2,170 research outputs found
The importance of the carboxyl portion of the Apx toxins of actinobacillus pleuropneumoniae in eliciting toxin-neutralizing antibodies
Actinobacillus pleuropneumoniae is the organism responsible for porcine pleuropneumonia. The primary virulence factors of A. pleuropneumoniae are three secreted Apx toxins. Apx I and II are cytolytic and hemolytic, while Apx III is only cytolytic. The Apx toxins are pore-forming toxins that promote bacterial multiplication by harming phagocytes infiltrating the respiratory tract of infected swine. Apx-mediated phagocyte damage further intensifies the inflammatory tissue damage associated with porcine pleuropneumonia. The Apx toxins are members of a group of toxins known as RTX toxins. Another RTX toxin previously worked with in this laboratory is the leukotoxin of Pasteurella haemoltyica, which is known to be a primary virulence factor involved in pneumonic pasteurellosis. Several functional domains of the Apx toxins and other RTX toxins have been identified. The carboxyl region containing the repeat domain was of particular interest. This study attempted to answer some preliminary questions about the Apx toxins in relation to work previously done with P. haemolytica leukotoxin in this laboratory. This information will allow future work with the Apx toxins in this laboratory to be more focused on particular aspects of the proteins. The first objective of this study was to examine cross-recognition between the Apx toxins and leukotoxin. This was done by using murine mAbs; ltx-2, ltx-4, and ltx-35, known to neutralize leukotoxin, as well as different samples of rabbit antisera generated against GST-fused peptides of the carboxyl one-third of the IktA, Apx lA, and Apx IIA genes, respectively. Monoclonal antibodies did not cross-react with the Apx toxins. However, rabbit antisera samples did cross-react between the Apx toxins and leukotoxin. The second objective was to evaluate the ability of fusion proteins, containing peptides of the carboxyl portion of Apx I and Apx II, respectively, to elicit anti-Apx toxin antibodies as well as Apx toxin-neutralizing antibodies. Results from these experiments showed that Apx toxin-reactive antibodies can be stimulated by the peptides used, as well as toxin-neutralizing antibodies. The results support earlier reports that the hemolytic and cytotoxic activities of the Apx toxins are independent of each other, as well. This study also confirms previous work from this laboratory showing the importance of the carboxyl portion of the RTX toxins in eliciting toxin-neutralizing antibodies, as well as the finding that post-translational modification of RTX toxin proteins is not required for recognition nor for the capability of the proteins to generate toxin-neutralizing antibodies
Aggregatibacter Actinomycetemcomitans Leukotoxin Utilizes a Cholesterol Recognition/Amino Acid Consensus Site for Membrane Association
Background: A repeats-in-toxin (RTX) leukotoxin and its integrin receptor aggregate in cholesterol-rich lipid rafts. Results: The affinity of the toxin to cholesterol is driven by a cholesterol recognition/amino acid consensus (CRAC) motif. Conclusion: Leukotoxin cytotoxicity is regulated by the CRAC motif. Significance: Other RTX toxins contain this CRAC motif, suggesting a role for cholesterol recognition in RTX cytolysis. © 2013 by The American Society for Biochemistry and Molecular Biology, Inc
In vivo testing of novel vaccine prototypes against Actinobacillus pleuropneumoniae
Actinobacillus pleuropneumoniae (A. pleuropneumoniae) is a Gram-negative bacterium that represents the main cause of porcine pleuropneumonia in pigs, causing significant economic losses to the livestock industry worldwide. A. pleuropneumoniae, as the majority of Gram-negative bacteria, excrete vesicles from its outer membrane (OM), accordingly defined as outer membrane vesicles (OMVs). Thanks to their antigenic similarity to the OM, OMVs have emerged as a promising tool in vaccinology. In this study we describe the in vivo testing of several vaccine prototypes for the prevention of infection by all known A. pleuropneumoniae serotypes. Previously identified vaccine candidates, the recombinant proteins ApfA and VacJ, administered individually or in various combinations with the OMVs, were employed as vaccination strategies. Our data show that the addition of the OMVs in the vaccine formulations significantly increased the specific IgG titer against both ApfA and VacJ in the immunized animals, confirming the previously postulated potential of the OMVs as adjuvant. Unfortunately, the antibody response raised did not translate into an effective protection against A. pleuropneumoniae infection, as none of the immunized groups following challenge showed a significantly lower degree of lesions than the controls. Interestingly, quite the opposite was true, as the animals with the highest IgG titers were also the ones bearing the most extensive lesions in their lungs. These results shed new light on A. pleuropneumoniae pathogenicity, suggesting that antibody-mediated cytotoxicity from the host immune response may play a central role in the development of the lesions typically associated with A. pleuropneumoniae infections
RTX proteins: a highly diverse family secreted by a common mechanism
