The Effect of Lethal Toxin on the Respiratory Epithelium. Fakultät für Chemie und Pharmazie - Digitale Hochschulschriften der LMU - Teil 02/06
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Inhalational anthrax is an acute infectious disease caused by exposure of the lungs to B. anthracis spores. Alveolar macrophages engulf spores causing them to germinate to the vegetative form of B. anthracis, which secretes edema toxin (ET)and lethal toxin (LT). The pathogenesis of inhalational anthrax is characterized by flu-like symptoms, respiratory distress, meningitis and shock, which is fatal in almost all cases.
The mechanism behind the respiratory distress is not well understood. Therefore, our goal was to determine the effects of lethal toxin in the human lung epithelium. To
study alterations in a more physiological setting, we developed a differentiated, polarized lung epithelial system. Lethal toxin exposure disrupted the lung barrier
function and wound healing. Assembly defects of junction proteins and additional multicellular junction sites resulted in a higher permeability. Pretreatment with
keratinocyte growth factor (KGF) and dexamethasone increased the viability, resulting in the rescue of the permeability changes.
Upon LT treatment, a more rigid cytoskeleton was observed, evidenced by enhanced actin stress fiber formations and tubulin stabilization. Cytoskeleton and adhesion
alterations prevented the epithelial cells from polarization, directed migration, and wound healing. The MAPK pathway and Cdc42 activity might be partially responsible for these motility defects.
Lethal toxin is known to induce rapid cell death in murine macrophages. In contrast, human epithelial cells are more resistant to the cytotoxic effect of LT. By following
the growth of epithelial cells after LT treatment, we observed inhibited cell proliferation due to a cell cycle arrest in the G1 phase.
Surprisingly, biotinylated lethal factor did not induce cytotoxicity in murine macrophages. This is not due to an internalization or proteolytic activity defect; instead changes in the mitochondrial potential and proteasome activity were observed. Biotinylated LT did not reduce proteasome activity as seen in LT treated cells and caused hypopolarization of the mitochondria. However, it is possible that biotinylation of lethal toxin could prevent interaction of LT with proteins that induce cell death.
The major challenge for anthrax treatment is to find a treatment, which can act faster, is easy to use and can bring patient out of the dangerous physiological state
in late pathogenesis. Our study has implications in saving the viability and barrier function of lung epithelial cells. One can devise better dosage and delivery of KGF
and dexamethasone as treatment modality for post anthrax exposure to reduce respiratory distress. Furthermore, overcoming the cell cycle arrest by the development of a drug would reduce the damage of lung epithelial cells and induce proliferation. The discovery that biotinylated LT is non-toxic to murine macrophages could revolutionize treatment of anthrax infection. Exploring the types of posttranslational modifications of LT that decrease toxicity and finding the mechanism behind it might, lead to therapies that directly counteract the effects of the lethal toxin in vivo.
Inhalational anthrax is an acute infectious disease caused by exposure of the lungs to B. anthracis spores. Alveolar macrophages engulf spores causing them to germinate to the vegetative form of B. anthracis, which secretes edema toxin (ET)and lethal toxin (LT). The pathogenesis of inhalational anthrax is characterized by flu-like symptoms, respiratory distress, meningitis and shock, which is fatal in almost all cases.
The mechanism behind the respiratory distress is not well understood. Therefore, our goal was to determine the effects of lethal toxin in the human lung epithelium. To
study alterations in a more physiological setting, we developed a differentiated, polarized lung epithelial system. Lethal toxin exposure disrupted the lung barrier
function and wound healing. Assembly defects of junction proteins and additional multicellular junction sites resulted in a higher permeability. Pretreatment with
keratinocyte growth factor (KGF) and dexamethasone increased the viability, resulting in the rescue of the permeability changes.
Upon LT treatment, a more rigid cytoskeleton was observed, evidenced by enhanced actin stress fiber formations and tubulin stabilization. Cytoskeleton and adhesion
alterations prevented the epithelial cells from polarization, directed migration, and wound healing. The MAPK pathway and Cdc42 activity might be partially responsible for these motility defects.
Lethal toxin is known to induce rapid cell death in murine macrophages. In contrast, human epithelial cells are more resistant to the cytotoxic effect of LT. By following
the growth of epithelial cells after LT treatment, we observed inhibited cell proliferation due to a cell cycle arrest in the G1 phase.
Surprisingly, biotinylated lethal factor did not induce cytotoxicity in murine macrophages. This is not due to an internalization or proteolytic activity defect; instead changes in the mitochondrial potential and proteasome activity were observed. Biotinylated LT did not reduce proteasome activity as seen in LT treated cells and caused hypopolarization of the mitochondria. However, it is possible that biotinylation of lethal toxin could prevent interaction of LT with proteins that induce cell death.
The major challenge for anthrax treatment is to find a treatment, which can act faster, is easy to use and can bring patient out of the dangerous physiological state
in late pathogenesis. Our study has implications in saving the viability and barrier function of lung epithelial cells. One can devise better dosage and delivery of KGF
and dexamethasone as treatment modality for post anthrax exposure to reduce respiratory distress. Furthermore, overcoming the cell cycle arrest by the development of a drug would reduce the damage of lung epithelial cells and induce proliferation. The discovery that biotinylated LT is non-toxic to murine macrophages could revolutionize treatment of anthrax infection. Exploring the types of posttranslational modifications of LT that decrease toxicity and finding the mechanism behind it might, lead to therapies that directly counteract the effects of the lethal toxin in vivo.
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