Mycobacterium bovis BCG chaperonin 60.1 contributes to adaptations under stresses: implication for escaping isoniazid bactericidal mechanism and for mycobacterial biofilm growth

Zeng, Sheng

29 April 2019

Tuberculosis, caused by Mycobacterium tuberculosis, still poses a huge global health threat today. During infection, the bacilli are believed to confront with various stresses, including hypoxia. Hypoxia is known to trigger the bacteria to adapt into a nonreplicating dormant state associated with reduced drug susceptibility. In addition to dormancy, mycobacteria, like other bacteria, may switch to sessile biofilm growth that is generally associated with augmented drug and stress tolerance. Bacterial biofilm is physically heterogeneous and may harbor cells displaying distinct metabolic activities. It is therefore likely that some cell populations within an established biofilm are in a nonreplicating dormant state. A better understanding of mycobacterial dormancy establishment and biofilm growth could unveil crucial bacillary survival strategies that will provide insights into a rational design of chemotherapy regimen.The mycobacterial chaperonin 60.1 (Cpn60.1, also known as GroEL1), a probable chaperonin and/or nucleoid associated protein, is necessary for mycobacterial cell wall virulence lipid biosynthesis, which was reported to be enhanced at the early stage of mycobacterial hypoxic adaptation, and for reduced drug susceptibility under aerobic condition. We therefore investigated whether Cpn60.1 was essential for mycobacterial adaptation to hypoxic dormancy using Mycobacterium bovis BCG as the model organism. We found that Cpn60.1, although nonessential for mycobacterial survival, reduced isoniazid (INH) susceptibility under hypoxia. Unexpectedly and interestingly, INH’s bactericidal activity was found to involve electron transport chain perturbation (e.g. enhanced oxygen consumption and increased adenosine triphosphate level) via NADH dehydrogenases, succinate dehydrogenases, cytochrome bc1 and F0F1 ATP synthase. Moreover, respiratory reprogramming to cytochrome bd was observed to protect against INH-induced killing.Intriguingly, we found that Cpn60.1 was required for respiratory and energetic downregulation under excess glycerol as well as in response to drugs (such as Q203 inhibiting cytochrome bc1). Cpn60.1 also played a role in lipidomic adaptation under excess glycerol (e.g. enhanced phthiocerol dimycocerosate and glycerol-based lipids synthesis but repressed trehalose-based lipids synthesis). Defective energetic downregulation in the absence of Cpn60.1 compromised the establishment of the Crabtree effect characterized by respiratory downregulation, glycolytic enhancement and secretion of several metabolites (i.e. pyruvate, succinate, acetate and glutamate). The Crabtree effect was necessary for mycobacterial adaptation to excess glycerol and biofilm growth. Due to a compromised Crabtree effect, a Cpn60.1-deficient Mycobacterium bovis BCG strain, i.e. the Δcpn60.1 strain, suffered from methylglyoxal-induced growth stasis under excess glycerol, leading to the biofilm defect under the standard biofilm medium. Given the essentiality for Cpn60.1 in mycobacterial respiratory adaptation under stresses, it is likely that the enhanced INH susceptibility of the Δcpn60.1 strain under hypoxia was due to a problematic respiratory reprogramming.In summary, Mycobacterium bovis BCG Cpn60.1 is not required for bacillary survival under hypoxic dormancy. However, it participates in various adaptations (e.g. respiratory downregulation) necessary for mycobacterial biofilm growth and for escaping INH’s bactericidal mechanism. / Doctorat en Sciences biomédicales et pharmaceutiques (Pharmacie) / info:eu-repo/semantics/nonPublished

Métabolisme

Electron transport chain

Metabolic pathway

Dormancy

Methylglyoxal

Bedaquiline

Q203

TCA

Glycolysis

Biofilm marker

Establishing the comet assay to determine the effects of different perturbations on DNA repair capacity / by Anzaan Steenkamp