Repeats-in-toxin (RTX) exoproteins of Gram-negative bacteria form a steadily growing family of proteins with diverse biological functions. Their common feature is the unique mode of export across the bacterial envelope via the type I secretion system and the characteristic, typically nonapeptide, glycine- and aspartate-rich repeats binding Ca2+ ions. In this review, we summarize the current state of knowledge on the organization of rtx loci and on the biological and biochemical activities of therein encoded proteins. Applying several types of bioinformatic screens on the steadily growing set of sequenced bacterial genomes, over 1000 RTX family members were detected, with the biological functions of most of them remaining to be characterized. Activities of the so far characterized RTX family members are then discussed and classified according to functional categories, ranging from the historically first characterized pore-forming RTX leukotoxins, through the large multifunctional enzymatic toxins, bacteriocins, nodulation proteins, surface layer proteins, up to secreted hydrolytic enzymes exhibiting metalloprotease or lipase activities of industrial interest
Cholesterol stimulates the lytic activity of Adenylate Cyclase Toxin on lipid membranes by promoting toxin oligomerization and formation of pores with a greater effective size
Several toxins acting on animal cells present different, but specific, interactions with cholesterol. Bordetella pertussis infects the human respiratory tract and causes whooping cough, a highly contagious and resurgent disease. Its virulence factor adenylate cyclase toxin (ACT) plays an important role in the course of infection. ACT is a pore-forming cytolysin belonging to the Repeats in ToXin (RTX) family of leukotoxins/hemolysins and is capable of permeabilizing several cell types and lipid vesicles. Previously, we observed that in the presence of cholesterol ACT induces greater liposome permeabilization. Similarly, recent reports also implicate cholesterol in the cytotoxicity of an increasing number of pore-forming RTX toxins. However, the mechanistic details by which this sterol promotes the lytic activity of ACT or of these other RTX toxins remain largely unexplored and poorly understood. Here, we have applied a combination of biophysical techniques to dissect the role of cholesterol in pore formation by ACT. Our results indicate that cholesterol enhances the lytic potency of ACT by promoting toxin oligomerization, a step which is indispensable for ACT to accomplish membrane permeabilization and cell lysis. Since our experimental design eliminates the possibility that this cholesterol effect derives from toxin accumulation due to lateral lipid phase segregation, we hypothesize that cholesterol facilitates lytic pore formation, by favoring a toxin conformation more prone to protein-protein interactions and oligomerization. Our data shed light on the complex relationship between lipid membranes and protein toxins acting on these membranes. Coupling cholesterol binding, increased oligomerization and increased lytic activity is likely pertinent for other RTX cytolysins.Rocío Alonso is gratefully acknowledged for excellent technical assistance. This study was supported by grants from the Spanish Ministerio de Economia y Competitividad BFU2017-82758-P (H.O.) and of Basque Government (Grupos Consolidados IT1264-19). D.G.B was recipients of a fellowship from the Bizkaia Biophysics Foundation, and JA was recipient of a fellowship from the Basque Government
Inositol Hexakisphosphate-Induced Autoprocessing of Large Bacterial Protein Toxins
Large bacterial protein toxins autotranslocate functional effector domains to the eukaryotic cell cytosol, resulting in alterations to cellular functions that ultimately benefit the infecting pathogen. Among these toxins, the clostridial glucosylating toxins (CGTs) produced by Gram-positive bacteria and the multifunctional-autoprocessing RTX (MARTX) toxins of Gram-negative bacteria have distinct mechanisms for effector translocation, but a shared mechanism of post-translocation autoprocessing that releases these functional domains from the large holotoxins. These toxins carry an embedded cysteine protease domain (CPD) that is activated for autoprocessing by binding inositol hexakisphosphate (InsP6), a molecule found exclusively in eukaryotic cells. Thus, InsP6-induced autoprocessing represents a unique mechanism for toxin effector delivery specifically within the target cell. This review summarizes recent studies of the structural and molecular events for activation of autoprocessing for both CGT and MARTX toxins, demonstrating both similar and potentially distinct aspects of autoprocessing among the toxins that utilize this method of activation and effector delivery
Membrane Repair Mechanisms against Permeabilization by Pore-Forming Toxins
