Mitochondrial Quality Control Adaptations Support Malignant Progression of Serous Ovarian Cancer Cells and Spheroids

Grieco, Joseph Patrick

26 April 2022

Serous ovarian cancer is the 5th leading cause of cancer-related deaths in women, with a 30% survival rate when spread into the highly hypoxic and visceral peritoneal cavity. Despite efforts to treat this highly metastatic disease, traditional chemotherapeutic and cytoreductive therapies are unable to diminish or induce cell death of circulating metastases from colonizing secondary sites due to their genetic and histologic heterogeneity and development of drug resistance. The dissemination route for primary metastasis, however, is most often conserved to the peritoneal cavity, which is low in nutrients and hypoxic (1-2% O2). Cells exfoliated from the primary tumor will aggregate during migration, which elicits a survival signal to maintain viability in this environment. The underlying cellular and molecular changes involved with aggregation have yet to be determined. We have previously found that aggregation of murine ovarian surface epithelial (MOSE) cells present a more suppressed metabolic phenotype upon aggregation. My research sought to identify how the mitochondria were internally regulated to support malignant transformation, migration, and invasion through modulation of quality control, mitochondrial dynamics, mitophagy, and mitobiogenesis. We have shown that aggregation of cancer cells supports increased mitochondrial fragmentation localized to the hypoxic core of our spheroid models. Further, aggregation supports enhanced viability through an upregulation of cancer genetic pathways associated with cell death, proliferation, stemness, and epithelial mesenchymal transition (EMT). Nutrient deprivation during migration further enhanced mitochondrial fragmentation and induction of mitophagy to prevent activation of apoptosis. Additionally, we have identified a phenotypic switch from enhanced mitophagy during peritoneal dissemination that supports survival of ovarian cancer cell aggregates to mitochondrial biogenesis during secondary tissue colonization that enables proliferation upon invasion. We have associated these changes with an increased bioenergetic proliferative niche through inhibition of proliferation, migration, and mitochondrial translation. This research has contributed to the understanding for the role of mitophagy as a survival rather than apoptotic signal in cancer cells as adaptation to nutrient-deprived environments, while also identifying how these processes can be reversed upon adhesion to support invasion and metastatic capacity during secondary colonization. This research is significant because it will identify molecular adaptations associated with the viability of disseminating cancer metastases as well as promote novel preventative therapeutics that can be used to limit the mortality of highly aggressive ovarian cancer in women. / Doctor of Philosophy / Ovarian cancer continues to be one of the highest contributors of gynecologic cancer-related deaths in women. This is due to limited symptomology, biomarker availability, and screenings for patients. Women are mostly diagnosed when the disease has already spread throughout the abdominal cavity which makes treatment much more difficult and, accordingly, the survival rate is much lower. Ovarian metastases mostly spread throughout the peritoneal cavity. Interestingly, this cavity has been identified to being limited in nutrients and oxygen that are essential for survival thus suggesting that these cancer cells must adapt to these harsh conditions to remain viable. We have previously observed that the cancer cells are able to clump together, and form 3D structures known as spheroids which have drastically reduced their proliferation and appear highly resistant tor treatment than single cells. In this project, we wanted to determine how the mitochondria (primary energy producers) were structurally changing in response to the formation of these spheroids and in nutrient- and oxygen-starved conditions. We have found that these organelles become much smaller and circular in low-oxygen conditions, especially in the center of the spheroids. Further, we found changes in cancer- and mitochondrial-related pathways during spheroid formation which could further support survival. Finally, we found that key functions related to the mitochondrial quality control and enhanced mitochondrial content and activity are switched when changing nutrient availability from low oxygen and nutrient conditions to oxygenated and nutrient-rich conditions and generate conditions that allow the spheroids to attach to abdominal organs and form secondary tumors. This research is important because it suggests new possible markers that can be used as therapeutic targets to prevent these aggressive functions associated with more terminally staged disease.

mitochondria

ovarian cancer

mitophagy

mitochondrial dynamics

mitobiogenesis

viability

reactive oxygen species

spheroid

Mitochondrial Dynamics Alteration in Astrocytes Following Primary Blast-Induced Traumatic Brain Injury