Steenkamp, Anzaan

January 2011

Single cell gel electrophoresis (SCGE), more commonly known as the Comet assay, is an uncomplicated, affordable and versatile method for investigating DNA damage and repair. Existing comet–assay based methods were modified and applied in this study in order to examine the effects of different perturbations on the DNA repair capacity of different samples. Mitochondrial functioning has a vast effect on overall cell physiology and does not simply involve the production of energy in the form of ATP that sustains common biological processes, but is also associated with important cellular occurrences such as apoptosis and ROS production. It is suggested that a change in mitochondrial function may lead to extensive ROS production which may negatively affect macromolecules, including proteins involved in DNA repair pathways, and impaired energy formation which in turn may hamper the proper occurrence of energy driven processes. Complex I and ?III knock–down systems established in 143B cells are used to investigate the effect that perturbations of the energy metabolism may have on DNA repair capacity. Metallothioneins (MTs) are known to play an imperative role in trace element homeostasis and detoxification of metals and are effective ROS scavengers. The prooxidant environment that heavy metal imbalance causes may result in mutagenesis and transformation through DNA damage. It is suggested that an imbalance in the metal homeostasis caused by MT knock–out may create an environment favourable for DNA damage formation and at the same time impair DNA repair pathways. Because of the multi–functionality and involvement of metallothioneins in such a wide variety of biological processes, it was considered interesting and essential to extend the investigation on the effect of the absence of metallothioneins on DNA repair. A metallothionein I and ?II knock–out mouse model is employed to determine the effect of MT knock–out on DNA repair capacity. It was clear from the results obtained that transfection of cells, as used to investigate a perturbation in the energy metabolism in 143B cells, has an impairing effect on DRC. It was also confirmed that metallothioneins play an important and diverse role in cell biology since the absence thereof inhibits both BER and NER. / Thesis (M.Sc. (Biochemistry))--North-West University, Potchefstroom Campus, 2011.

Comet assay

DNA repair capacity

Base excision repair (BER)

Nucleotide excision repair (NER)

Electron transport chain

Metallothionein

Establishing the comet assay to determine the effects of different perturbations on DNA repair capacity / by Anzaan Steenkamp

Steenkamp, Anzaan

January 2011

Single cell gel electrophoresis (SCGE), more commonly known as the Comet assay, is an uncomplicated, affordable and versatile method for investigating DNA damage and repair. Existing comet–assay based methods were modified and applied in this study in order to examine the effects of different perturbations on the DNA repair capacity of different samples. Mitochondrial functioning has a vast effect on overall cell physiology and does not simply involve the production of energy in the form of ATP that sustains common biological processes, but is also associated with important cellular occurrences such as apoptosis and ROS production. It is suggested that a change in mitochondrial function may lead to extensive ROS production which may negatively affect macromolecules, including proteins involved in DNA repair pathways, and impaired energy formation which in turn may hamper the proper occurrence of energy driven processes. Complex I and ?III knock–down systems established in 143B cells are used to investigate the effect that perturbations of the energy metabolism may have on DNA repair capacity. Metallothioneins (MTs) are known to play an imperative role in trace element homeostasis and detoxification of metals and are effective ROS scavengers. The prooxidant environment that heavy metal imbalance causes may result in mutagenesis and transformation through DNA damage. It is suggested that an imbalance in the metal homeostasis caused by MT knock–out may create an environment favourable for DNA damage formation and at the same time impair DNA repair pathways. Because of the multi–functionality and involvement of metallothioneins in such a wide variety of biological processes, it was considered interesting and essential to extend the investigation on the effect of the absence of metallothioneins on DNA repair. A metallothionein I and ?II knock–out mouse model is employed to determine the effect of MT knock–out on DNA repair capacity. It was clear from the results obtained that transfection of cells, as used to investigate a perturbation in the energy metabolism in 143B cells, has an impairing effect on DRC. It was also confirmed that metallothioneins play an important and diverse role in cell biology since the absence thereof inhibits both BER and NER. / Thesis (M.Sc. (Biochemistry))--North-West University, Potchefstroom Campus, 2011.

Comet assay

DNA repair capacity

Base excision repair (BER)

Nucleotide excision repair (NER)

Electron transport chain

Metallothionein

Análise dos níveis relativos de transcrição de genes antioxidantes e da cadeia de transporte de elétrons de Aspergillus fumigatus / Transcription relative levels analysis of Aspergillus fumigatus antioxidant and electrons transport chain genes