Permeabilization of the plasma membrane represents an important threat for any cell, since it compromises its viability by disrupting cell homeostasis. Numerous pathogenic bacteria produce pore-forming toxins that break plasma membrane integrity and cause cell death by colloid-osmotic lysis. Eukaryotic cells, in turn, have developed different ways to cope with the effects of such membrane piercing. Here, we provide a short overview of the general mechanisms currently proposed for plasma membrane repair, focusing more specifically on the cellular responses to membrane permeabilization by pore-forming toxins and presenting new data on the effects and cellular responses to the permeabilization by an RTX (repeats in toxin) toxin, the adenylate cyclase toxin-hemolysin secreted by the whooping cough bacterium Bordetella pertussis, which we have studied in the laboratory.This study was supported by grants from the Basque Government (Grupos Consolidados IT849-13) and grant from the Spanish Ministerio de Economia y Competitividad (BFU2017-82758-PAEI/FEDER, UE)
GtxA from Gallibacterium anatis, a cytolytic RTX-toxin with a novel domain organisation
Gallibacterium anatis is a pathogen in chickens and other avian species where it is a significant cause of salpingitis and peritonitis. We found that bacterial cells and cell-free, filter-sterilised culture supernatant from the haemolytic G. anatis biovar haemolytica were highly cytotoxic towards avian-derived macrophage-like cells (HD11). We obtained the genome sequence of G. anatis 12656-12 and used a rational approach to identify a gene predicted to encode a 2026 amino acid RTX-toxin, which we named GtxA (Gallibacterium toxin). The construction of a gtxA knock-out mutant showed gtxA to be responsible for G. anatis’ haemolytic and leukotoxic activity. In addition, Escherichia coli expressing gtxA and an adjacent acyltransferase, gtxC, became cytolytic. GtxA was expressed during in vitro growth and was localised in the extracellular protein fraction in a growth phase dependent manner. GtxA had an unusual modular structure; the C-terminal 1000 amino acids of GtxA were homologous to the classical pore-forming RTX-toxins in other members of Pasteurellaceae. In contrast, the N-terminal approximately 950 amino acids had few significant matches in sequence databases. Expression of truncated GtxA proteins demonstrated that the C-terminal RTX-domain had a lower haemolytic activity than the full-length toxin, indicating that the N-terminal domain was required for maximal haemolytic activity. Cytotoxicity towards HD11 cells was not detected with the C-terminal alone, suggesting that the N-terminal domain plays a critical role for the leukotoxicity
Understanding the Mechanism of Translocation of Adenylate Cyclase Toxin across Biological Membranes
Adenylate cyclase toxin (ACT) is one of the principal virulence factors secreted by the whooping cough causative bacterium Bordetella pertussis, and it has a critical role in colonization of the respiratory tract and establishment of the disease. ACT targets phagocytes via binding to the CD11b/CD18 integrin and delivers its N-terminal adenylate cyclase (AC) domain directly to the cell cytosol, where it catalyzes unregulated conversion of cytosolic ATP into cAMP upon activation by binding to cellular calmodulin. High cAMP levels disrupt bactericidal functions of the immune cells, ultimately leading to cell death. In spite of its relevance in the ACT biology, the mechanism by which its ≈400 amino acid-long AC domain is transported through the target plasma membrane, and is released into the target cytosol, remains enigmatic. This article is devoted to refresh our knowledge on the mechanism of AC translocation across biological membranes. Two models, the so-called “two-step model” and the recently-proposed “toroidal pore model”, will be considered.This study was supported by grants from the Basque Government (Grupos Consolidados IT849-13 and ETORTEK Program KK-2015/0000089). A.E. was recipient of a fellowship from the University of the Basque Country (UPV/EH) and D.G.-B. was recipient of a fellowship from the Bizkaia Biophysics Foundation
Molecular and virulence characteristics of an outer membrane-associated RTX exoprotein in Pasteurella pneumotropica
<p>Abstract</p> <p>Background</p> <p><it>Pasteurella pneumotropica </it>is a ubiquitous bacterium that is frequently isolated from laboratory rodents and causes various clinical symptoms in immunodeficient animals. Currently two RTX toxins, PnxIA and PnxIIA, which are similar to hemolysin-like high-molecular-weight exoproteins are known in this species. In this study, we identified and analyzed a further RTX toxin named PnxIIIA and the corresponding type I secretion system.</p> <p>Results</p> <p>The RTX exoprotein, PnxIIIA, contains only a few copies of the RTX repeat-like sequence and 3 large repeat sequences that are partially similar to the outer membrane protein found in several prokaryotes. Recombinant PnxIIIA protein (rPnxIIIA) was cytotoxic toward J774A.1 mouse macrophage cells, whereas cytotoxicity was attenuated by the addition of anti-CD11a monoclonal antibody. rPnxIIIA could bind to extracellular matrices (ECMs) and cause hemagglutination of sheep erythrocytes. Binding was dependent on the 3 large repeat sequences in PnxIIIA. Protein interaction analyses indicated that PnxIIIA is mainly localized in the outer membrane of <it>P. pneumotropica </it>ATCC 35149 in a self-assembled oligomeric form. PnxIIIA is less cytotoxic to J774A.1 cells than PnxIA and PnxIIA.</p> <p>Conclusions</p> <p>The results implicate that PnxIIIA is located on the cell surface and participates in adhesion to ECMs and enhanced hemagglutination in the rodent pathogen <it>P. pneumotropica</it>.</p
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