Helena Ostolaza

Release of lipid vesicle contents by the bacterial protein toxin α-haemolysin

Abstract α-Haemolysin is a protein toxin (107 kDa) secreted by some pathogenic strains of E. coli . It binds to mammalian cell membranes, disrupting cellular activities and lysing cells. This paper describes the mechanism of α-haemolysin-induced membrane leakage, from experiments in which extrusion large unilamellar vesicles, loaded with fluorescent solutes, are treated with purified toxin. The results show that the toxin does not require of any membrane receptor to exert its activity, that vesicles become leaky following an ‘all-or-none’ mechanism, and that leakage occurs through a non-osmotic detergent-like bilayer disruption induced by the protein. Small pores formed by monomeric α-haemolysin, as described by other authors, do not appear to be related to the process of membrane disruption. Instead, the experimental data would be in agreement with the idea of oligomeric assemblies being required to produce release of solutes from a single vesicle.

Surfactant-induced cell toxicity and cell lysis. A study using B16 melanoma cells.

The effects of a variety of detergents (non-ionic, ionic and bile derivatives) on B16 melanoma cells have been examined. Two main effects can be clearly differentiated: loss of cell viability and cell lysis. Under our conditions, cell-surfactant interaction is highly dependent on the nature of the amphiphile (more specifically, on its critical micellar concentration). Loss of cell viability occurs at surfactant concentrations below the critical micellar concentration, i.e. the incorporation of detergent monomers into the cell membranes is enough to impair their barrier function, so that Trypan Blue is no longer actively secreted outside the cell. On the other hand, cell lysis only occurs at or near the critical micellar concentration of the detergent, i.e. when the bilayer-micelle transition may take place. Comparative studies using B16 cells and phospholipid vesicles indicate that the amount of detergent required to induce cell lysis is the same that produces disruption of the lipid bilayer. Thus, our results suggest that membranes are the primary target for the toxicologic effects of surfactants on cells. Moreover, they provide a rationale for the interpretation of other studies in this field: previous results from different laboratories are shown to fit very well our data.

REVERSIBLE ADSORPTION AND NONREVERSIBLE INSERTION OF ESCHERICHIA COLI ALPHA -HEMOLYSIN INTO LIPID BILAYERS

Alpha-Hemolysin is an extracellular protein toxin (107 kDa) produced by some pathogenic strains of Escherichia coli. Although stable in aqueous medium, it can bind to lipid bilayers and produce membrane disruption in model and cell membranes. Previous studies had shown that toxin binding to the bilayer did not always lead to membrane lysis. In this paper, we find that alpha-hemolysin may bind the membranes in at least two ways, a reversible adsorption and an irreversible insertion. Reversibility is detected by the ability of liposome-bound toxin to induce hemolysis of added horse erythrocytes; insertion is accompanied by an increase in the protein intrinsic fluorescence. Toxin insertion does not necessarily lead to membrane lysis. Studies of alpha-hemolysin insertion into bilayers formed from a variety of single phospholipids, or binary mixtures of phospholipids, or of phospholipid and cholesterol, reveal that irreversible insertion is favored by fluid over gel states, by low over high cholesterol concentrations, by disordered liquid phases over gel or ordered liquid phases, and by gel over ordered liquid phases. These results are relevant to the mechanism of action of alpha-hemolysin and provide new insights into the membrane insertion of large proteins.

Insertion Of Escherichia Coli Alpha-Haemolysin In Lipid Bilayers As A Non-Transmembrane Integral Protein: Prediction And Experiment