Renata Vilela Rodrigues

11 January 2013

Aspergillus fumigatus é um fungo oportunista, sendo uma importante causa de morbidade e mortalidade entre os pacientes imunossuprimidos, acometidos com aspergilose invasiva. O sistema de defesa antioxidante do fungo atua como fator primordial de sua patogenicidade, mitigando os efeitos deletérios de espécies reativas produzidas pelo hospedeiro. Este trabalho teve o objetivo de avaliar o nível de transcrição relativo dos genes associados às proteínas mitocondriais e antioxidantes na presença de diferentes agentes pró-oxidantes para hifas e germinantes de cepas controle (CEA17) e nocaute para oxidase alternativa (?aoxA) de A. fumigatus. Utilizando qPCR, foram analisados 23 genes para as cepas CEA17 e mutante, dentre os quais, 5 associados à cadeia de transporte de elétrons (CTE), 4 relacionados aos componentes alternativos mitocondriais e 14 associados às proteínas antioxidantes. Os resultados foram obtidos através da normalização com o gene constitutivo gapdh utilizando a cepa CEA17 sem tratamento de cada fase de desenvolvimento celular como calibrador. As diferenças de transcrição da maioria dos genes estudados variaram com o pró-oxidante utilizado e com a fase de desenvolvimento celular (germinantes e hifas). A CTE em germinantes apresentou maiores níveis de transcritos dos complexos II e III em CEA17 do que em ?aoxA tratadas com menadiona. Com os demais complexos e atpase não foram observadas diferenças significativas quando comparados os resultados de ambas as cepas. Entretanto, os níveis de transcritos de atpase não foram superiores ao controle em nenhuma das cepas, sugerindo sua regulação na presença de ucp. ucp-like teve seus níveis de transcritos aumentados no mutante, sugerindo o desacoplamento da CTE em relação ao controle e à CEA17, que apresentou alto nível de transcritos de nde. Nesta cepa, os níveis de aoxA e ucp não foram significativamente diferentes. Esse fato, associado a níveis menores de ndiA e transcritos dos complexos I e II, sugerem manutenção do fluxo de elétrons na mitocôndria. Em relação às enzimas antioxidantes, houve aumento significativo nos níveis de cat2, catA, prx1, trx1 e grx1, indicando provável resposta à ausência de AOX. Os transcritos relacionados à CTE em hifas não apresentou diferença significativa nos níveis de complexo III e atpase em CEA17 e ?aoxA. No entanto, complexo IV se mostrou superior no mutante. Nesta fase de desenvolvimento, o aumento dos níveis de ucp-like está relacionado ao tratamento com menadiona e não com a presença de aoxA, explicando os mesmos níveis de transcritos em CEA17 e ?aoxA. Os níveis de nde sugerem atividade coordenada de sua proteína com AOX, por seus níveis estarem modulados pela presença de aoxA. A participação da Nde e da AOX na detoxificação das espécies reativas de oxigênio é sugerida ao se obter altos níveis de seus transcritos em hifas tratadas com menadiona. Diferentemente de germinantes, transcritos de sod3 foram predominantes em hifas de CEA17, enquanto transcritos de sod2 foram maiores em ?aoxA. Entre as catalases, os níveis de catA foram maiores no mutante, bem como a atividade das catalases como um todo. prx1 e trx1 foram maiores em CEA17 e ii grx1 em ?aoxA. Porém, trx1 atingiu os mais altos níveis de transcritos em germinantes, indicando possível redução de proteínas tiólicas e ribonucleotídeos por diferentes vias, de acordo com a fase de desenvolvimento do fungo. As enzimas antioxidantes clássicas, como superóxido dismutase, catalase e enzimas tiólicas, apresentaram aumento de transcrição na maioria das condições estudadas. No entanto, menadiona e paraquat promoveram maiores variações nos transcritos do que o observado com peróxido de hidrogênio gerado pelo sistema glicose/glicose oxidase. / Aspergillus fumigatus is an opportunistic fungus which has been referred to as a major cause of morbidity and mortality in imunosupressed patients affected with invasive aspergillosis. The antioxidant defense system of the fungus plays an important role in its pathogenicity by overcoming the negative effects of the oxygen reactive species produced by host. This work aims evaluating the transcription of genes associated to mitochondrial and antioxidant proteins in the presence of different prooxidants for hyphae and germinants of control (CEA17) and alternative oxidase knockout (?aoxA) strains. Using qPCR, 23 genes have been analyzed, 5 of which are electron transport chain (ETC), 4 are related to alternative components of the mitochondria, and 14 are associated to antioxidant proteins. The results were obtained via normalization with the constitutive gene gapdh using untreated CEA17 strain in each developmental phase as calibrator. The differences in the transcription of most analyzed genes varied with the prooxidant and the developmental phase (germinants and hyphae). The ETC in germinants presented higher amounts of transcripts of the complex II and III in CEA17 than in ?aoxA treated with menadione. With other complexes and the atpase no significant difference has been noted between both strains. However, the transcript levels of ATP synthase were not higher than control in any strain, which is related to its regulation in the presence of UCP. UCP-like had increased transcription in mutant, suggesting uncoupling from the ETC, relative to control and CEA17, which showed high levels of nde. In this strain, aoxA and ucp-like transcripts were not significantly different. This fact associated the lower levels of ndiA and transcripts of the complexes I and II suggest the maintenance of the electron flow in the mitochondria. Concerning the antioxidant enzymes, there was significant increase in the transcript production of cat2, catA, prx1, Ttrx1 and Ggrx1, suggesting a response to the absence of AOX. The ETC transcripts in hyphae did not present significant difference in the levels of complex III and atpase in CEA17 and ?aoxA. Yet the complex IV has shown higher in mutant than in CEA17. In this developmental phase, the increase of ucp-like is related to the treatment with menadione and not with the presence of aoxA, what explains the equivalent amount of transcripts in CEA17 and ?aoxA. The levels of nde suggest coordinated action of the protein with AOX, because it is modulated by the presence of aoxA. The role of Nde and AOX in the detoxification of reactive oxygen species is suggested by their high levels of transcripts in hyphae treated with menadione. Different from germinants, transcripts of sod3 was predominant in CEA17 hyphae, whereas transcripts of sod2 were higher for ?aoxA. Among catalases, levels of catA were higher in mutant, as was the activity of catalase as a whole. prx1 and trx1 transcripts were higher in CEA17 and grx1 in ?aoxA. Yet, trx1 reached the highest levels of transcripts in germinants, indicating a possible reduction of thiol proteins and ribonucleotides through different ways, according to the developmental phase of the fungus. The classical antioxidant enzymes, as superoxide dismutase, catalase and thiol enzymes showed increase in the transcripts in most of the analyzed situations. iv However, menadione and paraquat promoted higher variation in the transcripts than that observed with hydrogen peroxide generated by the system glucose/glucose oxidase.

