Measurement of intravesicular volumes by salt entrapment.

Internal volume is a very sensitive parameter of vesicle morphology. Measurement of captured volumes by solute entrapment is legitimate for most types of vesicles (Perkin, W.R. et al. (1993) Chem. Phys. Lipids 64, 197-217). In this study chloride was selected as the most convenient marker ion because the ubiquity of Cl- in physiological buffers eliminates prelabeling with exogenous markers and because minute concentrations of trapped chloride are well detectable in the presence of large extravesicular nitrate concentrations. Perfect exchange of external chloride for nitrate was shown to be accomplished by gel filtration, dialysis, or sucrose gradient flotation-but only after significant technical improvements and/or elimination of experimental pitfalls. Reliability was cross-checked by simultaneous entrapment of Cl- and K+. Diafiltration and ion exchange chromatography appeared inapplicable for exchange of extravesicular salt. When a representative variety of vesicle preparations was analyzed for internal volume (as well as for external surface and size) unexpected features of vesicle morphology were discovered. This emphasizes the genuine role of macroscopic vesicle characterization in complementing information from electron microscopy.

Protonation of histidine-132 promotes oligomerization of the channel-forming toxin aerolysin.

Aerolysin is a bacterial toxin that binds to a receptor on eukaryotic cells and oligomerizes to form stable, SDS-resistant, noncovalent oligomers that insert into the plasma membrane and produce well-defined channels. Little is known about the mechanisms controlling this process. Here we show that the protonation of a single histidine is required for oligomerization of aerolysin in solution. First we have investigated the effect of pH on the activity of aerolysin. The toxin's ability to disrupt human erythrocytes declined as the pH increased above 7.4. Experiments with receptor-free planar lipid bilayers demonstrated that the rate at which aerolysin formed channels also decreased with increasing pH, although the conductance of preexisting channels was not affected. The reduction in the rate of channel formation was shown to be due to a decrease in the toxin's ability to oligomerize. Our data indicate that the pH effect on activity is due to the deprotonation of a single residue rather than a global effect of pH on the protein. In agreement with our previous site-directed mutagenesis studies, His-132 is most likely to be the target of this pH effect. This conclusion was reinforced by the fact that we could shift the pH dependence of the activity to lower pH values by mutating Asp-139, a residue less than 3 A away from His-132 and likely to contribute to the usually high pKa of this histidine.

Partial purification of the rat erythrocyte receptor for the channel-forming toxin aerolysin and reconstitution into planar lipid bilayers.

The cytolytic toxin aerolysin binds to a receptor on the surface of eukaryotic cells. Murine erythrocytes are among the most sensitive to the toxin. Here we describe the detergent solubilization and partial purification of the receptor from rat erythrocytes. We show that it can be successfully incorporated into planar lipid bilayers, greatly decreasing the concentration of aerolysin required to form channels. Exploiting the ability of the receptor to bind aerolysin after SDS electrophoresis and blotting, we obtain evidence that it is a 47 kDa glycoprotein that is sensitive to proteases and N-glycosidase. It may correspond to CHIP28, the water channel of the human erythrocyte.

The aerolysin membrane channel is formed by heptamerization of the monomer.

The cytolytic toxin aerolysin has been found to form heptameric oligomers by SDS-PAGE electrophoresis, STEM mass measurements of single oligomers and image analysis of two-dimensional membrane crystals. Two types of crystal, flat sheets and long regular tubes, have been obtained by reconstitution of purified protein and Escherichia coli phospholipids. A noise-filtered image of the best crystalline sheets reveals a structure with 7-fold symmetry containing a central strongly stain-excluding ring that encircles a dark stain-filled channel 17 A in diameter. The ring is surrounded by seven arms each made up of two unequal sized domains. By combining projected views and side-views, a simplified model of the aerolysin channel complex has been constructed. The relevance of this structure to the mode of action of aerolysin is discussed.

Site-directed mutagenesis at histidines of aerolysin from Aeromonas hydrophila: a lipid planar bilayer study.

The role of histidine residues in the formation of channels by the cytolytic toxin aerolysin has been studied in planar lipid bilayers by substituting each of the six histidines in the native protein with asparagine. His341 or His186 mutants had the same channel-forming ability as native toxin, whereas the His332 and His121 mutants were less active. Mutations at His132 and His107, which interfere with the oligomerization of the toxin, drastically reduce pore formation. These findings support the conclusion that oligomerization of the toxin must precede channel formation, and that at least two of the six histidine residues are essential for this to occur. The aerolysin channel is a water-filled pore with an approximate diameter of 9.3 +/- 0.4 A.

Aerolysin, a hemolysin from Aeromonas hydrophila, forms voltage-gated channels in planar lipid bilayers.

