EFFECTS OF LAMINAR SHEAR STRESS ON MITOCHONDRIAL DNA INTEGRITY IN ENDOTHELIAL CELLS

Kim, Boa

January 2014

Purpose/hypothesis: Regular practice of exercise is the most effective non-pharmacological intervention that improves vascular health, which is thought to be mediated by a repeated exposure of vessel walls to increased hemodynamic shear stress (SS). Mitochondria have been shown to be essential cellular structures responsible for a wide variety of vascular functions, and its impairment is often associated with cardiovascular disease. However, researches on vascular mitochondrial adaptations to SS are in a very early stage and many questions remain unresolved. The objective of this study is to investigate the effect of exercise preconditioning on endothelial mitochondria in an angiotensin (Ang) II-induced hypertension model. It was hypothesized that exercise preconditioning prevents Ang II induced-hypertensive phenotypes by improving mitochondrial homeostasis in the endothelium. Methods: High-magnitude laminar SS (LSS) (20 dyne/cm2) was applied to human aortic endothelial cells (HAECs) using a cone-and-plate shear apparatus for 48 hours. Either LSS-preconditioned or static flow-situated HAECs were incubated with Ang II. In in vivo experiments, C57BL/6J mice were singly housed with or without a voluntary running wheel for 7 weeks. Ang II or saline was infused in a constant rate using an implantable osmotic pump for the last 2 weeks of the experimental period. Mitochondrial membrane potential (ÄØm) and mitoROS production were measured using fluorochrome molecular probe-based microscopic techniques, and mtDNA damage was assessed by a long amplicon quantitative PCR (LA-QPCR) method. Results: In HAECs, LSS preconditioning attenuated Ang II-induced mitochondrial dysfunction, which was evidenced by decreased mitoROS generation, increased ÄØm, and reduced mtDNA damage. Likewise, in aortic tissues, Ang II-induced mitochondrial phenotypic changes (i.e. mitoROS production, mtDNA damage and ÄØm reduction) were significantly reduced in exercise-preconditioned mice compared to sedentary controls. Moreover, Ang II-induced blood pressure elevation was completely blocked in exercise preconditioned animals. Conclusion: Taken together, high-magnitude LSS improves endothelial function by enhancing mtDNA integrity and mitochondrial function. These findings further support the idea that aerobic exercise is a prominent life-style modification strategy to prevent hypertension by targeting dysfunctional mitochondria in the vessel wall. / Kinesiology

Kinesiology

Physiology

Biology

Endothelial Cells

Hypertension

Mitochondria

Mtdna

Mtdna Damage

Shear Stress

O papel do fator de transcrição mitocondrial A (TFAM) na proteção do DNA mitocondrial contra lesões oxidadas / The Role of mitochondrial transcription factor a (TFAM)in the mitochondrial DNA protection against oxidative damage

Paulo Newton Tonolli

28 January 2014

O fator de transcrição mitocondrial A (TFAM) pertence ao grupo das proteínas de alta mobilidade, apresentando um importante papel para a replicação, transcrição e estrutura/organização do DNA mitocondrial (DNAmt). O DNAmt está organizado em um complexo nucleoprotéico, chamado de nucleóide, do qual TFAM é o principal componente protéico, empacotando o DNAmt de forma análoga às histonas no DNA nuclear. Em analogia ao DNA nuclear, foi sugerido que esse empacotamento pode proteger o DNAmt do ataque de espécies oxidantes, enquanto que, por outro lado, poderia também impedir o acesso das enzimas de reparo. Este trabalho visou esclarecer qual o papel de TFAM na proteção do DNAmt e entender como TFAM influencia o reparo do DNAmt. Nossos resultados indicaram que o empacotamento do DNAmt por TFAM pode proteger o DNA da formação de lesões em condições de estresse oxidativo. Células com redução na expressão de TFAM apresentaram taxas alteradas de proliferação e uma menor viabilidade celular após o tratamento com o fotossensibilizador azul de metileno, indicando que TFAM pode contribuir para a manutenção da integridade funcional da mitocondria. A velocidade do reparo do DNAmt, em células Kd-TFAM, foi aparentemente maior, o que indicou a importância da modulação da interação de TFAM com o DNAmt para um reparo rápido e eficiente das lesões oxidadas. Portanto, TFAM desempenha um papel importante para a estabilidade genômica mitocondrial, protegendo o DNAmt dos efeitos deletérios das lesões oxidadas no estresse oxidativo, e também modulando a velocidade do reparo do DNAmt, provavelmente através de modificações/interações que permitam que as enzimas de reparo acessem as lesões no DNAmt. / The mitochondrial transcription factor A (TFAM) belongs to the high mobility group box proteins, and is essencial for replication, transcription and structure/organization of the mitochondrial DNA (mtDNA).The mtDNA is organized in a nucleoproteic complex called the nucleoid, where TFAMis the main protein component,packaging mtDNA in a manner similar to histones in the nuclear DNA. In analogy to the histone role in nuclear DNA, it was suggested that mtDNA packaging by TFAM could protect the mtDNA against oxidized lesions. On the other hand, it could also prevent the access of repair enzymes. This study aimed to understand whether TFAM plays a role in mtDNA stability through these opposing effects of protecting from damage and preventing repair. Our results indicated that TFAM protects the mtDNA against lesion formation upon oxidative stress. Cells with reduced expression of TFAM showed altered proliferation and lower cellular viability after treatment with the photoactivated dye methylene blue, indicating an important role for TFAM in maintaining mitochondrial function and cell survival. MtDNA repair rate was apparently higherin Kd-TFAM cells, which indicated the importance of modulating the interaction of TFAM with mtDNA for a quick and efficient repair of oxidized lesions. Therefore, TFAM plays an important role in maintaining mitochondrial genomic stability by protecting the mtDNA of the deleterious effects of oxidized lesions in oxidative stress, also modulating mtDNA repair, likely through modifications/interactions that modulate its DNA binding activity and access to lesions in mtDNA by DNA repair enzymes.

