Local anesthetics noncompetitively inhibit terbium binding to the exterior surface of nerve membrane vesicles

It has previously been shown that terbium binds to membrane vesicles prepared from the walking leg nerve of the lobster (Homarus americanus) with a high affinity K_d of 2.2 μM. Fluorescence of bound Tb³⁺ occurs via energy transfer from the aromatic residues of proteins (γ_ex = 280 nm; γ_em = 546 nm), and calcium inhibits Tb³⁺ binding competitively with a K_i of 1.8 mM. Displacement studies with EDTA demonstrate that more than 95% of the bound Tb³⁺ is at the vesicle exterior and is not being taken up by the vesicles. To investigate the putative role of Ca²⁺ in the interaction of local anesthetics with axonal membranes, lidocaine and the analogs GX-HCl and QX-314 were tested as inhibitors of Tb³⁺ binding. Inhibition by lidocaine is seen only at considerably higher doses (25 mM) than are required for conduction block of intact nerves (5 mM). Inhibition by lidocaine and the primary amine analog GX-HCl is entirely noncompetitive, whereas the quaternary ammonium derivative QX-314 appears to be a mixed competitive-noncompetitive inhibitor of Tb³⁺ binding. These data are not compatible with the hypothesis that there is a functionally essential cation binding site on the axonal membrane surface for which Ca²⁺ and local anesthetics compete, although local anesthetic action may be modified indirectly by altered calcium concentrations. Evidence is presented for a mechanism by which local anesthetics indirectly displace Tb³⁺ by altering the physical state of the axonal membrane.     

Permeability to ions of bovine retinal disk membrane vesicles in the bleached state

The permeability of the bleached disk membrane of retinal rod outer segments to univalent and divalent ions is studied by light scattering. The membranes are isolated from frozen dark-adapted bovine retinae, swollen into spherical vesicles in a hypotonic medium and bleached in dilute suspension and their size is determined by elastic and quasi-elastic light scatterings. Various electrolytes are then added to the suspending medium in order to examine their osmotic activity relative to the vesicles deformation characteristics. By following the deformation behavior of the membrane vesicles by elastic light scattering in terms of the oblate ellipsoidal shell model, the osmotic activity of a given electrolyte is qualitatively deduced and thereby the permeability of the membrane to the electrolyte is ranked in reference to a chosen standard, i.e., sucrose. By this method, we show that the permeabilities to Na⁺, K⁺, Mg²⁺ and Ca²⁺ are all alike, and those to halides (F^?, Cl^?, Br^?, I^?), nitrate and phosphates (HPO₄^2?/H₂PO₄^?) are similar. Acetate, however, is about 3-times more permeative, while sulfate is less permeative than the other anions by about the same factor. The viability of our method is checked with use of an ionophore, lasolocid (X-537A), by establishing partial recovery from the osmotic deformation through the suppression of the cation osmotic effect. Ion-induced aggregation and pH-dependent size and shape changes are both found to be insignificant.     

Sodium ion uptake into isolated plasma membrane vesicles: indirect effects of other ions

Vesicles derived from plasma membrane of corneal endothelium were agitated to their minimum size distribution. When isotonic salt solutions surrounding the vesicles were changed there were alterations to the vesicle size distribution: the modal point of the logarithmic distribution did not change but the log variance did, indicating that substantial fission and fusion of vesicles occurred depending upon the nature of the surrounding solute. Orientation and total membrane area was conserved in the transformed population of vesicles. Although the ions added to the external isotonic salt solutions in the present series of experiments have no direct effect upon sodium membrane transporters in these membranes, kinetics of sodium accumulation into the vesicles were affected in a way that correlated with changes to the vesicle size distribution. Early-saturating (<1 min) intravesicular concentrations of sodium corresponded with apparently stable populations. Late-saturating (>1 min) intravesicular concentrations of sodium corresponded with significant vesicle distribution shifts and included a few seconds of delay. During the linear accumulation phase, both populations showed similar magnitudes of sodium transport. The significance of these data is discussed.     

