilized tonoplast proteins and SDS-PAGE analysis of reconstituted proteins in comparison with the polypeptide pattern of the purified tonoplast H⁺-ATPase from the same plant source indicated a highly selective reconstitution of the tonoplast H⁺-ATPase.     

Dipole moment changes and voltage dependent membrane capacity of squid axon

Changes in the membrane capacity of squid axons during hyper- and depolarizations are measured between ?160 and +40 mV. After corrections for the series resistance and fringe effect, we found that the membrane capacity increased from 0.68 to 1.2 μF/cm² with depolarization. It was further observed that tetrodotoxin in the external medium eliminated the change in membrane capacity without affecting the conductivity. The voltage-dependent membrane conductivity is, in turn, greatly reduced by the internal cesium ion. These observations clearly indicate that the voltage-dependent membrane capacity and conductivity are closely related to ionic channels. Particularly, the increase in membrane capacity with depolarizations may be due to sodium channels. The change in the dipole moment associated with sodium sites was determined using values of α_{m and}β_m at various depolarizations. We found, based on voltage clamp measurements, that the increase in the dipole moment of the sodium site between ?40 and ?5 mV is 1230 Debye units (D.U.) and 930 D.U. between ?5 and +60 mV, indicating that the depolarization of sodium channels may consist of two different steps.     

Structure of planar membrane formed from liposomes

Lipid vesicles with incorporated ion channels from polyene antibiotic amphotericin B were used to investigate structures of planar membranes formed by Shindler's techniques. A planar membrane assembled on the aperture in a lavsan film from two layers generated at the air-aqueous liposome suspension interface is not a simple bilayer but a bimolecular membrane containing numerous partly fused liposomes. A complete fusion of liposomal membranes with the planar bilayer is an unlikely event during membrane formation. A planar bimolecular lipid membrane without incorporated liposomes can be made by a method consisting of three stages: formation of a lipid layer on the air-water interface of a suspension containing liposomes, transfer of this layer along the surface of the solution into a chamber containing a solution without liposomes where a lipid monomolecular layer forms gradually (within about 20 min) at the air-water interface, assembling of the planar bilayer membrane from this monolayer. The knowledge of the planar membrane structure may be useful in experiments on incorporation of membrane proteins into a planar lipid bilayer.     

The function of tight junctions in maintaining differences in lipid composition between the apical and the basolateral cell surface domains of MDCK cells.

Tight junctions in epithelial cells have been postulated to act as barriers inhibiting lateral diffusion of lipids and proteins between the apical and basolateral plasma membrane domains. To study the fence function of the tight junction in more detail, we have fused liposomes containing the fluorescent phospholipid N-Rh-PE into the apical plasma membrane of MDCK cells. Liposome fusion was induced by low pH and mediated by the influenza virus hemagglutinin, which was expressed on the apical cell surface after viral infection. Redistribution of N-Rh-PE to the basolateral surface, monitored at 0 degree C by fluorescence microscopy, appeared to be dependent on the transbilayer orientation of the fluorescent lipids in the plasma membrane. Asymmetric liposomes containing over 85% of the N-Rh-PE in the external bilayer leaflet, as shown by a phospholipase A2 assay, were generated by octyl beta-D-glucoside dialysis. When these asymmetric liposomes were fused with the apical plasma membrane, fluorescent lipid did not move to the basolateral side. Symmetric liposomes which contained the marker in both leaflets were obtained by freeze-thawing asymmetric liposomes or by reverse-phase evaporation. Upon fusion of these with the apical membrane, redistribution to the basolateral membrane occurred immediately. Redistribution could be observed with asymmetric liposomes only when the tight junctions were opened by incubation in a Ca2+-free medium. During the normal experimental manipulations the tight junctions remained intact since a high trans-epithelial electrical resistance was maintained over the cell monolayer. We conclude that the tight junction acts as a diffusion barrier for the fluorescent phospholipid N-Rh-PE in the exoplasmic leaflet of the plasma membrane but not in the cytoplasmic leaflet.     

