Oliver Knapp

Structural and functional characterization of an essential RTX subdomain of Bordetella pertussis adenylate cyclase toxin

The adenylate cyclase toxin (CyaA) is one of the major virulence factors of Bordetella pertussis, the causative agent of whooping cough. CyaA is able to invade eukaryotic cells by a unique mechanism that consists in a calcium-dependent, direct translocation of the CyaA catalytic domain across the plasma membrane of the target cells. CyaA possesses a series of a glycine- and aspartate-rich nonapeptide repeats (residues 1006–1613) of the prototype GGXG(N/D)DX(L/I/F)X (where X represents any amino acid) that are characteristic of the RTX (repeat in toxin) family of bacterial cytolysins. These repeats are arranged in a tandem fashion and may fold into a characteristic parallel β-helix or β-roll motif that constitutes a novel type of calcium binding structure, as revealed by the three-dimensional structure of the Pseudomonas aeruginosa alkaline protease. Here we have characterized the structure-function relationships of various fragments from the CyaA RTX subdomain. Our results indicate that the RTX functional unit includes both the tandem repeated nonapeptide motifs and the adjacent polypeptide segments, which are essential for the folding and calcium responsiveness of the RTX module. Upon calcium binding to the RTX repeats, a conformational rearrangement of the adjacent non-RTX sequences may act as a critical molecular switch to trigger the CyaA entry into target cells.

Clostridium perfringens delta toxin is sequence related to beta toxin, NetB, and Staphylococcus pore-forming toxins, but shows functional differences.

Clostridium perfringens produces numerous toxins, which are responsible for severe diseases in man and animals. Delta toxin is one of the three hemolysins released by a number of C. perfringens type C and possibly type B strains. Delta toxin was characterized to be cytotoxic for cells expressing the ganglioside GM2 in their membrane. Here we report the genetic characterization of Delta toxin and its pore forming activity in lipid bilayers. Delta toxin consists of 318 amino acids, its 28 N-terminal amino acids corresponding to a signal peptide. The secreted Delta toxin (290 amino acids; 32619 Da) is a basic protein (pI 9.1) which shows a significant homology with C. perfringens Beta toxin (43% identity), with C. perfringens NetB (40% identity) and, to a lesser extent, with Staphylococcus aureus alpha toxin and leukotoxins. Recombinant Delta toxin showed a preference for binding to GM2, in contrast to Beta toxin, which did not bind to gangliosides. It is hemolytic for sheep red blood cells and cytotoxic for HeLa cells. In artificial diphytanoyl phosphatidylcholine membranes, Delta and Beta toxin formed channels. Conductance of the channels formed by Delta toxin, with a value of about 100 pS to more than 1 nS in 1 M KCl and a membrane potential of 20 mV, was higher than those formed by Beta toxin and their distribution was broader. The results of zero-current membrane potential measurements and single channel experiments suggest that Delta toxin forms slightly anion-selective channels, whereas the Beta toxin channels showed a preference for cations under the same conditions. C. perfringens Delta toxin shows a significant sequence homolgy with C. perfringens Beta and NetB toxins, as well as with S. aureus alpha hemolysin and leukotoxins, but exhibits different channel properties in lipid bilayers. In contrast to Beta toxin, Delta toxin recognizes GM2 as receptor and forms anion-selective channels.

Segments Crucial for Membrane Translocation and Pore-forming Activity of Bordetella Adenylate Cyclase Toxin

Bordetella adenylate cyclase toxin-hemolysin (CyaA, AC-Hly, or ACT) permeabilizes cell membranes by forming small cation-selective (hemolytic) pores and subverts cellular signaling by delivering into host cells an adenylate cyclase (AC) enzyme that converts ATP to cAMP. Both AC delivery and pore formation were previously shown to involve a predicted amphipathic α-helix502–522 containing a pair of negatively charged Glu509 and Glu516 residues. Another predicted transmembrane α-helix565–591 comprises a Glu570 and Glu581 pair. We examined the roles of these glutamates in the activity of CyaA. Substitutions of Glu516 increased specific hemolytic activity of CyaA by two different molecular mechanisms. Replacement of Glu516 by positively charged lysine residue (E516K) increased the propensity of CyaA to form pores, whereas proline (E516P) or glutamine (E516Q) substitutions extended the lifetime of open single pore units. All three substitutions also caused a drop of pore selectivity for cations. Substitutions of Glu570 and Glu581 by helix-breaking proline or positively charged lysine residue reduced (E570K, E581P) or ablated (E570P, E581K) AC membrane translocation. Moreover, E570P, E570K, and E581P substitutions down-modulated also the specific hemolytic activity of CyaA. In contrast, the E581K substitution enhanced the hemolytic activity of CyaA 4 times, increasing both the frequency of formation and lifetime of toxin pores. Negative charge at position 570, but not at position 581, was found to be essential for cation selectivity of the pore, suggesting a role of Glu570 in ion filtering inside or close to pore mouth. The pairs of glutamate residues in the predicted transmembrane segments of CyaA thus appear to play a key functional role in membrane translocation and pore-forming activities of CyaA.

