Role of Mitochondrial Dynamics and Autophagy in Removal of Helix-Distorting Mitochondrial DNA Damage

<p>Mitochondria are the primary energy producers of the cell and play key roles in cellular signaling, apoptosis and reactive oxygen species (ROS) production. Mitochondria are the only organelles that contain their own genome which encodes for a small subset of electron transport chain (ETC) p...

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Main Author: Bess, Amanda Smith
Other Authors: Meyer, Joel N
Published: 2012
Subjects:
Online Access:http://hdl.handle.net/10161/5805
id ndltd-DUKE-oai-dukespace.lib.duke.edu-10161-5805
record_format oai_dc
collection NDLTD
sources NDLTD
topic Toxicology
Environmental science
autophagy
Caenorhabditis elegans
mitochondrial DNA
mitochondrial morphology
mitophagy
ultraviolet radiation
spellingShingle Toxicology
Environmental science
autophagy
Caenorhabditis elegans
mitochondrial DNA
mitochondrial morphology
mitophagy
ultraviolet radiation
Bess, Amanda Smith
Role of Mitochondrial Dynamics and Autophagy in Removal of Helix-Distorting Mitochondrial DNA Damage
description <p>Mitochondria are the primary energy producers of the cell and play key roles in cellular signaling, apoptosis and reactive oxygen species (ROS) production. Mitochondria are the only organelles that contain their own genome which encodes for a small subset of electron transport chain (ETC) proteins as well as the necessary tRNAs and ribosomal subunits to translate these proteins. Over 300 pathogenic mitochondrial DNA (mtDNA) mutations have been shown to cause a number of mitochondrial diseases emphasizing the importance of mtDNA maintenance and integrity to human health. Additionally, mitochondrial dysfunction and mtDNA instability are linked to many wide-spread diseases associated with aging including cancer and neurodegeneration. Mitochondria lack the ability to repair certain helix-distorting lesions that are induced at high levels in mtDNA by important environmental genotoxins including polycyclic aromatic hydrocarbons, ultraviolet C radiation (UVC) and mycotoxins. These lesions are irreparable and persistent in the short term, but their long-term fate is unknown. Degradation of mitochondria and mtDNA is carried out by autophagy. Autophagy is protective against cell stress and apoptosis resulting from exposure to mitochondrial toxicants suggesting that it plays an important role in removal of unstable mitochondria that can serve as a source of ROS or initiate apoptotic cell death. Furthermore, dysfunctional mitochondria can be specifically targeted for degradation by the more specific process of mitophagy influenced in part by the processes of mitochondrial dynamics (i.e., fusion and fission). </p><p>The goals of this dissertation were to investigate the long-term fate of helix-distorting mtDNA damage and determine the significance of autophagy and mitochondrial dynamics in removal of and recovery from persistent mtDNA damage. Removal of irreparable mtDNA damage and the necessity of autophagy, mitophagy, fusion and fission genes in removal of this damage were examined using genetic approaches in adult <italic>Caenorhabditis elegans</italic>. In order to investigate the significance of autophagy, fusion and fission genes in recovery from mtDNA damage-induced mitochondrial dysfunction <italic>in vivo</italic>, an experimental method was developed to specifically induce persistent mtDNA damage and mitochondrial dysfunction without persistent nDNA damage in developing <italic>C. elegans</italic>. Additionally, the effect of persistent helix-distorting DNA damage on mitochondrial morphology, mitochondrial function and autophagy was investigated in <italic>C. elegans</italic> and in mammalian cell culture. The rate and specificity of mitochondrial degradation was further examined in cell culture using live-cell fluorescence microscopy and transmission electron microscopy. </p><p>Removal of UVC-induced mtDNA damage was detectable by 72 hours in <italic>C. elegans</italic> and mammalian cell culture, and required mitochondrial fusion, fission and autophagy, providing genetic evidence for a novel mtDNA damage removal pathway. UVC exposure induced autophagy with no detectable effect on mitochondrial morphology in both systems; mitochondrial function was inhibited in the <italic>C. elegans</italic> system but not in the cell culture system in which the degree of mtDNA damage induced was less. Furthermore, mutations in genes involved in these processes as well as pharmacological inhibition of autophagy exacerbated mtDNA damage-mediated larval arrest, illustrating the <italic>in vivo</italic> relevance of removal of persistent mtDNA damage. Mutations in genes in these pathways exist in the human population, demonstrating the potential for important gene-environment interactions affecting mitochondrial health after genotoxin exposure.</p> === Dissertation
author2 Meyer, Joel N
author_facet Meyer, Joel N
Bess, Amanda Smith
author Bess, Amanda Smith
author_sort Bess, Amanda Smith
