Interaction of <i>Escherichia coli</i> hemolysin with biological membranes

Schindel, Christine; Zitzer, Alexander; Schulte, Berit; Gerhards, A.; Stanley, Peter; Hughes, Colin; Koronakis, Vassilis; Bhakdi, Sucharit; Palmer, Michaël

doi:10.1046/j.1432-1327.2001.01937.x

Cited by 57 publications

(52 citation statements)

References 26 publications

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“…28,31 Incubation of platelets with WAM582, a nonpathogenic K-12 laboratory strain of E coli that encodes for the wild-type hlyA operon, induced Bcl-x L degradation within 2 hours ( Figure 3C). In contrast, WAM783, which carries the hlyA operon lacking hlyC, failed to induce Bcl-x L degradation in incubations lasting up to 8 hours ( Figure 3C).…”

Section: Uti89 Did Not Degrade Bcl-x L Protein In Platelets (Supplemementioning

confidence: 98%

Bacteria differentially induce degradation of Bcl-xL, a survival protein, by human platelets

Kraemer

Campbell

Schwertz

et al. 2012

Blood

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Bacteria can enter the bloodstream in response to infectious insults. Bacteremia elicits several immune and clinical complications, including thrombocytopenia. A primary cause of thrombocytopenia is shortened survival of platelets. We demonstrate that pathogenic bacteria induce apoptotic events in platelets that include calpain-mediated degradation of Bcl-x L , an essential regulator of platelet survival. Specifically, bloodstream bacterial isolates from patients with sepsis induce lateral condensation of actin, impair mitochondrial membrane potential, and degrade Bcl-x L protein in platelets. Bcl-x L protein degradation is enhanced when platelets are exposed to pathogenic Escherichia coli that produce the poreforming toxin ␣-hemolysin, a response that is markedly attenuated when the gene is deleted from E coli. We also found that nonpathogenic E coli gain degrading activity when they are forced to express ␣-hemolysin. Like ␣-hemolysin, purified ␣-toxin readily degrades Bcl-x L protein in platelets, as do clinical Staphylococcus aureus isolates that produce ␣-toxin. Inhibition of calpain activity, but not the proteasome, rescues Bcl-x L protein degradation in platelets coincubated with pathogenic E coli including ␣-hemolysin producing strains. This is the first evidence that pathogenic bacteria can trigger activation of the platelet intrinsic apoptosis program and our results suggest a new mechanism by which bacterial pathogens might cause thrombocytopenia in patients with bloodstream infections. IntroductionBacteremia is a leading cause of morbidity and mortality in the United States and worldwide. 1,2 Risk factors for bacteremia include indwelling catheters, 3 trauma, 4 and surgery. 5 Bloodstream infections also are found frequently in patients with malignancies, 6 endocarditis, 7 and urinary tract infections. 8 In severe cases, bacteremia elicits a vigorous immune response that results in sepsis and septic shock. 9 Bloodstream infections often are accompanied by thrombocytopenia. 10 Adverse clinical outcomes commonly are observed in thrombocytopenic patients with documented bacteremia, and the severity of thrombocytopenia is associated with an increase in the rate of mortality of patients in the intensive care unit. 10,11 It generally is presumed that the infectious milieu induces thrombocytopenia by activating platelets that subsequently deposit in microvascular thrombi or get cleared from the circulation. 12 Indeed, bacteria or bacterial products can induce platelet activation by directly or indirectly binding to surface receptors such as integrin ␣ IIb ␤ 3 , GPIb, and TLRs. 13 However, the precise mechanisms that underpin bacteremia-induced thrombocytopenia remain poorly defined.In addition to the biochemical pathways that regulate classic platelet functional responses such as aggregation and adhesion, it has been demonstrated recently that megakaryocytes and platelets possess an intrinsic apoptosis program. 14,15 Key components of the platelet apoptotic pathway include the prosurvival protein Bcl-x L and...

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Section: Uti89 Did Not Degrade Bcl-x L Protein In Platelets (Supplemementioning

confidence: 98%

Bacteria differentially induce degradation of Bcl-xL, a survival protein, by human platelets

Kraemer

Campbell

Schwertz

et al. 2012

Blood

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“…Recent data indicate that insertion may take place in the absence of Ca 2ϩ (9,10), but Ca 2ϩ binding to the nonapeptide repeat domain is essential for membrane lysis (9,11,12). Note that the Ca 2ϩ -binding domain is located near the protein C terminus, whereas the membrane insertion domain is located near the N terminus (9,10,13). The present study is devoted to exploring the early stages of HlyA interaction with the target cell, namely its binding to the surface receptor.…”

Section: ␣-Hemolysinmentioning

confidence: 99%

“…HlyA first binds a receptor on the cell surface, a ␤ 2 -integrin in leukocytes (7) or glycophorin in red blood cells (8), and then becomes inserted in the cell membrane. Recent data indicate that insertion may take place in the absence of Ca 2ϩ (9,10), but Ca 2ϩ binding to the nonapeptide repeat domain is essential for membrane lysis (9,11,12). Note that the Ca 2ϩ -binding domain is located near the protein C terminus, whereas the membrane insertion domain is located near the N terminus (9,10,13).…”