Guilhaume Correa, Fernanda

11 January 2023

Mild blast-induced traumatic brain injury (bTBI) is a modality of injury that has been of major concern considering a large number of military personnel exposed to the blast wave from explosives. bTBI results from the propagation of high-pressure static blast forces and their subsequent energy transmission within brain tissue. Current literature presents a neuro-centric approach to the role of mitochondria dynamics dysfunction in bTBI; however, changes in astrocyte-specific mitochondrial dynamics have not been characterized. As a result of fission and fusion, the mitochondrial structure is constantly altering shape to respond to physiological stimuli or stress insults by adapting structure and function, which are intimately connected. Dysregulation of the protein regulator of mitochondrial fission, DRP1, and upregulation in the phosphorylation of DRP1 at the serine 616 site is reported to play a crucial role in astrocytic mitochondrial dysfunction, favoring fission over fusion post-TBI. Astrocytic mitochondria are starting to be recognized to play an essential role in overall brain metabolism, synaptic transmission, and neuron protection. Mitochondria are vulnerable to injury insults leading to the worsening of mitochondrial fission and increased mitochondrial fragmentation. In this study, a combination of in vitro and in vivo bTBI models were used to examine the effect of blast on astrocytic mitochondrial dynamics. Acute differential remodeling of the astrocytic mitochondrial network was observed, accompanied by an acute (4hr) and sub-acute (7 days) activation of the GTP-protein DRP1. Further, results showed a time-dependent reactive astrocyte phenotype transition in the rat hippocampus. This discovery can lead to innovative therapeutics targets to help prevent secondary injury cascades that involve mitochondria dysfunction. / Doctor of Philosophy / Blast-induced traumatic brain injury (bTBI) is a modality of injury that has become prominent considering a large number of military personnel exposed to a blast wave caused by explosives. Blast injury results from the energy transmission of the blast wave to the brain. Within the brain, there are specialized cells, called astrocytes, that help maintain a healthy environment. This work investigates the role that astrocytes play during the injury recovery process. Within the astrocytes, there are organelles called mitochondria, that help maintain the energy for the cell. The number and function of mitochondria can change in response to the brain injury. They can increase in number by a process called fission and they can decrease in number by a process called fusion. These events effect the function of the mitochondria. Researchers have methods that can identify changes in the number and function of the mitochondria. In this work, astrocyte mitochondrial dynamics were examined and compared using models of bTBI. We found significant changes in the mitochondria of astrocytes, which could lead to an unhealthy environment in the brain. This discovery can lead to new treatments for patients that may improve their quality of life following bTBI.

mild

acute

sub-acute

astrocytes

mitochondrial dynamics

fission

Skeletal muscle autophagy and mitophagy in response to high-fat feeding and endurance training

Tarpey, Michael

13 January 2016

Obesity is associated with reduced skeletal muscle insulin sensitivity, a major risk factor for development of type II diabetes. These metabolic diseases are commonly associated with an accumulation of mitochondrial dysfunction, which is speculated to contribute toward insulin resistance. High-fat diets reduce human skeletal muscle insulin sensitivity and mitochondrial function. Conversely, endurance training increases insulin sensitivity and enhances mitochondrial performance. Recent evidence in mice has found that central mechanisms of mitochondrial quality control, autophagy and mitophagy, may be suppressed in response to excess fat intake, but upregulated following endurance exercise training. These data may provide a mechanism for dietary and exercise-mediated regulation of mitochondrial quality and metabolic function. The current study investigated the impact of an acute high-fat diet on skeletal muscle autophagy and mitophagy in sedentary, healthy, non-obese college age males'. The expression of skeletal muscle autophagy and mitophagy protein markers were analyzed in response to a high-fat meal before and after a 5-day high-fat diet. Next, we examined the differences in skeletal muscle autophagy and mitophagy protein markers, and associations with skeletal muscle metabolic flexibility between endurance-trained male runners' and sedentary, healthy, non-obese males' following an overnight fast and in response to a high-fat meal. Autophagy markers' indicated reduced autophagy activity in response to a high-fat meal and following a high-fat diet, which exacerbated the high-fat meal response. However, these data could not be confirmed due to methodological limitations. Mitophagy markers were not significantly affected by the high-fat meal or diet. There were no significant differences in the expression of autophagy protein markers between endurance-trained and sedentary groups', but mitophagy markers were significantly elevated in endurance-trained runners'. Metabolic flexibility was not significantly different between groups' following an overnight fast or in response to a high-fat meal, and was not associated with the expression of autophagy and mitophagy protein markers. In conclusion, autophagy may be suppressed by a 5-day high-fat diet, but further analysis is required for confirmation. Endurance-trained male runners show increased markers of mitophagy, which were not associated with improved metabolic flexibility while fasted or following a high-fat meal. / Ph. D.