Aspergillus fumigatus

Cadeia de transporte de elétrons

Componentes alternativos mitocondriais

Enzimas antioxidantes

Mitocôndria

Antioxidant enzymes

Aspergillus fumigatus

Electrons transport chain

Mitochondrial

Mitochondrion

ROS generated by mitochondrial electron transport chain complexes I and III regulate differentiation of the pluripotent cell line P19

Pashkovskaia, Natalia

20 December 2017

Mitochondria are essential for the viability of mammalian cells and provide a compartment for specific chemical reactions. Cellular respiration -- the main mitochondrial function -- is tightly connected with ROS production: the mitochondrial electron transport chain complexes I and III are the main ROS sources in mammalian cells. It has been reported that complex I and complex III activities are essential for cell cycle, apoptosis and stem cell differentiation (Spitkovsky et al., 2004; Varum et al., 2009; Lee et al., 2011; Ma et al., 2011; Tormos et al., 2012). In our work, we aimed to investigate the role of mitochondrial electron transport chain activity in the regulation of the differentiation potential and to unravel signaling pathways that could participate in this regulation. As a model, we used the P19 pluripotent stem cell line that can be easily differentiated into trophoblasts, expressing intermediate filaments cytokeratin 8/18, and neurons, which express cytoskeleton protein beta-III-tubulin. We first showed that both trophoblast and neural differentiation of P19 cells were accompanied by activation of cellular respiration. The analysis of respiratory chain complexes and supercomplexes, however, showed that undifferentiated P19 cells, as well as their differentiated derivatives did not differ in their respiratory machinery, including functional respirasomes. While undifferentiated cells did not use respiration as the main energy source, cellular respiration was activated during differentiation, indicating that oxidative metabolism was important for efficient differentiation. To investigate the potential role of mitochondrial electron transport chain activity we monitored the influence of a disrupted electron flow on the differentiation of P19 cells. We found that the activity of complex I and complex III influenced the differentiation potential of the pluripotent P19 cell line: the presence of complex I and complex III inhibitors rotenone, antimycin A, or myxothiazol increased the amount of cytokeratin 8/18+ cells during trophoblast differentiation, but almost completely prevented the formation of neuron-like beta-III-tubulin+ cells during neuron differentiation. Moreover, a low oxygen level (1 % O2 vs 21 % O2 in atmosphere) - the final electron acceptor - had the same effect on differentiation. These data suggest that mitochondrial electron transport chain activity contributes to the regulation of differentiation. The presence of complex I and complex III inhibitors, as well as oxygen scarcity, increase ROS production. We suggested that increased ROS level could explain the observed effects. By visualizing mitochondrial superoxide production with a specific dye – MitoSox - we confirmed that rotenone, antimycin A, myxothiazol, as well as low oxygen conditions, increased the superoxide level. These results suggest that the observed changes of the differentiation potential of P19 cells are associated with ROS production. To prove this idea, we differentiated P19 cells in presence of paraquat – a known ROS inducer. In line with our hypothesis paraquat promoted trophoblast differentiation. The received results suggest that the mitochondrial electron transport chain activity regulates differentiation through the ROS level. ROS are secondary messengers that participate in numerous processes including cell proliferation and differentiation. We aimed to predict the signal pathway that connects ROS level in stem cells and their differentiation potential. For this purpose, we performed a microarray analysis and compared the gene expression profiles of cells grown under hypoxia or in the presence of the complex III inhibitor myxothiazol with untreated control cells. The expression analysis revealed p53 as a transcriptional factor that impacts the differentiation potential in treated cells. p53 is a known redox-sensing molecule (Bigarella et al., 2014) that influences the differentiation potential through cell cycle control (Maimets et al., 2008). This observation is in line with our results and suggests that p53 may regulate the differentiation potential of P19 cells. We are planning to investigate the role of p53 signaling in the regulation of cell cycle and differentiation potential of P19 cell line.