Modulation of serotonin uptake kinetics by ions and ion gradients in human placental brush-border membrane vesicles

The modulation of serotonin uptake kinetics by Na+, Cl-, H+, and K+ was investigated in brush-border membrane vesicles prepared from normal human term placentas. The presence of Na+ and Cl- in the external medium was mandatory for the function of the serotonin transporter. In both cases, the initial uptake rate of serotonin was a hyperbolic function of the ion concentration, indicating involvement of one Na+ and one Cl- per transport of one serotonin molecule. The apparent dissociation constant for Na+ and Cl- was 145 and 79 mM, respectively. The external Na+ increased the Vmax of the transporter and also increased the affinity of the transporter for serotonin. The external Cl- also showed similar effects on the Vmax and the Kt, but its effect on the Kt was small compared to that of Na+. The presence of an inside-acidic pH, with or without a transmembrane pH gradient, stimulated the NaCl-dependent serotonin uptake. The effect of internal [H+] on the transport function was to increase the Vmax and decrease the affinity of the transporter for serotonin. The presence of K+ inside the vesicles also greatly stimulated the initial rates of serotonin uptake, and the stimulation was greater at pH 7.5 than at pH 6.5. This stimulation was a hyperbolic function of the internal K+ concentration at both pH values, indicating involvement of one K+ per transport of one serotonin molecule. The apparent dissociation constant for K+ was 5.6 mM at pH 6.5 and 4.0 mM at pH 7.5. The effects of internal [K+] on the uptake kinetics were similar to those of internal [H+].(ABSTRACT TRUNCATED AT 250 WORDS)     

Luminescence of peptide-bound terbium ions. Determination of binding constants

Luminescence of Tb3+ ions bound to a calmodulin fragment has been studied. It is shown that during their lifetime excited ions dissociate from the peptide. If concentration of free peptide is high enough they can be coordinated again. As a consequence, observed terbium luminescence lifetime and intensity depends not only on binding equilibrium, but also on concentration of free peptide molecules. In such a system terbium binding constant cannot be correctly determined by simple steady-state measurements of luminescence intensities. Instead, terbium luminescence decay curves measured at various peptide concentrations must be analysed. Such an analysis has been made for a fragment of the IIIrd calcium binding domain of rat testis calmodulin. Rate constant of terbium association and the equilibrium binding constant corresponding to the best fit of theoretical functions to experimental points have been determined.     

Fast axonal transport of foreign synaptic vesicles in squid axoplasm

Translocation of intracellular organelles requires interaction with the cellular cytoskeleton, but the membrane and cytoskeletal proteins involved in movement are unknown. Here we show that highly purified synaptic vesicles from electric fish added to extruded squid axoplasm can show ATP-dependent movement. The movement is indistinguishable from that of endogenous vesicles and has a slight preference for the orthograde direction. In the presence of a nonhydrolyzable ATP analog, the synaptic vesicles bind to axoplasmic fibers but do not move. Elastase treatment of vesicles inhibits both binding and movement. We conclude that a protein component on the surface of cholinergic synaptic vesicles from electric fish is conserved during evolution and so can be recognized by the organelle-translocating machinery of the squid axon, resulting in ATP-dependent movement. Synaptic vesicles apparently retain the capacity for fast axonal transport, even after they reach their intracellular destination.     

Solute distributions and trapping efficiencies observed in freeze-thawed multilamellar vesicles

It has recently been observed (Gruner, Lenk, Janoff and Ostro (1985) Biochemistry, in the press) that mechanical dispersion of dry lipid in an aqueous buffer to form multilamellar vesicle (MLV) systems does not result in equilibrium trans-membrane distributions of solute. In particular, the entrapped buffer exhibits reduced solute concentrations. Here we demonstrate that egg phosphatidylcholine MLV systems dispersed in the presence of Mn2+ also exhibit non-equilibrium solute distributions, and that repetitive freeze-thawing cycles can remove such solute heterogeneity. Further, the resulting freeze-thawed MLVs exhibit dramatically enhanced trapped volumes and trapping efficiencies. At 400 mg phospholipid per ml, for example, the trapping efficiencies can be as high as 90%. This is associated with a remarkable change in MLV morphology where large inter-bilayer separations are commonly observed.     