mitophagy

autophagy

mitochondrial quality

mitochondrial dynamics

high-fat diet

endurance training

Caracterização da função e da dinâmica mitocondrial em modelo animal de disfunção cardíaca associada ao infarto do miocárdio: efeitos do treinamento físico aeróbico / Characterization of mitochondrial metabolism and dynamics in cardiac dysfunction-induced myocardial infarction in rats: effects of exercise training

Campos, Juliane Cruz

12 June 2012

O infarto do miocárdio é atualmente considerado a etiologia que mais contribui para o aparecimento de insuficiência cardíaca (IC) em humanos. Em detrimento a hiperativação de fatores neuro-humorais, a progressão da IC é caracterizada por uma série de anormalidades celulares associadas à disfunção ventricular. Dentre estas anormalidades, alterações na função e dinâmica mitocondrial merecem destaque, uma vez que a homeostase da organela é essencial para a viabilidade celular e o bom funcionamento da bomba cardíaca. No presente estudo, caracterizamos em modelo animal de disfunção cardíaca associada ao infarto do miocárdio: a) fenótipo cardíaco; b) função mitocondrial; c) equilíbrio redox; e d) dinâmica mitocondrial. Nossos resultados nos permitem afirmar que doze semanas após a cirurgia de infarto do miocárdio, os animais desenvolveram importantes alterações fenotípicas como aumento da massa cardíaca, dilatação ventricular, hipertrofia do cardiomiócito e maior deposição de tecido fibroso cardíaco, que contribuíram para o estabelecimento da disfunção ventricular. Além disso, foi possível confirmar a instalação do quadro de disfunção mitocondrial cardíaca, representada pela redução na capacidade respiratória e perda da homeostase redox. Por fim, encontramos um aumento no número de mitocôndrias cardíacas com menor diâmetro, alterações que vieram acompanhadas de uma menor atividade das enzimas relacionadas à fusão mitocondrial. Uma vez caracterizada a função e a dinâmica mitocondrial na disfunção cardíaca, avaliamos o efeito do treinamento físico aeróbico (TF) nessas variáveis. O TF, atualmente utilizado como um adjuvante no tratamento das doenças cardiovasculares, foi eficaz em promover o remodelamento cardíaco reverso e melhorar a função cardíaca nos animais infartados. Além disso, melhorou a capacidade respiratória e reduziu o estresse oxidativo, restaurando a função mitocondrial. Aliado a esses achados, o TF normalizou a atividade das enzimas relacionadas à dinâmica mitocondrial, fato associado à normalização do número e tamanho da organela. Esses resultados demonstram que a disfunção cardíaca induzida por infarto do miocárdio está associada à um quadro de mitocondriopatia em ratos, com alterações tanto na função quanto estrutura mitocondrial, e que o TF desencadeia efeitos benéficos na manutenção da integridade/função mitocondrial e melhora da função contrátil cardíaca / Myocardial infarction is considered the etiology that most contributes to the onset of heart failure in humans. Among the ventricular dysfunction-associated cellular abnormalities, changes in mitochondrial function and dynamics are critical, since the organelle homeostasis is crucial in maintaining the metabolic, electrical and mechanical properties of the heart. In the present study, we characterized in cardiac dysfunction- induced myocardial infarction in rats: a) cardiac phenotype; b) mitochondrial metabolism; c) redox balance, and d) mitochondrial dynamics. Our results show that twelve weeks after myocardial surgery, the animals developed pathological cardiac remodeling-associated ventricular dysfunction. Furthermore, we observed a reduced mitochondrial respiratory capacity and loss of redox homeostasis. Finally, we found a lower activity of enzymes related to mitochondrial fusion, these changes were accompanied by an increase in the number of small mitochondria. Once characterized mitochondrial function and dynamics, we evaluated the effect of exercise training in these variables in rats with cardiac dysfunction. The exercise training, currently established as an important non-pharmacological treatment for cardiovascular diseases, reversed the pathological cardiac remodeling and minimized the ventricular dysfunction in infarcted animals. Furthermore, exercise training restored the mitochondrial function by increasing respiratory capacity and reducing oxidative stress. Finally, exercise training restored the activity of mitochondrial dynamics-related enzymes and morphology. Taken together, our findings uncover the potential benefits of exercise training in reversing the cardiac mitochondriopathy observed in failing hearts, reinforcing the importance of this intervention as a non-pharmacological tool for heart failure therapy