info:eu-repo/classification/ddc/570

ddc:570

Mitochondrie a jejich role v karcinogenezi / Mitochondria and their role in carcinogenesis

Bajzíková, Martina

January 2021

(EN) Mitochondria are the principal intracellular organelles responsible for fuel generation; however, they are not just cell powerhouses but are involved in a range of other intracellular functions including cell metabolism, proliferation, death, and immune responses. Loss of function in mitochondria will result in oxidative stress, which is one of the underlying causal factors for a variety of diseases including cancer. Cancer cells can predominantly produce energy by glycolysis even in the presence of oxygen. This alternative metabolic behavior is known as the "Warburg Effect." Linked to this, cancer cell mitochondria can switch between glycolysis and oxidative phosphorylation (OXPHOS) for their energy requirements and survival. The electron transport chain (ETC) function is pivotal for mitochondrial respiration, which is also needed for dihydroorotate dehydrogenase (DHODH) activity that is essential for de novo pyrimidine synthesis. In our research, we have used respiration-deficient cancer cells to challenge the dogma that mitochondria with their DNA are constrained within cells in the body. Our results document that mitochondria move from normal cells within the tumor stroma to tumor cells without mitochondrial DNA (mtDNA), resulting in long-lasting recovery of mitochondrial functions and,...

Dýchání jako mezioborové téma ve výuce přírodovědných předmětů / Respiration as an interdisciplinary topic in science education

Čermáková, Vendula

January 2018

This diploma thesis is focused on topics of and respiratory chain and their processing as educational animations for secondary schools. In the theoretical part of the diploma thesis, supporting terms are defined (visualisations, interdisciplinary relations, animations). Next, themes are included in educational field and thematic unit in RVP G. Two analyses of the topic of respiratory chain are mentioned and evaluated in this part. Firstly, there is an analysis focused on the most used chemical and biological textbooks. The second one is focused on available online animations. For research purpose of the diploma thesis quantitative method was used - a questionnaire survey. Results of this survey are listed in the practical part. Practical part presents educational materials specified for support of education topics of respiration and respiratory chain. Stress on illustrative nature and interdisciplinarity is laid in these materials. The principal materials are educational animations which were made in program Adobe Flash Professional CS6. Study text was also written to these animations. Created educational animations give a complex view on respiratory process. These materials can be used in biology and chemistry subjects or in scientific courses. Animations include two tests giving feedback to...

Novo papel da proteína XPC na regulação dos complexos da cadeia de transporte de elétrons e desequilíbrio redox / New role of XPC protein in regulating the electron transport chain complexes and redox unbalance