Expression of a peptide processing enzyme in cultured cells: truncation mutants reveal a routing domain.

Peptidylglycine alpha-amidating monooxygenase (PAM) is a bifunctional enzyme responsible for the alpha-amidation of peptides in secretory granules of neuroendocrine cells. The single gene encoding PAM undergoes tissue-specific alternative splicing and endoproteolytic processing to generate bifunctional membrane proteins with a single transmembrane domain as well as soluble proteins that are mono- or bifunctional. In order to examine the endoproteolytic processing and subcellular localization of the various forms of PAM in cells lacking regulated secretory granules, we established stably transfected hEK-293 cell lines expressing naturally occurring and mutant forms of PAM. As expected, newly synthesized soluble PAM proteins were rapidly secreted into the medium. Integral membrane protein forms of PAM were largely localized in the perinuclear region with punctate staining visible throughout the cell and 2-5% of the enzyme activity detectable on the cell surface. Bifunctional PAM proteins were slowly released into the medium after expression of integral membrane protein forms of PAM. Deletion of 77 amino acids from the COOH-terminus of the integral membrane forms of PAM resulted in a membrane-bound protein which retained both enzymatic activities but accumulated on the cell surface. Rapid internalization of full-length PAM proteins was observed by incubating live cells with antiserum to PAM; deletion of the COOH-terminal domain eliminated the ability of cells to internalize PAM. Thus the cytoplasmic domain of integral membrane PAM contains a routing determinant recognized by cells lacking the regulated secretory pathway.     

Transfer of phosphatidic acid between microsomal and mitochondrial outer and inner membranes

A protein fraction from rat liver cytoplasm, precipitable at 50-95% saturation of ammonium sulphate, binds phosphatidic acid from mitochondrial and microsomal membranes. Protein-bound phosphatidic acid was eluted from Sephadex G-75 in fractions corresponding to a molecular weight of about 10 000. No such binding was observed with mitochondrial soluble proteins, either total or precipitated with ammonium sulphate between 50 and 95% saturation. The transfer of phosphatidic acid from microsomes to mitochondria was increased by liver cytoplasmic proteins precipitable at 50-95% saturation of ammonium sulphate but not with mitochondrial soluble proteins. This increase by cytoplasmic proteins was pronounced in 200 mM sucrose but was negligible in 100 mM KCI where the spontaneous transfer was quite high. Cytoplasmic proteins stimulated the synthesis of cardiolipin and phosphatidylglycerol in mitochondria deprived of the outer membrane but not in intact mitochondria when phosphatidic acid was supplied either by microsomes or liposomes. It is suggested that the transfer of phosphatidic acid from the outer to the inner mitochondrial membrane is not mediated by transfer proteins but occurs either by direct contact of the membranes or as free diffusion through the aqueous phase.     

Turnover studies on proteins of rat liver lysosomes.

The turnover of rat liver lysosomal proteins was studied by a double isotope-labeling technique. The cellular fractions investigated included soluble lysosomal proteins, lysosomal membrane proteins, highly purified lysosomal beta-glucuronidase, and for comparison, microsomal proteins and soluble cytoplasmic proteins. Both "normal" lysosomes and Triton WR-1339-filled lysosomes (tritosomes) were studied, with similar results. It was found that (a) the turnover rate of lysosomal proteins, of both the soluble and membranous compartments, was very similar to that of the proteins of the microsomal and soluble cytoplasmic fractions, and (b) the turnover rate of lysosomal proteins was asynchronous. The latter conclusion was based on two lines of evidence: (a) lysosomal beta-glucuronidase had a distinctly slower turnover rate than the average rate of the soluble lysosomal proteins, and (b) subunits of the proteins of the soluble lysosomal fraction as separated by sodium dodecyl sulfate. Sephadex G-200 gel filtration showed different rates of degradation.