title Role of Mitochondrial Dynamics and Autophagy in Removal of Helix-Distorting Mitochondrial DNA Damage
title_short Role of Mitochondrial Dynamics and Autophagy in Removal of Helix-Distorting Mitochondrial DNA Damage
title_full Role of Mitochondrial Dynamics and Autophagy in Removal of Helix-Distorting Mitochondrial DNA Damage
title_fullStr Role of Mitochondrial Dynamics and Autophagy in Removal of Helix-Distorting Mitochondrial DNA Damage
title_full_unstemmed Role of Mitochondrial Dynamics and Autophagy in Removal of Helix-Distorting Mitochondrial DNA Damage
title_sort role of mitochondrial dynamics and autophagy in removal of helix-distorting mitochondrial dna damage
publishDate 2012
url http://hdl.handle.net/10161/5805
work_keys_str_mv AT bessamandasmith roleofmitochondrialdynamicsandautophagyinremovalofhelixdistortingmitochondrialdnadamage
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spelling ndltd-DUKE-oai-dukespace.lib.duke.edu-10161-58052013-01-07T20:08:12ZRole of Mitochondrial Dynamics and Autophagy in Removal of Helix-Distorting Mitochondrial DNA DamageBess, Amanda SmithToxicologyEnvironmental scienceautophagyCaenorhabditis elegansmitochondrial DNAmitochondrial morphologymitophagyultraviolet radiation<p>Mitochondria are the primary energy producers of the cell and play key roles in cellular signaling, apoptosis and reactive oxygen species (ROS) production. Mitochondria are the only organelles that contain their own genome which encodes for a small subset of electron transport chain (ETC) proteins as well as the necessary tRNAs and ribosomal subunits to translate these proteins. Over 300 pathogenic mitochondrial DNA (mtDNA) mutations have been shown to cause a number of mitochondrial diseases emphasizing the importance of mtDNA maintenance and integrity to human health. Additionally, mitochondrial dysfunction and mtDNA instability are linked to many wide-spread diseases associated with aging including cancer and neurodegeneration. Mitochondria lack the ability to repair certain helix-distorting lesions that are induced at high levels in mtDNA by important environmental genotoxins including polycyclic aromatic hydrocarbons, ultraviolet C radiation (UVC) and mycotoxins. These lesions are irreparable and persistent in the short term, but their long-term fate is unknown. Degradation of mitochondria and mtDNA is carried out by autophagy. Autophagy is protective against cell stress and apoptosis resulting from exposure to mitochondrial toxicants suggesting that it plays an important role in removal of unstable mitochondria that can serve as a source of ROS or initiate apoptotic cell death. Furthermore, dysfunctional mitochondria can be specifically targeted for degradation by the more specific process of mitophagy influenced in part by the processes of mitochondrial dynamics (i.e., fusion and fission). </p><p>The goals of this dissertation were to investigate the long-term fate of helix-distorting mtDNA damage and determine the significance of autophagy and mitochondrial dynamics in removal of and recovery from persistent mtDNA damage. Removal of irreparable mtDNA damage and the necessity of autophagy, mitophagy, fusion and fission genes in removal of this damage were examined using genetic approaches in adult <italic>Caenorhabditis elegans</italic>. In order to investigate the significance of autophagy, fusion and fission genes in recovery from mtDNA damage-induced mitochondrial dysfunction <italic>in vivo</italic>, an experimental method was developed to specifically induce persistent mtDNA damage and mitochondrial dysfunction without persistent nDNA damage in developing <italic>C. elegans</italic>. Additionally, the effect of persistent helix-distorting DNA damage on mitochondrial morphology, mitochondrial function and autophagy was investigated in <italic>C. elegans</italic> and in mammalian cell culture. The rate and specificity of mitochondrial degradation was further examined in cell culture using live-cell fluorescence microscopy and transmission electron microscopy. </p><p>Removal of UVC-induced mtDNA damage was detectable by 72 hours in <italic>C. elegans</italic> and mammalian cell culture, and required mitochondrial fusion, fission and autophagy, providing genetic evidence for a novel mtDNA damage removal pathway. UVC exposure induced autophagy with no detectable effect on mitochondrial morphology in both systems; mitochondrial function was inhibited in the <italic>C. elegans</italic> system but not in the cell culture system in which the degree of mtDNA damage induced was less. Furthermore, mutations in genes involved in these processes as well as pharmacological inhibition of autophagy exacerbated mtDNA damage-mediated larval arrest, illustrating the <italic>in vivo</italic> relevance of removal of persistent mtDNA damage. Mutations in genes in these pathways exist in the human population, demonstrating the potential for important gene-environment interactions affecting mitochondrial health after genotoxin exposure.</p>DissertationMeyer, Joel N2012Dissertationhttp://hdl.handle.net/10161/5805