Mori, Mateus Prates

22 April 2015

Espécies reativas de oxigênio (EROs) são normalmente e continuamente geradas em mitocôndrias, majoritariamente na cadeia de transporte de elétrons (CTE). Harman (1956, 1972 e 1992) teorizou que os radicais livres gerados nas mitocôndrias seriam a principal causa do envelhecimento. De fato, durante o envelhecimento é observado um desequilíbrio entre formação e remoção de EROs, que resulta em estresse redox. Essa condição favorece a formação de lesões oxidadas no DNA, acarretando em mutagênese ou morte celular. Diversos mecanismos moleculares cooperam para o reparo de DNA. Duas vias de reparo de DNA lidam com a maioria das lesões: o reparo por excisão de base (BER) e o reparo por excisão de nucleotídeos (NER). A via BER corrige pequenas modificações de bases que surgem de reações de desaminação, alquilação e oxidação. A via NER é mais versátil, reconhecendo lesões que distorcem a dupla hélice de DNA, como danos induzidos por luz UV e adutos volumos. Pacientes xeroderma pigmentoso (XP-A a XP-G) herdam mutações em um de sete genes que codificam proteínas envolvidas na via NER, ou em um gene que codifica uma polimerase translesão (XP-V). A doença é caracterizada por fotosensibilidade e incidência elevada de neoplasias cutâneas. A proteína XPC atua na etapa de reconhecimento da lesão de DNA na subvia de reparo global do genoma (GG-NER), e sua mutação dá origem aos sintomas clássicos de XP. Novas funções de XPC foram recentemente descritas: i) atuando como cofator na via BER auxiliando as DNA glicosilases OGG1, TDG e SMUG; ii) atuando como cofator transcricional de elementos responsivos a Oct4/Sox2, RXR e PPARα; e iii) na adaptação metabólica na transformação de queratinócitos. Então, propusemo-nos a investigar as relações entre XPC e a manutenção da integridade do DNA mitocondrial, a sensibilidade celular a estresse redox mitocondrial e possíveis alterações bioenergéticas e redox. Para tal, padronizamos um ensaio in vitro de cinética de incisão em DNA plasmidial a fim de investigarmos o possível papel de XPC no reparo de lesões oxidadas em mtDNA. Porém, nossos dados revelaram que XPC não se encontra em mitocôndrias. Apesar disso, células XP-C são mais sensíveis ao tratamento com azul de metileno (AM), antimicina A (AA) e rotenona (ROT), que geram estresse redox mitocondrial. A sensibilidade à AA foi completamente revertida em células corrigidas. Células XP-C apresentaram alterações quanto ao uso dos complexos mitocondriais, com diminuição da taxa de consumo de oxigênio (OCR) via complexo I e um aumento da OCR via complexo II, dependente da presença de XPC. Ademais, a linhagem XP-C apresentou um desequilíbrio redox mitocondrial com maior produção de EROs e menor atividade de GPx. O DNA mitocondrial de células XP-C apresentou níveis elevados de lesão e deleção, que no entanto não retornaram aos níveis encontrados em células selvagens na linhagem XP-C corrigida. Observamos uma acentuada diminuição da expressão de PPARGC1A, um importante regulador de biogênese mitocondrial. Contudo, não foi possível determinar o mecanismo de supressão da expressão de PPARGC1A. Por fim, identificamos que o tipo de mutação em XPC pode estar associado a expressão de PPARGC1A. Esse estudo abre novas possibilidade na investigação do papel de proteína XPC, à parte da instabilidade genômica, na adaptação metabólica e desequilíbrio redox em direção da progressão tumoral. / Mitochondria continuously produce reactive oxygen species (ROS), mainly at the electron transport chain. Harman (1956, 1972 e 1992) proposed that normal aging is driven by increased mitochondrially generated free radicals. Indeed, during the course of aging there is an increased imbalance between formation and removal of ROS, leading to redox stress. This condition favours the formation of oxidized DNA lesions, given rise to mutations and cell death. Several molecular mechanisms cooperates to repair the DNA. Two DNA repair pathways deal with the majority of lesions: base excision repair (BER) and nucleotide excision repair (NER). The BER pathway corrects small base modifications that arise from deamination, alkylation and oxidation reactions. The NER pathway is more versitile, recognizing helix-distorting lesions, such as UV-induced damage and bulky adducts. Xeroderma pigmentosum (XP-A to XP-G) patients inherit mutations in one of seven protein-coding genes involved in NER pathway, or in a gene coding a translesion DNA polymerase (XP-V). Photosensitivity and a thousand-fold increased in the risk of developing cutaneous neoplasms are the main clinical features of XP. XPC protein functions in the recognition step of global genome NER (GG-NER) sub-pathway, and mutations in this gene lead to classical XP symptoms. Recently, it has been described that XPC acts: i) as a cofactor in BER pathway through functional interaction with DNA glycosylases OGG1, TDG and SMUG1; ii) as coactivator in transcription at Oct4/Sox2, RXR and PPARα responsive elements; iii) in metabolic shift during keratinocytes transformation. Thus, we sought to investigate a possible role for XPC in the maintenance of mtDNA integrity, cellular sensitivity to mitochondrial redox stress and eventual bioenergetic and redox changes. For this purpose, we established an in vitro plasmid incision assay to investigate the possible role of XPC in the repair of oxidized lesions in mitochondrial DNA. However, our data revealed that XPC did not localized in mitochondria. Nonetheless, XP-C cells are more sensitive to methylene blue, antimycin A (AA) and rotenone treatment, which induce mitochondrial redox stress. The XP-C sensitivity to AA was completely reverted in XPC-corrected cells. XP-C cells presented altered usage of mitochondrial complexes, with decreased oxygen consumption rate (OCR) via complex I and increased OCR through complex II, an XPC-dependent phenomenon. Furthermore, the XP-C cell line showed mitochondrial redox imbalance with increased ROS production and decrease GPx activity. MtDNA from XP-C cells accumulate lesions and deletions, which, however, were found at similar levels in the corrected cell line. We identified a sharp decrease in the expression of PPARGC1A, a master regulator of mitochondrial biogenesis. Nevertheless, it was not possible to determine the mechanism of suppression of PPARGC1A expression. Finally, our results suggest a possible link between the type of XPC mutation and PPARGC1A expression. This study unfolds new possible roles for XPC, aside from its established roles in genomic instability, in metabolic adaptation and redox imbalance towards tumour progression.

