Literature DB >> 23027535

Bacillus anthracis lethal toxin reduces human alveolar epithelial barrier function.

Marybeth Langer1, Elizabeth Stewart Duggan, John Leland Booth, Vineet Indrajit Patel, Ryan A Zander, Robert Silasi-Mansat, Vijay Ramani, Tibor Zoltan Veres, Frauke Prenzler, Katherina Sewald, Daniel M Williams, Kenneth Mark Coggeshall, Shanjana Awasthi, Florea Lupu, Dennis Burian, Jimmy Dale Ballard, Armin Braun, Jordan Patrick Metcalf.   

Abstract

The lung is the site of entry for Bacillus anthracis in inhalation anthrax, the deadliest form of the disease. Bacillus anthracis produces virulence toxins required for disease. Alveolar macrophages were considered the primary target of the Bacillus anthracis virulence factor lethal toxin because lethal toxin inhibits mouse macrophages through cleavage of MEK signaling pathway components, but we have reported that human alveolar macrophages are not a target of lethal toxin. Our current results suggest that, unlike human alveolar macrophages, the cells lining the respiratory units of the lung, alveolar epithelial cells, are a target of lethal toxin in humans. Alveolar epithelial cells expressed lethal toxin receptor protein, bound the protective antigen component of lethal toxin, and were subject to lethal-toxin-induced cleavage of multiple MEKs. These findings suggest that human alveolar epithelial cells are a target of Bacillus anthracis lethal toxin. Further, no reduction in alveolar epithelial cell viability was observed, but lethal toxin caused actin rearrangement and impaired desmosome formation, consistent with impaired barrier function as well as reduced surfactant production. Therefore, by compromising epithelial barrier function, lethal toxin may play a role in the pathogenesis of inhalation anthrax by facilitating the dissemination of Bacillus anthracis from the lung in early disease and promoting edema in late stages of the illness.

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Year:  2012        PMID: 23027535      PMCID: PMC3497415          DOI: 10.1128/IAI.01011-12

Source DB:  PubMed          Journal:  Infect Immun        ISSN: 0019-9567            Impact factor:   3.441


  65 in total

1.  HTI56, an integral membrane protein specific to human alveolar type I cells.

Authors:  L G Dobbs; R F Gonzalez; L Allen; D K Froh
Journal:  J Histochem Cytochem       Date:  1999-02       Impact factor: 2.479

2.  Flow cytometric identification and isolation of hypertrophic type II pneumocytes after partial pneumonectomy.

Authors:  B D Uhal; S R Rannels; D E Rannels
Journal:  Am J Physiol       Date:  1989-09

3.  Secondary necrosis is a source of proteolytically modified forms of specific intracellular autoantigens: implications for systemic autoimmunity.

Authors:  X Wu; C Molinaro; N Johnson; C A Casiano
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4.  Detection of anthrax toxin in the serum of animals infected with Bacillus anthracis by using engineered immunoassays.

Authors:  Robert Mabry; Kathleen Brasky; Robert Geiger; Ricardo Carrion; Gene B Hubbard; Stephen Leppla; Jean L Patterson; George Georgiou; B L Iverson
Journal:  Clin Vaccine Immunol       Date:  2006-06

5.  Modelling the incubation period of anthrax.

Authors:  Ron Brookmeyer; Elizabeth Johnson; Sarah Barry
Journal:  Stat Med       Date:  2005-02-28       Impact factor: 2.373

6.  Cellular effects of heparin on the production and release of tissue factor pathway inhibitor in human endothelial cells in culture.

Authors:  C Lupu; E Poulsen; S Roquefeuil; A D Westmuckett; V V Kakkar; F Lupu
Journal:  Arterioscler Thromb Vasc Biol       Date:  1999-09       Impact factor: 8.311

7.  Extracellular signal-regulated kinases 1/2 control claudin-2 expression in Madin-Darby canine kidney strain I and II cells.