The cytolytic toxin aerolysin was found to form ion channels which displayed slight anion selectivity in planar lipid bilayers. In voltage-clamp experiments the ion current flowing through the channels was homogeneous indicating a defined conformation and a uniform size. The channels remained open between -70 to +70 mV, but outside this range they underwent voltage-dependent inactivation which was observed as open-closed fluctuations at the single-channel level. Zinc ions not only prevented the formation of channels by inhibiting oligomerization of monomeric aerolysin but they also induced a closure of preformed channels in a voltage-dependent fashion. The results of a Hill plot indicated that 2-3 zinc ions bound to a site within the channel lumen. Proaerolysin, and a mutant of aerolysin in which histidine 132 was replaced by an asparagine, were both unable to oligomerize and neither could form channels. This is evidence that oligomerization is a necessary step in channel formation.

Colicins: prokaryotic killer-pores.

Colicins are plasmid-encoded protein antibiotics which kill bacteria closely related to the producing strain (generally Escherichia coli). The study of the function of colicins has revealed many features which reflect common targeting and translocation mechanisms with bacteriophages and toxins. Like many toxins, colicins are composed of structural domains specialized in one of the different steps of the activity, targeting, translocation and killing. The major group comprises those colicins which permeabilize the cytoplasmic membrane, thereby destroying the cell's membrane potential. These colicins form well-defined voltage-gated ion channels in artificial membranes. The scope of this review is to describe some of the more recent findings concerning the structure and mode of action of pore-forming colicins with a special attention to models of membrane insertion and pore structure based on the recently determined three-dimensional structure of the pore-forming domain of colicin A.

Colicin N forms voltage- and pH-dependent channels in planar lipid bilayer membranes.

The protein antibiotic colicin N forms ion-permeable channels through planar lipid bilayers. Channels are induced when positive voltages higher than +60 mV are applied. Incorporated channels activate and inactivate in a voltage-dependent fashion. It is shown that colicin N undergoes a transition between an "acidic" and a "basic" channel form which are distinguishable by different voltage dependences. The single-channel conductance is non-ohmic and strongly dependent on pH, indicating that titratable groups control the passage of ions through the channel. The ion selectivity of colicin N channels is influenced by the pH and the lipid composition of the bilayer membrane. In neutral membranes the channel undergoes a transition from slightly cation-selective to slightly anion-selective when the pH is changed from 7 to 5. In lipid membranes bearing a negative surface charge the channel shows a more pronounced cation selectivity which decreases but does not reverse upon lowering the pH from 7 to 5. The high degree of similarity between the channel characteristics of colicin A and N suggests that the channels share common features in their molecular structure.

Phallolysin. A mushroom toxin, forms proton and voltage gated membrane channels.

Phallolysin, a water soluble protein of Mr 34,000 produced by the poisonous mushroom Amanita phalloides, causes lysis of various mammalian cell types. Lysis is thought to be initiated by the formation of ion permeable membrane channels. We therefore studied the interaction of phallolysin with solvent-free planar lipid bilayers. In the presence of low phallolysin concentrations (10-100 nM) single channel current fluctuations were observed. Unit channel conductances are 44 pS in 500 mM NaCl and 77 pS in 1 M NaCl. Although the channel does not significantly discriminate between alkali cations, its permeability to Cl- is lower (PK+/PCl- = 4/1). Gating kinetics display a pronounced bursting behavior and a dependence on membrane voltage, cis side pH-value, and on membrane lipid composition. An equivalence relation between membrane voltage and proton concentration was found, i.e. a pH change of one unit is equivalent to a corresponding voltage change of 130 mV. Dependence on the amount of negatively charged lipids is explained by changes of the actual pH due to surface charge effects.

Melittin and a chemically modified trichotoxin form alamethicin-type multi-state pores.

The bee venom constituent, melittin, is structurally and functionally related to alamethicin. By forming solvent-free planar bilayers of small area (approx. 100 microns 2) on the tip of fire-polished glass pipettes we could observe single melittin pores in these membranes. An increase in the applied voltage induced further non-integral conductance levels. This indicates that melittin forms multi-level pores similar to those formed by alamethicin. Trichotoxin A40, an antibiotic analogue of alamethicin, also induces a voltage-dependent bilayer conductivity, but no stable pore states are resolved. However, chemical modification of the C-terminal molecule part by introduction of a dansyl group leads to a steeper voltage-dependence and pore state stabilization. Comparing structure and activity of several natural and synthetic amphiphilic polypeptides, we conclude that a lipophilic, N-terminal alpha-helical part of adequate length (dipole moment) and a large enough hydrophilic, C-terminal region are sufficient prerequisites for voltage-dependent formation of multi-state pores.