α‐Haemolysin is an extracellular protein toxin (≈107 kDa) secreted by Escherichia coli that acts at the level of the plasma membranes of target eukaryotic cells. The nature of the toxin interaction with the membrane is not known at present, although it has been established that receptor‐mediated binding is not essential. In this work, we have studied the perturbation produced by purified α‐haemolysin on pure phosphatidylcholine bilayers in the form of large unilamellar vesicles, under conditions in which the toxin has been shown to induce vesicle leakage. The bilayer systems containing bound protein have been examined by differential scanning calorimetry, fluorescence spectroscopy, differential solubilization by Triton X‐114, and freeze–fracture electron microscopy. All the data concur in indicating that α‐haemolysin, under conditions leading to cell lysis, becomes inserted in the target membrane in the way of intrinsic or integral proteins. In addition, the experimental results support the idea that inserted α‐haemolysin occupies only one of the membrane phospholipid monolayers, i.e. it is not a transmembrane protein. The experimental data are complemented by structure prediction studies according to which as many as ten amphipathic α‐helices, appropriate for protein–lipid interaction, but no hydrophobic transmembrane helices are predicted in α‐haemolysin. These observations and predictions have important consequences for the mechanism of cell lysis by α‐haemolysin; in particular, a non‐transmembrane arrangement of the toxin in the target membrane is not compatible with the concept of α‐haemolysin as a pore‐forming toxin.

Membrane Restructuring by Bordetella pertussis Adenylate Cyclase Toxin, a Member of the RTX Toxin Family

Adenylate cyclase toxin (ACT) is secreted by Bordetella pertussis, the bacterium causing whooping cough. ACT is a member of the RTX (repeats in toxin) family of toxins, and like other members in the family, it may bind cell membranes and cause disruption of the permeability barrier, leading to efflux of cell contents. The present paper summarizes studies performed on cell and model membranes with the aim of understanding the mechanism of toxin insertion and membrane restructuring leading to release of contents. ACT does not necessarily require a protein receptor to bind the membrane bilayer, and this may explain its broad range of host cell types. In fact, red blood cells and liposomes (large unilamellar vesicles) display similar sensitivities to ACT. A varying liposomal bilayer composition leads to significant changes in ACT-induced membrane lysis, measured as efflux of fluorescent vesicle contents. Phosphatidylethanolamine (PE), a lipid that favors formation of nonlamellar (inverted hexagonal) phases, stimulated ACT-promoted efflux. Conversely, lysophosphatidylcholine, a micelle-forming lipid that opposes the formation of inverted nonlamellar phases, inhibited ACT-induced efflux in a dose-dependent manner and neutralized the stimulatory effect of PE. These results strongly suggest that ACT-induced efflux is mediated by transient inverted nonlamellar lipid structures. Cholesterol, a lipid that favors inverted nonlamellar phase formation and also increases the static order of phospholipid hydrocarbon chains, among other effects, also enhanced ACT-induced liposomal efflux. Moreover, the use of a recently developed fluorescence assay technique allowed the detection of trans-bilayer (flip-flop) lipid motion simultaneous with efflux. Lipid flip-flop further confirms the formation of transient nonlamellar lipid structures as a result of ACT insertion in bilayers.

Calcium-dependent conformation of E. coli α-haemolysin. Implications for the mechanism of membrane insertion and lysis

Previous studies from this laboratory had shown that calcium ions were essential for the membrane lytic activity of E. coli alpha-haemolysin (HlyA), while zinc ions did not sustain such a lytic activity. The present data indicate that calcium-binding does not lead to major changes in the secondary structure, judging from circular dichroism spectra. However binding to Ca2+ exposes new hydrophobic residues at the protein surface, as indicated by the increased binding of the fluorescent probe aniline naphtholsulphonate (ANS), and by the increased tendency of the Ca2+-bound protein to self-aggregate. In addition zinc ions are seen to decrease the thermal stability of HlyA which, according to intrinsic fluorescence and differential scanning calorimetry data, is stable below 95 degrees C when bound to calcium, while it undergoes irreversible denaturation above 60 degrees C in the zinc-bound form. Binding to phosphatidylcholine bilayers is quantitatively similar in the presence of both cations, but about one-third of the zinc-bound HlyA is released in the presence of 2 M NaCl. Differential scanning calorimetry of dimyristoylglycerophosphocholine large unilamellar vesicles reveals that Zn2+-HlyA interaction with the lipid bilayer has a strong polar component, while Ca2+-HlyA appears to interact mainly through hydrophobic forces. Experiments in which HIyA transfer is measured from phospholipid vesicles to red blood cells demonstrate that Ca2+ ions promote the irreversible binding of the toxin to bilayers. All these data can be interpreted in terms of a specific Ca2+ effect that increases the surface hydrophobicity of the protein, thus facilitating its irreversible bilayer insertion in the fashion of intrinsic membrane proteins.