Desequilíbrio redox

Electron transport chain complexes

PPARGC1A

PPARGC1A

Redox imbalance

Regulação

Regulation

Repair of DNA

Reparação do DNA

XPC

XPC

Novo papel da proteína XPC na regulação dos complexos da cadeia de transporte de elétrons e desequilíbrio redox / New role of XPC protein in regulating the electron transport chain complexes and redox unbalance

Mateus Prates Mori

22 April 2015

Espécies reativas de oxigênio (EROs) são normalmente e continuamente geradas em mitocôndrias, majoritariamente na cadeia de transporte de elétrons (CTE). Harman (1956, 1972 e 1992) teorizou que os radicais livres gerados nas mitocôndrias seriam a principal causa do envelhecimento. De fato, durante o envelhecimento é observado um desequilíbrio entre formação e remoção de EROs, que resulta em estresse redox. Essa condição favorece a formação de lesões oxidadas no DNA, acarretando em mutagênese ou morte celular. Diversos mecanismos moleculares cooperam para o reparo de DNA. Duas vias de reparo de DNA lidam com a maioria das lesões: o reparo por excisão de base (BER) e o reparo por excisão de nucleotídeos (NER). A via BER corrige pequenas modificações de bases que surgem de reações de desaminação, alquilação e oxidação. A via NER é mais versátil, reconhecendo lesões que distorcem a dupla hélice de DNA, como danos induzidos por luz UV e adutos volumos. Pacientes xeroderma pigmentoso (XP-A a XP-G) herdam mutações em um de sete genes que codificam proteínas envolvidas na via NER, ou em um gene que codifica uma polimerase translesão (XP-V). A doença é caracterizada por fotosensibilidade e incidência elevada de neoplasias cutâneas. A proteína XPC atua na etapa de reconhecimento da lesão de DNA na subvia de reparo global do genoma (GG-NER), e sua mutação dá origem aos sintomas clássicos de XP. Novas funções de XPC foram recentemente descritas: i) atuando como cofator na via BER auxiliando as DNA glicosilases OGG1, TDG e SMUG; ii) atuando como cofator transcricional de elementos responsivos a Oct4/Sox2, RXR e PPARα; e iii) na adaptação metabólica na transformação de queratinócitos. Então, propusemo-nos a investigar as relações entre XPC e a manutenção da integridade do DNA mitocondrial, a sensibilidade celular a estresse redox mitocondrial e possíveis alterações bioenergéticas e redox. Para tal, padronizamos um ensaio in vitro de cinética de incisão em DNA plasmidial a fim de investigarmos o possível papel de XPC no reparo de lesões oxidadas em mtDNA. Porém, nossos dados revelaram que XPC não se encontra em mitocôndrias. Apesar disso, células XP-C são mais sensíveis ao tratamento com azul de metileno (AM), antimicina A (AA) e rotenona (ROT), que geram estresse redox mitocondrial. A sensibilidade à AA foi completamente revertida em células corrigidas. Células XP-C apresentaram alterações quanto ao uso dos complexos mitocondriais, com diminuição da taxa de consumo de oxigênio (OCR) via complexo I e um aumento da OCR via complexo II, dependente da presença de XPC. Ademais, a linhagem XP-C apresentou um desequilíbrio redox mitocondrial com maior produção de EROs e menor atividade de GPx. O DNA mitocondrial de células XP-C apresentou níveis elevados de lesão e deleção, que no entanto não retornaram aos níveis encontrados em células selvagens na linhagem XP-C corrigida. Observamos uma acentuada diminuição da expressão de PPARGC1A, um importante regulador de biogênese mitocondrial. Contudo, não foi possível determinar o mecanismo de supressão da expressão de PPARGC1A. Por fim, identificamos que o tipo de mutação em XPC pode estar associado a expressão de PPARGC1A. Esse estudo abre novas possibilidade na investigação do papel de proteína XPC, à parte da instabilidade genômica, na adaptação metabólica e desequilíbrio redox em direção da progressão tumoral. / Mitochondria continuously produce reactive oxygen species (ROS), mainly at the electron transport chain. Harman (1956, 1972 e 1992) proposed that normal aging is driven by increased mitochondrially generated free radicals. Indeed, during the course of aging there is an increased imbalance between formation and removal of ROS, leading to redox stress. This condition favours the formation of oxidized DNA lesions, given rise to mutations and cell death. Several molecular mechanisms cooperates to repair the DNA. Two DNA repair pathways deal with the majority of lesions: base excision repair (BER) and nucleotide excision repair (NER). The BER pathway corrects small base modifications that arise from deamination, alkylation and oxidation reactions. The NER pathway is more versitile, recognizing helix-distorting lesions, such as UV-induced damage and bulky adducts. Xeroderma pigmentosum (XP-A to XP-G) patients inherit mutations in one of seven protein-coding genes involved in NER pathway, or in a gene coding a translesion DNA polymerase (XP-V). Photosensitivity and a thousand-fold increased in the risk of developing cutaneous neoplasms are the main clinical features of XP. XPC protein functions in the recognition step of global genome NER (GG-NER) sub-pathway, and mutations in this gene lead to classical XP symptoms. Recently, it has been described that XPC acts: i) as a cofactor in BER pathway through functional interaction with DNA glycosylases OGG1, TDG and SMUG1; ii) as coactivator in transcription at Oct4/Sox2, RXR and PPARα responsive elements; iii) in metabolic shift during keratinocytes transformation. Thus, we sought to investigate a possible role for XPC in the maintenance of mtDNA integrity, cellular sensitivity to mitochondrial redox stress and eventual bioenergetic and redox changes. For this purpose, we established an in vitro plasmid incision assay to investigate the possible role of XPC in the repair of oxidized lesions in mitochondrial DNA. However, our data revealed that XPC did not localized in mitochondria. Nonetheless, XP-C cells are more sensitive to methylene blue, antimycin A (AA) and rotenone treatment, which induce mitochondrial redox stress. The XP-C sensitivity to AA was completely reverted in XPC-corrected cells. XP-C cells presented altered usage of mitochondrial complexes, with decreased oxygen consumption rate (OCR) via complex I and increased OCR through complex II, an XPC-dependent phenomenon. Furthermore, the XP-C cell line showed mitochondrial redox imbalance with increased ROS production and decrease GPx activity. MtDNA from XP-C cells accumulate lesions and deletions, which, however, were found at similar levels in the corrected cell line. We identified a sharp decrease in the expression of PPARGC1A, a master regulator of mitochondrial biogenesis. Nevertheless, it was not possible to determine the mechanism of suppression of PPARGC1A expression. Finally, our results suggest a possible link between the type of XPC mutation and PPARGC1A expression. This study unfolds new possible roles for XPC, aside from its established roles in genomic instability, in metabolic adaptation and redox imbalance towards tumour progression.