Section: ␣-Hemolysinmentioning

confidence: 99%

A Receptor-binding Region in Escherichia coli α-Haemolysin

Cortajarena¹,

Goñi

Ostolaza

2003

Journal of Biological Chemistry

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Escherichia coli ␣-hemolysin (HlyA) is a 107-kDa protein toxin with a wide range of mammalian target cells. Previous work has shown that glycophorin is a specific receptor for HlyA in red blood cells (Cortajarena, A. L., Goñ i, F. M., and Ostolaza, H. (2001) J. Biol. Chem. 276, 12513-12519). The present study was aimed at identifying the glycophorin-binding region in the toxin. Data in the literature pointed to a short amino acid sequence near the C terminus as a putative receptor-binding domain. Previous sequence analyses of several homologous toxins that belong, like HlyA, to the so-called RTX toxin family revealed a conserved region that corresponded to residues 914 -936 of HlyA. We therefore prepared a deletion mutant lacking these residues (HlyA⌬914 -936) and found that its hemolytic activity was decreased by 10,000-fold with respect to the wild type. This deletion mutant was virtually unable to bind human and horse red blood cells or to bind pure glycophorin in an affinity column. 1 is a 107-kDa protein toxin secreted by pathogenic strains of Escherichia coli. It is a member of the so-called "RTX family," a group of proteins characterized by the presence of a Gly-and Asp-rich nonapeptide sequence repeated in tandem near the protein C terminus (for reviews, see Refs. 1-5). These repeats constitute a Ca 2ϩ -binding domain whose structure has been solved at high resolution for a non-toxin member of the RTX family, the alkaline protease from Pseudomonas aeruginosa (6). HlyA first binds a receptor on the cell surface, a ␤ 2 -integrin in leukocytes (7) or glycophorin in red blood cells (8), and then becomes inserted in the cell membrane. Recent data indicate that insertion may take place in the absence of Ca 2ϩ (9, 10), but Ca 2ϩ binding to the nonapeptide repeat domain is essential for membrane lysis (9,11,12). Note that the Ca 2ϩ -binding domain is located near the protein C terminus, whereas the membrane insertion domain is located near the N terminus (9, 10, 13). The present study is devoted to exploring the early stages of HlyA interaction with the target cell, namely its binding to the surface receptor. In particular, our investigation is aimed at the region(s) of the protein that bind(s) the receptor glycophorin on mammalian erythrocytes (8). A number of previous studies suggest that a region between the repeat domain and the C terminus may be involved in binding this specific receptor. For example, Bejerano et al. (14) have described two amino acid "blocks," located after the nonapeptide repeats, in the C terminus of the adenylate cyclase toxin (another member of the RTX family). Block A (15 amino acids) is essential for the toxic activity since it is required for the toxin binding and insertion into the membrane. Deletion of block B, however, does not affect the toxin activity. HlyA possesses homologous A and B blocks (Fig. 1), and it has been shown (14) that deletion of a region that includes the last two residues of block A, the connection between the blocks, and the first nine amino acids of block B...

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“…They are considered a virulence factor from these microorganisms and also a member of the RTX (repeats in toxin) protein family (Welch, 2001). The presence of amphipathic and hydrophilic domains confers to the protein an overall amphiphilic character, which explains its tendency both to aggregate and to interact with membranes (Hyland et al, 2001;Schindel et al, 2001;Soloaga et al, 1999).…”

Section: Hemolysin-domain Proteinmentioning

confidence: 99%

An insight into the sialome of the blood-sucking bug Triatoma infestans, a vector of Chagas’ disease

Assumpção

Francischetti

Andersen

et al. 2008

Insect Biochemistry and Molecular Biology

117

132

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Triatoma infestans is a hemiptera, vector of Chagas' disease, that feeds exclusively on vertebrate blood in all life stages. Hematophagous insects' salivary glands (SG) produce potent pharmacological compounds that counteract host hemostasis, including anti-clotting, anti-platelet, and vasodilatory molecules. To obtain a further insight into the salivary biochemical and pharmacological complexity of this insect, a cDNA library from its salivary glands was randomly sequenced. Also, salivary proteins were submitted to two dimentional gel (2D-gel) electrophoresis followed by MS analysis. We present the analysis of a set of 1,534 (SG) cDNA sequences, 645 of which coded for proteins of a putative secretory nature. Most salivary proteins described as lipocalins matched peptide sequences obtained from proteomic results.

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Interaction of Escherichia coli hemolysin with biological membranes

Cited by 57 publications

References 26 publications

Bacteria differentially induce degradation of Bcl-xL, a survival protein, by human platelets

Bacteria differentially induce degradation of Bcl-xL, a survival protein, by human platelets

A Receptor-binding Region in Escherichia coli α-Haemolysin

An insight into the sialome of the blood-sucking bug Triatoma infestans, a vector of Chagas’ disease

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