Interaction of parvalbumin of pike II with calcium and terbium ions

Fluorimetric titrations of parvalbumin II (pI 4.2) of pike (Pike II) with Ca2+ and Tb3+ show the CD and EF binding sites to be non-equivalent. The intrinsic binding constants of the strong and the weak sites obtained for Ca2+ are: KsCa = 1.6.10(8) M-1; KwCa = 6.6.10(5) M-1. Differences of the order of 100% were encountered between the Tb3+ binding constants obtained with four different versions of titration. Their average values are: KsTb = 1.9.10(11) M-1; KwTb = 1.0.10(7) M-1. The distances of the strong and the weak sites from the singular Tyr-48, rs = 9.5 A and r2 = 11.5 A, were derived from F?rster-type energy transfer and proved compatible with the X-ray structure of parvalbumin III (pI 4.2) of carp (CarpIII). From the distances, it is suggested that CD is the strong and EF the weak metal-binding site of PikeII. Tb3+ was shown by CD spectroscopy to have the same structural effect on PikeII as Ca2+. Removal of the metal ions from PikeII results in a decrease of helix content as monitored by CD spectroscopy. This decrease is larger than that in CarpIII. A concomitant decrease of the fluorescence quantum yield at nearly constant decay time is indicative of mainly static quenching, probably by the non-coordinating carboxylate groups. The maximum helix content is almost completely reestablished upon binding of the first metal ion. However, small changes of the energy transfer in PikeII with one terbium ion bound to the strong site indicate fine structural rearrangements of the strong binding site when Ca2+ is bound to the weak one.     

Interfacial spin trapping in model membrane systems

The nature of mitochondrial DNA replication during the synchronous cell cycle in the yeast, $\text{Saccharomyces}\text{cerevisiae}$ has been investigated by examining the rate of labeled DNA precursor incorporation into specific segments of the mitochondrial genome at defined points during synchronous growth. The movement of label uptake from one area of the DNA to another at different times during the synchronous cell cycle indicates mitochondrial DNA replication to be a synchronous process during this time with most or all molecules at the same point in replication at any given time during the cell cycle.     

Multiple-point adsorption of terbium ions by lead ion templated thermosensitive gel: elucidating recognition of conformation in gel by terbium probe

Lead ion templated thermosensitive heteropolymer gel which has recognition ability of methacrylate pairs has been synthesized and characterized. The gel consists of a main monomer component, N-isopropylacrylamide (NIPA), responsible for volume phase transition, methacrylic acid (MAA) moieties imprinted as pairs to adsorb terbium ions and cross-links. An imprinting technique was applied using lead ion complex with methacrylate ligands in dioxane media. After gel was obtained, lead ions were removed by washing and the imprinted gel showed strong binding ability to terbium ions, comparable with that of the non-imprinted gel prepared without lead ions. It was found that the Tb(3+) fluorescence intensity was considerably increased upon binding this ion to both imprinted and non-imprinted gels, but the largest enhancement of fluorescence intensity was observed when Tb(3+) was bound to imprinted gel in shrunken state. This is because of the decrease of coordinated water molecules on Tb(3+) and the strong binding of this ion to methacrylate pairs which are encoded within the weakly cross-linked network of imprinted gel.     