EROs

Lesões DNAmt

Lesões oxidadas

Mitocôndrias

Reparo DNAmt

TFAM

Mitochondria

mtDNA damage

mtDNA repair

Oxidative damage

ROS

TFAM

O papel do fator de transcrição mitocondrial A (TFAM) na proteção do DNA mitocondrial contra lesões oxidadas / The Role of mitochondrial transcription factor a (TFAM)in the mitochondrial DNA protection against oxidative damage

Tonolli, Paulo Newton

28 January 2014

O fator de transcrição mitocondrial A (TFAM) pertence ao grupo das proteínas de alta mobilidade, apresentando um importante papel para a replicação, transcrição e estrutura/organização do DNA mitocondrial (DNAmt). O DNAmt está organizado em um complexo nucleoprotéico, chamado de nucleóide, do qual TFAM é o principal componente protéico, empacotando o DNAmt de forma análoga às histonas no DNA nuclear. Em analogia ao DNA nuclear, foi sugerido que esse empacotamento pode proteger o DNAmt do ataque de espécies oxidantes, enquanto que, por outro lado, poderia também impedir o acesso das enzimas de reparo. Este trabalho visou esclarecer qual o papel de TFAM na proteção do DNAmt e entender como TFAM influencia o reparo do DNAmt. Nossos resultados indicaram que o empacotamento do DNAmt por TFAM pode proteger o DNA da formação de lesões em condições de estresse oxidativo. Células com redução na expressão de TFAM apresentaram taxas alteradas de proliferação e uma menor viabilidade celular após o tratamento com o fotossensibilizador azul de metileno, indicando que TFAM pode contribuir para a manutenção da integridade funcional da mitocondria. A velocidade do reparo do DNAmt, em células Kd-TFAM, foi aparentemente maior, o que indicou a importância da modulação da interação de TFAM com o DNAmt para um reparo rápido e eficiente das lesões oxidadas. Portanto, TFAM desempenha um papel importante para a estabilidade genômica mitocondrial, protegendo o DNAmt dos efeitos deletérios das lesões oxidadas no estresse oxidativo, e também modulando a velocidade do reparo do DNAmt, provavelmente através de modificações/interações que permitam que as enzimas de reparo acessem as lesões no DNAmt. / The mitochondrial transcription factor A (TFAM) belongs to the high mobility group box proteins, and is essencial for replication, transcription and structure/organization of the mitochondrial DNA (mtDNA).The mtDNA is organized in a nucleoproteic complex called the nucleoid, where TFAMis the main protein component,packaging mtDNA in a manner similar to histones in the nuclear DNA. In analogy to the histone role in nuclear DNA, it was suggested that mtDNA packaging by TFAM could protect the mtDNA against oxidized lesions. On the other hand, it could also prevent the access of repair enzymes. This study aimed to understand whether TFAM plays a role in mtDNA stability through these opposing effects of protecting from damage and preventing repair. Our results indicated that TFAM protects the mtDNA against lesion formation upon oxidative stress. Cells with reduced expression of TFAM showed altered proliferation and lower cellular viability after treatment with the photoactivated dye methylene blue, indicating an important role for TFAM in maintaining mitochondrial function and cell survival. MtDNA repair rate was apparently higherin Kd-TFAM cells, which indicated the importance of modulating the interaction of TFAM with mtDNA for a quick and efficient repair of oxidized lesions. Therefore, TFAM plays an important role in maintaining mitochondrial genomic stability by protecting the mtDNA of the deleterious effects of oxidized lesions in oxidative stress, also modulating mtDNA repair, likely through modifications/interactions that modulate its DNA binding activity and access to lesions in mtDNA by DNA repair enzymes.

EROs

Lesões DNAmt

Lesões oxidadas

Mitochondria

Mitocôndrias

mtDNA damage

mtDNA repair

Oxidative damage

Reparo DNAmt

ROS

TFAM

TFAM