Desequilíbrio redox

PPARGC1A

Regulação

Reparação do DNA

XPC

Electron transport chain complexes

PPARGC1A

Redox imbalance

Regulation

Repair of DNA

XPC

Vliv antidepresiv a depresivní poruchy na mitochondriální funkce / Effects of antidepressants and depressive disorders on mitochondrial functions

Hroudová, Jana

January 2012

Mood disorders are serious diseases. Nevertheless, their pathophysiology is not sufficiently clarified. Biological markers that would facilitate the diagnosis or successful prediction of pharmacotherapy are still being sought. The aim of the study was to find out whether mitochondrial functions are affected by antidepressants, mood stabilizers and depression. Our research is based on recent hypotheses of mood disorders, the advanced monoamine hypothesis, the neurotrophic hypothesis, and the mitochondrial dysfunction hypothesis. We assume that impaired function of mitochondria leads to neuronal damage and can be related to the origin of mood disorders. Effects of antidepressants and mood stabilizers on mitochondrial functions can be related to their therapeutic or side effects. In vitro effects of pharmacologically different antidepressants and mood stabilizers on the activities of mitochondrial enzymes were measured in mitochondria isolated from pig brains (in vitro model). Activity of monoamine oxidase (MAO) isoforms was determined radiochemically, activities of other mitochondrial enzymes were measured spectrophotometrically. Overall activity of the system of oxidative phosphorylation was measured electrochemically using high- resolution respirometry. Methods were modified to measure the same...