Oligomerization is involved in pore formation by Bordetella adenylate cyclase toxin

The Bordetella adenylate cyclase‐hemolysin (CyaA, ACT, or AC‐Hly) is a multifunctional toxin. Simultaneously with promoting calcium ion entry, CyaA delivers into host cells an adenylate cyclase enzyme (AC) and permeabilizes cell membrane by forming small cation‐selective pores. Indirect evidence suggested that these two activities were accomplished by different membraneinserted CyaA conformers, one acting as an AC‐delivering monomer and the other as an uncharacterized poreforming oligomer. We tested this model by directly detecting toxin oligomers in cell membrane and by assessing oligomerization of specific mutants with altered poreforming properties. CyaA oligomers were revealed in sheep erythrocyte membranes by immunogold labeling and directly demonstrated by pulldown of membraneinserted CyaA together with biotinylated CyaAAC‐ toxoid. Membrane oligomers of CyaAcould also be resolved by nondenaturing electrophoresis of mild detergent extracts of erythrocytes. Furthermore, CyaA mutants exhibiting enhanced (E581K) or reduced (E570K+E581P) specific hemolytic and pore‐forming activity were found to exhibit also a correspondingly enhanced or reduced propensity to form oligomers in erythrocyte membranes. On the other hand, processed CyaA, with the AC domain cleaved off by erythrocyte proteases, was detected only in a monomeric form excluded from the oligomers of unprocessed CyaA. These results provide the first direct evidence that oligomerization is involved in formation of CyaApores in target membranes and that translocation of the AC domain across cell membrane may be accomplished by monomelic CyaA.—Vojtova‐Vodolanova, J., Basler, M., Osicka, R., Knapp, O., Maier, E., Cerny, J., Benada, O., Benz, R., Sebo, P. Oligomerization is involved in pore formation by Bordetella adenylate cyclase toxin. FASEB J. 23, 2831–2843 (2009). www.fasebj.org

Clostridium septicum alpha-toxin forms pores and induces rapid cell necrosis

Alpha-toxin is the unique lethal virulent factor produced by Clostridium septicum, which causes traumatic or non-traumatic gas gangrene and necrotizing enterocolitis in humans. Here, we analyzed channel formation of the recombinant septicum alpha-toxin and characterized its activity on living cells. Recombinant septicum alpha-toxin induces the formation of ion-permeable channels with a single-channel conductance of about 175pS in 0.1M KCl in lipid bilayer membranes, which is typical for a large diffusion pore. Septicum alpha-toxin channels remained mostly in the open configuration, displayed no lipid specificity, and exhibited slight anion selectivity. Septicum alpha-toxin caused a rapid decrease in the transepithelial electrical resistance of MDCK cell monolayers grown on filters, and induced a rapid cell necrosis in a variety of cell lines, characterized by cell permeabilization to propidium iodide without DNA fragmentation and activation of caspase-3. Septicum alpha-toxin also induced a rapid K(+) efflux and ATP depletion. Incubation of the cells in K(+)-enriched medium delayed cell death caused by septicum alpha-toxin or epsilon-toxin, another potent pore-forming toxin, suggesting that the rapid loss of intracellular K(+) represents an early signal of pore-forming toxins-mediated cell necrosis.

Identification of the channel forming domain of Clostridium perfringens epsilon-toxin (ETX)

Epsilon-toxin (ETX) is a potent toxin produced by Clostridium perfringens strains B and D. The bacteria are important pathogens in domestic animals and cause edema mediated by ETX. This toxin acts most likely by heptamer formation and rapid permeabilization of target cell membranes for monovalent anions and cations followed by a later entry of calcium. In this study, we compared the primary structure of ETX with that of the channel-forming stretches of a variety of binding components of A-B-types of toxins such as Anthrax protective antigen (PA), C2II of C2-toxin and Ib of Iota-toxin and found a remarkable homology to amino acids 151-180 of ETX. Site-directed mutagenesis of amino acids within the putative channel-forming domain resulted in changes of cytotoxicity and effects on channel characteristics in lipid bilayer experiments including changes of selectivity and partial channel block by methanethiosulfonate (MTS) reagents and antibodies against His(6)-tags from the trans-side of the lipid bilayer membranes.

The Aerolysin-Like Toxin Family of Cytolytic, Pore-Forming Toxins

Pore-forming toxins (PFTs) represent the largest known group of bacterial protein toxins to date. Membrane insertion and subsequent pore-formation occurs after initial binding to cell-surface receptor and oligomerization. Aerolysin, a toxin produced by the Gram-negative bacterium Aeromonas hydrophila and related species, belongs to the PFT group and shares a common mechanism of action involving  -barrel structures resulting from the assembly of  - hairpins from individual toxin monomers into a heptamer. Aerolysin is also the name given to structurally and mechanistically related toxins called the aerolysin-like toxin family. A universal characteristic of this toxin family involves the diverse life forms that synthesize these proteins throughout Nature. Examples include: 1) epsilon-toxin and septicum-alpha-toxin produced by anaerobic, Gram-positive Clostridium species; 2) enterolobin by the Brazilian tree Enterolobium contortisiliquum; 3) a mushroom toxin Laetiporus sulphureus lectin (LSL); 4) mosquitocidal toxins (Mtxs) from the Gram-positive bacteria Bacillus sphaericus and parasporine-2 from Bacillus thuringiensis; and 6) hydralysins from the tiny aquatic animal Chlorohydra viridis. The following review provides an overview of the different members within the aerolysin-like toxin family.