The Calcium-binding C-terminal Domain of Escherichia coli α-Hemolysin Is a Major Determinant in the Surface-active Properties of the Protein

α-Hemolysin (HlyA) from Escherichia coli is a protein toxin (1024 amino acids) that targets eukaryotic cell membranes, causing loss of the permeability barrier. HlyA consists of two main regions, an N-terminal domain rich in amphipathic helices, and a C-terminal Ca2+-binding domain containing a Gly- and Asp-rich nonapeptide repeated in tandem 11–17 times. The latter is called the RTX domain and gives its name to the RTX protein family. It had been commonly assumed that membrane interaction occurred mainly if not exclusively through the amphipathic helix domain. However, we have cloned and expressed the C-terminal region of HlyA, containing the RTX domain plus a few stabilizing sequences, and found that it is a potent surface-active molecule. The isolated domain binds Ca2+ with about the same affinity (apparent K0.5 ≈150 μm) as the parent protein HlyA, and Ca2+ binding induces in turn a more compact folding with an increased proportion of β-sheet structure. Both with and without Ca2+ the C-terminal region of HlyA can interact with lipid monolayers spread at an air-water interface. However, the C-terminal domain by itself is devoid of membrane lytic properties. The present results can be interpreted in the light of our previous studies that involved in receptor binding a peptide in the C-terminal region of HlyA. We had also shown experimentally the distinction between reversible membrane adsorption and irreversible lytic insertion of the toxin. In this context, the present data allow us to propose that both major domains of HlyA are directly involved in membrane-toxin interaction, the nonapeptide repeat, calcium-binding RTX domain being responsible for the early stages of HlyA docking to the target membrane.

α‐Haemolysin from E. coli purification and self‐aggregation properties

An improved, straightforward purification procedure for E. coli α‐haemolysin has been developed. The protein exists in the form of large aggregates, held together mainly by hydrophobic forces. In the presence of urea or other chaotropic agents, the size of the aggregates decreases, while the specific activity is increased.

INTERACTION OF THE BACTERIAL PROTEIN TOXIN ALPHA -HAEMOLYSIN WITH MODEL MEMBRANES : PROTEIN BINDING DOES NOT ALWAYS LEAD TO LYTIC ACTIVITY

α‐Haemolysin interaction with model membranes has been investigated by a 2‐fold procedure. First, protein binding has been measured, by a direct method as well as through changes in the intrinsic fluorescence of the protein when incubated with liposomes and divalent cations. Then, the above results have been correlated with the protein lytic activity. The extent of protein binding is not significantly modified by the presence or absence of Ca2+, or by changes in lipid composition, although these factors influence greatly the membrane lytic activity of the protein. Moreover, Ca2+ binding to the toxin must occur prior to protein binding to the bilayer, for a lytic effect to take place.

Permeabilizing action of an antimicrobial lactoferricin-derived peptide on bacterial and artificial membranes.

A synthetic peptide (23 residues) that includes the antibacterial and lipopolysaccharide‐binding regions of human lactoferricin, an antimicrobial sequence of lactoferrin, was used to study its action on cytoplasmic membrane of Escherichia coli 0111 and E. coli phospholipid vesicles. The peptide caused a depolarization of the bacterial cytoplasmic membrane, loss of the pH gradient, and a bactericidal effect on E. coli. Similarly, the binding of the peptide to liposomes dissipated previously created transmembrane electrical and pH gradients. The dramatic consequences of the transmembrane ion flux during the peptide exposure indicate that the adverse effect on bacterial cells occurs at the bacterial inner membrane.