Host DNA repair proteins in response to Pseudomonas aeruginosa in lung epitehlial cells and in mice

Host DNA damage and DNA repair response to bacterial infections and its significance are not fully understood. Here, we demonstrate that infection by Gram-negative bacterium P. aeruginosa significantly altered the expression and enzymatic activity of base excision DNA repair protein OGG1 in lung epi...

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Veröffentlicht in:	Infection and immunity 2011, Vol.79 (1), p.75-87
Hauptverfasser:	WU, MIN, HUANG, HUANG, ZHANG, WEIDONG, KANNAN, SHIBICHAKRAVART, WEAVER, ANDREW, MCKIBBEN, MOLYNDA, HERINGTON, DANIELLE, ZENG, HUAWEI, GAO, HONGWEI
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Sprache:	eng
Schlagworte:	acetylation bacterial infections cell death cell proliferation DNA damage DNA repair enzyme activity epithelial cells gene expression regulation genotoxicity Gram-negative bacteria lipid peroxidation lungs mice mutation myeloperoxidase proteins Pseudomonas aeruginosa secretion small interfering RNA virulence
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creator	WU, MIN HUANG, HUANG ZHANG, WEIDONG KANNAN, SHIBICHAKRAVART WEAVER, ANDREW MCKIBBEN, MOLYNDA HERINGTON, DANIELLE ZENG, HUAWEI GAO, HONGWEI
description	Host DNA damage and DNA repair response to bacterial infections and its significance are not fully understood. Here, we demonstrate that infection by Gram-negative bacterium P. aeruginosa significantly altered the expression and enzymatic activity of base excision DNA repair protein OGG1 in lung epithelial cells. Down-regulation of OGG1 with siRNA strategy resulted in severe DNA damage and cell death. In addition, OGG1 knockout mice infected by P. aeruginosa exhibited increased lung injury with higher activities of myeloperoxidase and lipid peroxidation. Furthermore, acetylation of OGG1 correlates with host responses to bacterial genotoxicity as mutations of OGG1 acetylation sites increased nuclear excision DNA repair protein CSB expression. An interaction between OGG1 and CSB was identified during infection, indicating that a synergy between these two DNA repair pathways is required for the repair of damaged DNA. This synergy may be critical for maintaining homeostasis in severe infection cases. ExoS, a major virulence factor belonging to type 3 secretion system exoenzymes, was found to induce activities of DNA repair protein OGG1 and ERK1/2, whereas siRNA inhibition of ERK1/2 decreased cell proliferation in an Akt dependent manner. Together, our studies indicate that DNA damage responses by certain DNA repair proteins, along with other signaling systems (e.g., Akt), play a concerted role in host defense against P. aeruginosa, and may be promising targets for the treatment of Gram-negative bacterial infection.
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Here, we demonstrate that infection by Gram-negative bacterium P. aeruginosa significantly altered the expression and enzymatic activity of base excision DNA repair protein OGG1 in lung epithelial cells. Down-regulation of OGG1 with siRNA strategy resulted in severe DNA damage and cell death. In addition, OGG1 knockout mice infected by P. aeruginosa exhibited increased lung injury with higher activities of myeloperoxidase and lipid peroxidation. Furthermore, acetylation of OGG1 correlates with host responses to bacterial genotoxicity as mutations of OGG1 acetylation sites increased nuclear excision DNA repair protein CSB expression. An interaction between OGG1 and CSB was identified during infection, indicating that a synergy between these two DNA repair pathways is required for the repair of damaged DNA. This synergy may be critical for maintaining homeostasis in severe infection cases. 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Here, we demonstrate that infection by Gram-negative bacterium P. aeruginosa significantly altered the expression and enzymatic activity of base excision DNA repair protein OGG1 in lung epithelial cells. Down-regulation of OGG1 with siRNA strategy resulted in severe DNA damage and cell death. In addition, OGG1 knockout mice infected by P. aeruginosa exhibited increased lung injury with higher activities of myeloperoxidase and lipid peroxidation. Furthermore, acetylation of OGG1 correlates with host responses to bacterial genotoxicity as mutations of OGG1 acetylation sites increased nuclear excision DNA repair protein CSB expression. An interaction between OGG1 and CSB was identified during infection, indicating that a synergy between these two DNA repair pathways is required for the repair of damaged DNA. This synergy may be critical for maintaining homeostasis in severe infection cases. 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Here, we demonstrate that infection by Gram-negative bacterium P. aeruginosa significantly altered the expression and enzymatic activity of base excision DNA repair protein OGG1 in lung epithelial cells. Down-regulation of OGG1 with siRNA strategy resulted in severe DNA damage and cell death. In addition, OGG1 knockout mice infected by P. aeruginosa exhibited increased lung injury with higher activities of myeloperoxidase and lipid peroxidation. Furthermore, acetylation of OGG1 correlates with host responses to bacterial genotoxicity as mutations of OGG1 acetylation sites increased nuclear excision DNA repair protein CSB expression. An interaction between OGG1 and CSB was identified during infection, indicating that a synergy between these two DNA repair pathways is required for the repair of damaged DNA. This synergy may be critical for maintaining homeostasis in severe infection cases. ExoS, a major virulence factor belonging to type 3 secretion system exoenzymes, was found to induce activities of DNA repair protein OGG1 and ERK1/2, whereas siRNA inhibition of ERK1/2 decreased cell proliferation in an Akt dependent manner. Together, our studies indicate that DNA damage responses by certain DNA repair proteins, along with other signaling systems (e.g., Akt), play a concerted role in host defense against P. aeruginosa, and may be promising targets for the treatment of Gram-negative bacterial infection.</abstract></addata></record>
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source	American Society for Microbiology; EZB-FREE-00999 freely available EZB journals; PubMed Central
subjects	acetylation bacterial infections cell death cell proliferation DNA damage DNA repair enzyme activity epithelial cells gene expression regulation genotoxicity Gram-negative bacteria lipid peroxidation lungs mice mutation myeloperoxidase proteins Pseudomonas aeruginosa secretion small interfering RNA virulence
title	Host DNA repair proteins in response to Pseudomonas aeruginosa in lung epitehlial cells and in mice
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