The Aerolysin-Like Toxin Family of Cytolytic, Pore-Forming Toxins~!2009-08-20~!2009-09-17~!2010-03-09~!

Pore-forming toxins (PFTs) represent the largest known group of bacterial protein toxins to date. Membrane insertion and subsequent pore-formation occurs after initial binding to cell-surface receptor and oligomerization. Aerolysin, a toxin produced by the Gram-negative bacterium Aeromonas hydrophila and related species, belongs to the PFT group and shares a common mechanism of action involving -barrel structures resulting from the assembly of hairpins from individual toxin monomers into a heptamer. Aerolysin is also the name given to structurally and mechanistically related toxins called the aerolysin-like toxin family. A universal characteristic of this toxin family involves the diverse life forms that synthesize these proteins throughout Nature. Examples include: 1) epsilon-toxin and septicum-alpha-toxin produced by anaerobic, Gram-positive Clostridium species; 2) enterolobin by the Brazilian tree Enterolobium contortisiliquum; 3) a mushroom toxin Laetiporus sulphureus lectin (LSL); 4) mosquitocidal toxins (Mtxs) from the Gram-positive bacteria Bacillus sphaericus and parasporine-2 from Bacillus thuringiensis; and 6) hydralysins from the tiny aquatic animal Chlorohydra viridis. The following review provides an overview of the different members within the aerolysin-like toxin family. keywords: Pore-forming toxins, aerolysin, septicum-alpha-toxin, enterolobin, epsilon-toxin, Laetiporus sulphureus lectin.

Pore-forming activity of clostridial binary toxins.

Clostridial binary toxins (Clostridium perfringens Iota toxin, Clostridium difficile transferase, Clostridium spiroforme toxin, Clostridium botulinum C2 toxin) as Bacillus binary toxins, including Bacillus anthracis toxins consist of two independent proteins, one being the binding component which mediates the internalization into cell of the intracellularly active component. Clostridial binary toxins induce actin cytoskeleton disorganization through mono-ADP-ribosylation of globular actin and are responsible for enteric diseases. Clostridial and Bacillus binary toxins share structurally and functionally related binding components which recognize specific cell receptors, oligomerize, form pores in endocytic vesicle membrane, and mediate the transport of the enzymatic component into the cytosol. Binding components retain the global structure of pore-forming toxins (PFTs) from the cholesterol-dependent cytotoxin family such as perfringolysin. However, their pore-forming activity notably that of clostridial binding components is more related to that of heptameric PFT family including aerolysin and C. perfringens epsilon toxin. This review focuses upon pore-forming activity of clostridial binary toxins compared to other related PFTs. This article is part of a Special Issue entitled: Pore-Forming Toxins edited by Mauro Dalla Serra and Franco Gambale.

Residues involved in the pore-forming activity of the Clostridium perfringens iota toxin.

Clostridium perfringens iota toxin is a binary toxin that is organized into enzyme (Ia) and binding (Ib) components. Ib forms channels in lipid bilayers and mediates the transport of Ia into the target cells. Here we show that Ib residues 334–359 contain a conserved pattern of alternating hydrophobic and hydrophilic residues forming two amphipathic β‐strands involved in membrane insertion and channel formation. This stretch of amino acids shows remarkable structural and functional analogies with the β‐pore‐forming domain of C. perfringens epsilon toxin. Several mutations within the two amphipathic β‐strands affected pore formation, single‐channel conductance and ion selectivity (S339E‐S341E, Q345H N346E) confirming their involvement in channel formation. F454 of Ib corresponds to the Φ‐clamp F427 of anthrax protective antigen and F428 of C2II binary toxins. The mutation F454A resulted in a loss of cytotoxicity and strong increase in single‐channel conductance (500 pS as compared with 85 pS in 1 M KCl) with a slight decrease in cation selectivity, indicating that the Φ‐clamp is highly conserved and crucial for binary toxin activity. In contrast, the mutants Q367D, N430D, L443E had no or only minor effects on Ib properties, while T360I, T360A and T360W caused a dramatic effect on ion selectivity and single‐channel conductance, indicating gross disturbance of the oligomer structure. This suggests that, at least in the iota toxin family, T360 has a structural role in the pore organization. Moreover, introduction of charged residues within the channel (S339E‐S341E) or in the vestibule (Q367D, N430D and L443E) had virtually no effect on chloroquine or Ia binding, whereas F454A, T360I, T360A and T360W strongly decreased the chloroquine and Ia affinity to Ib. These results support that distinct residues within the vestibule interact with chloroquine and Ia or are responsible for channel structure, while the channel lining amino acids play a less important role.