Authors:  Joshua H Lipschutz; Shixiong Li; Amy Arisco; Daniel F Balkovetz
Journal:  J Biol Chem       Date:  2004-11-29       Impact factor: 5.157

8.  Characterization of macrophage sensitivity and resistance to anthrax lethal toxin.

Authors:  A M Friedlander; R Bhatnagar; S H Leppla; L Johnson; Y Singh
Journal:  Infect Immun       Date:  1993-01       Impact factor: 3.441

9.  Bacillus anthracis lethal toxin induces TNF-alpha-independent hypoxia-mediated toxicity in mice.

Authors:  Mahtab Moayeri; Diana Haines; Howard A Young; Stephen H Leppla
Journal:  J Clin Invest       Date:  2003-09       Impact factor: 14.808

10.  Microsphere and dilution techniques for the determination of blood flows and volumes in conscious mice.

Authors:  R W Barbee; B D Perry; R N Ré; J P Murgo
Journal:  Am J Physiol       Date:  1992-09
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  14 in total

1.  Gene expression profiling of primary human type I alveolar epithelial cells exposed to Bacillus anthracis spores reveals induction of neutrophil and monocyte chemokines.

Authors:  J Leland Booth; Elizabeth S Duggan; Vineet I Patel; Wenxin Wu; Dennis M Burian; David C Hutchings; Vicky L White; K Mark Coggeshall; Mikhail G Dozmorov; Jordan P Metcalf
Journal:  Microb Pathog       Date:  2018-04-25       Impact factor: 3.738

2.  Bacillus anthracis lethal toxin, but not edema toxin, increases pulmonary artery pressure and permeability in isolated perfused rat lungs.

Authors:  Xizhong Cui; Wanying Xu; Pranita Neupane; Andie Weiser-Schlesinger; Ray Weng; Benjamin Pockros; Yan Li; Mahtab Moayeri; Stephen H Leppla; Yvonne Fitz; Peter Q Eichacker
Journal:  Am J Physiol Heart Circ Physiol       Date:  2019-02-15       Impact factor: 4.733

3.  Bacillus cereus Certhrax ADP-ribosylates vinculin to disrupt focal adhesion complexes and cell adhesion.

Authors:  Nathan C Simon; Joseph T Barbieri
Journal:  J Biol Chem       Date:  2014-02-26       Impact factor: 5.157

4.  Bacillus anthracis spore movement does not require a carrier cell and is not affected by lethal toxin in human lung models.

Authors:  J Leland Booth; Elizabeth S Duggan; Vineet I Patel; Marybeth Langer; Wenxin Wu; Armin Braun; K Mark Coggeshall; Jordan P Metcalf
Journal:  Microbes Infect       Date:  2016-06-16       Impact factor: 2.700

5.  RUNX3-dependent oxidative epithelial-to-mesenchymal transition in methamphetamine-induced chronic lung injury.

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Review 6.  Desmosomes in acquired disease.

Authors:  Sara N Stahley; Andrew P Kowalczyk
Journal:  Cell Tissue Res       Date:  2015-03-21       Impact factor: 5.249

7.  RIG-I and TLR3 are both required for maximum interferon induction by influenza virus in human lung alveolar epithelial cells.

Authors:  Wenxin Wu; Wei Zhang; Elizabeth S Duggan; J Leland Booth; Ming-Hui Zou; Jordan P Metcalf
Journal:  Virology       Date:  2015-04-11       Impact factor: 3.616

Review 8.  Tight Junctions, the Epithelial Barrier, and Toll-like Receptor-4 During Lung Injury.

Authors:  Nachiket M Godbole; Asif Alam Chowdhury; Neha Chataut; Shanjana Awasthi
Journal:  Inflammation       Date:  2022-07-02       Impact factor: 4.657

9.  Bacillus anthracis has two independent bottlenecks that are dependent on the portal of entry in an intranasal model of inhalational infection.

Authors:  David E Lowe; Stephen M C Ernst; Christine Zito; Jason Ya; Ian J Glomski
Journal:  Infect Immun       Date:  2013-09-16       Impact factor: 3.441

10.  The sepsis model: an emerging hypothesis for the lethality of inhalation anthrax.

Authors:  Kenneth Mark Coggeshall; Florea Lupu; Jimmy Ballard; Jordan P Metcalf; Judith A James; Darise Farris; Shinichiro Kurosawa
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