Multifunctional membrane vesicles in Pseudomonas aeruginosa

Gram‐negative bacteria secrete small particles called membrane vesicles (MVs) into the extracellular milieu. While MVs have important roles in delivering toxins from pathogenic bacteria to eukaryotic cells, these vesicles also play ecological roles necessary for survival in various environmental conditions. Pseudomonas aeruginosa, which lives in soil, ocean, plant, animal and human environments, has become a model organism for studying these small extracellular particles. Such studies have increased our understanding of the function and biogenesis of bacterial MVs. Pseudomonas aeruginosa MVs possess versatile components and chemical substances with unique structures. These characteristics allow MVs to play their multifunctional biological roles, including microbial interaction, maintenance of biofilm structure and host infection. This review summarizes the comprehensive biochemical and physiochemical properties of MVs derived from P. aeruginosa. These studies will help us understand their biological roles of MVs not only in pathogenicity but also in microbial ecology. Also, the mechanisms of MV production, as currently understood, are discussed.     

Biogenesis of bacterial membrane vesicles

Membrane vesicle (MV) release remains undefined, despite its conservation among replicating Gram-negative bacteria both in vitro and in vivo . Proteins identified in Salmonella MVs, derived from the envelope, control MV production via specific defined domains that promote outer membrane protein–peptidoglycan (OM–PG) and OM protein–inner membrane protein (OM–PG–IM) interactions within the envelope structure. Modulation of OM–PG and OM–PG–IM interactions along the cell body and at division septa, respectively, maintains membrane integrity while co-ordinating localized release of MVs with distinct size distribution and protein content. These data support a model of MV biogenesis, wherein bacterial growth and division invoke temporary, localized reductions in the density of OM–PG and OM–PG–IM associations within the envelope structure, thus releasing OM as MVs.     

Fusion of photoreceptor membrane vesicles

Summary Then-alkyl bromides with 6 to 10 carbons induce formation of vesicles of 5 to 100 m diameter from the small vesicles (0.1 m average diameter) produced by disruption of the discs from frog rod photoreceptors. Then-alkanes,n-alkyl iodides andn-alkyl chlorides are relatively ineffective. The formation of large vesicles is independent of calcium concentration and is distinguished from fusion processes previously reported by the large number of vesicles involved. The results reported here together with others suggest the occurrence of multiple fusion (and/or rupture-resealing) events between vesicles, induced by then-alkyl bromides.     

Choline fluxes in synaptosomal membrane vesicles

Synaptic plasma membrane vesicles isolated from the highly cholinergic nervous tissue of insects were used to study the translocation of choline across the membrane via a high-affinity carrier-mediated mechanism energized by ion gradients as the sole driving force. The uphill movement of choline, energized mainly by the Na+ gradient, attained levels of choline severalfold the final equilibrium value at the peak of the overshoot. Efflux of choline required the presence of internal sodium ions and was promoted by external choline if Na+ was present. External choline inhibited choline efflux in the absence of sodium. It is concluded that the efflux of choline is in many aspects symmetrical with its uptake.     

Entrapment of lipid vesicles and membrane protein-lipid vesicles in gel bead pores

Phospholipid vesicles were entrapped in gel beads of Sepharose 6B and Sephacryl S-1000 during vesicle preparation by dialysis. Egg-yolk phospholipids solubilized with cholate or octyl glucoside were dialysed together with gel beads for 2.5 days in a flat dialysis bag. Some vesicles were formed in gel bead pores and vesicles of sufficient size became trapped. Red cell membrane protein-phospholipid vesicles could be immobilized in the same way. Non-trapped vesicles were carefully removed by chromatographic procedures and by centrifugation. The amount of entrapped vesicles increased with the initial lipid concentration and was dependent on the relative sizes of vesicles and gel pores. The largest amount of trapped vesicles, corresponding to 9.5 mumol of phospholipids per ml gel, was achieved when Sepharose 6B gel beads were dialysed with cholate-solubilized lipids at a concentration of 50 mM. In this case the vesicles had an average diameter of 60 nm and an internal volume of 15 microliters/ml gel. The amount of vesicles trapped in Sephacryl S-1000 gel beads upon dialysis under the same conditions was smaller: 2.2 mumol of phospholipids per ml gel. Probably most of the gel pores were too large to trap such vesicles. Larger vesicles, with an average diameter of 230 nm, were entrapped in the Sephacryl S-1000 matrix in an amount corresponding to 3.0 mumol phospholipids per ml gel upon dialysis of the gel beads and octyl glucoside-solubilized lipids at a concentration of 20 mM. The internal volume of these vesicles was 22 microliters/ml gel. The yield of immobilized phospholipids was up to 19%. The entrapped vesicles were somewhat unstable: 9% of the phospholipids were released during 9 days of storage at 4 degrees C. By the dialysis entrapment method vesicles can be immobilized in the gel beads without using hydrophobic ligands or covalent coupling.     

Localization of membrane proteins in membrane vesicles of Bacillus subtilis.

Electrons can be transferred to the respiratory chain in whole cells and in membrane vesicles of Bacillus subtilis W 23 by the membrane impermeable electron donor reduced 5-N-methyl-phenazonium-3-sulfonate as efficiently as by the membrane permeable electron donor reduced 5-N-methyl-phenazonium methyl-sulfate, indicating that the respiratory chain is accessible from the outside of the membrane.Succinate is oxidized by whole cells and membrane vesicles at a low rate and does not energize transport of l-glutamate. In the presence of 5-N-methyl-phenazonium-3-sulfonate or 5-N-methyl-phenazonium methyl-sulfate, the oxidation rate and the rate of l-glutamate transport are increased considerably. The electrons are transferred directly from succinic dehydrogenase to these acceptors. Succinic dehydrogenase must therefore be exposed to the outside surface of the membrane in both membrane vesicles and whole cells. The exposure of succinic dehydrogenase to the outside is also indicated by the observations that only a 5% increase in the oxidation rates of succinate-5-N-methyl-phenazonium methylsulfate and succinate-5-N-methyl-phenazonium-3-sulfonate is observed upon solubilization of the membrane with the nonionic detergent Brij-58. Furthermore, treatment of membrane vesicles with trypsin decreases by more than 95% these oxidation rates.NADH is oxidized at a high rate and energizes transport of l-glutamate in whole cells and membrane vesicles effectively. The NADH-oxidation is not effected by trypsin treatment of the vesicles indicating that the oxidation occurs at the inside-surface of the membrane. Trypsin treatment of the vesicles, however, significantly decreases the rate of l-glutamate transport driven by NADH. Therefore component(s) of the transport system for l-glutamate must be effected by trypsin treatment. No apparent differences could be observed in the localization of membrane-bound functions between membrane vesicles and whole cells. This strongly supports the contention that the vesicle membrane of B. subtilis has the same orientation as the cytoplasmic membrane of whole cells.     

Bacterial communication through membrane vesicles

ABSTRACT

Bacteria can communicate through diffusible signaling molecules that are perceived by cognate receptors. It is now well established that bacterial communication regulates hundreds of genes. Hydrophobic molecules which do not diffuse in aqueous environments alone have been identified in bacterial communication, that raised the question on how these molecules are transported between cells and trigger gene expressions. Recent studies show that these hydrophobic signaling molecules, including a long-chain N-acyl homoserine lactone signal produced in Paracoccus denitrificans, are carried by membrane vesicles (MVs). MVs were thought to be formed only through the blebbing of the cell membrane, but new findings in Pseudomonas aeruginosa and Bacillus subtilis revealed that different types of MVs can be formed through explosive cell lysis or bubbling cell death, which findings have certain implications on our view of bacterial interactions.     

Sedimentation studies on membrane vesicles

Analytical centrifugation was used in order to investigate the size distribution of vesicles in various membrane preparations. Under certain conditions depending among others on the speed of rotation and the temperature, a sedimentation profile was observed that was characteristic for membraneous material. Since the membrane vesicles exhibited a discontinuous distribution of sedimentation coefficients it was concluded that membrane vesicles only occur in a few size classes.