Cardiac dysfunction

Dinâmica mitocondrial

Disfunção cardíaca

Exercise training

Função mitocondrial

Mitochondrial dynamics

Mitochondrial function

Treinamento físico aeróbico

Caracterização da função e da dinâmica mitocondrial em modelo animal de disfunção cardíaca associada ao infarto do miocárdio: efeitos do treinamento físico aeróbico / Characterization of mitochondrial metabolism and dynamics in cardiac dysfunction-induced myocardial infarction in rats: effects of exercise training

Juliane Cruz Campos

12 June 2012

O infarto do miocárdio é atualmente considerado a etiologia que mais contribui para o aparecimento de insuficiência cardíaca (IC) em humanos. Em detrimento a hiperativação de fatores neuro-humorais, a progressão da IC é caracterizada por uma série de anormalidades celulares associadas à disfunção ventricular. Dentre estas anormalidades, alterações na função e dinâmica mitocondrial merecem destaque, uma vez que a homeostase da organela é essencial para a viabilidade celular e o bom funcionamento da bomba cardíaca. No presente estudo, caracterizamos em modelo animal de disfunção cardíaca associada ao infarto do miocárdio: a) fenótipo cardíaco; b) função mitocondrial; c) equilíbrio redox; e d) dinâmica mitocondrial. Nossos resultados nos permitem afirmar que doze semanas após a cirurgia de infarto do miocárdio, os animais desenvolveram importantes alterações fenotípicas como aumento da massa cardíaca, dilatação ventricular, hipertrofia do cardiomiócito e maior deposição de tecido fibroso cardíaco, que contribuíram para o estabelecimento da disfunção ventricular. Além disso, foi possível confirmar a instalação do quadro de disfunção mitocondrial cardíaca, representada pela redução na capacidade respiratória e perda da homeostase redox. Por fim, encontramos um aumento no número de mitocôndrias cardíacas com menor diâmetro, alterações que vieram acompanhadas de uma menor atividade das enzimas relacionadas à fusão mitocondrial. Uma vez caracterizada a função e a dinâmica mitocondrial na disfunção cardíaca, avaliamos o efeito do treinamento físico aeróbico (TF) nessas variáveis. O TF, atualmente utilizado como um adjuvante no tratamento das doenças cardiovasculares, foi eficaz em promover o remodelamento cardíaco reverso e melhorar a função cardíaca nos animais infartados. Além disso, melhorou a capacidade respiratória e reduziu o estresse oxidativo, restaurando a função mitocondrial. Aliado a esses achados, o TF normalizou a atividade das enzimas relacionadas à dinâmica mitocondrial, fato associado à normalização do número e tamanho da organela. Esses resultados demonstram que a disfunção cardíaca induzida por infarto do miocárdio está associada à um quadro de mitocondriopatia em ratos, com alterações tanto na função quanto estrutura mitocondrial, e que o TF desencadeia efeitos benéficos na manutenção da integridade/função mitocondrial e melhora da função contrátil cardíaca / Myocardial infarction is considered the etiology that most contributes to the onset of heart failure in humans. Among the ventricular dysfunction-associated cellular abnormalities, changes in mitochondrial function and dynamics are critical, since the organelle homeostasis is crucial in maintaining the metabolic, electrical and mechanical properties of the heart. In the present study, we characterized in cardiac dysfunction- induced myocardial infarction in rats: a) cardiac phenotype; b) mitochondrial metabolism; c) redox balance, and d) mitochondrial dynamics. Our results show that twelve weeks after myocardial surgery, the animals developed pathological cardiac remodeling-associated ventricular dysfunction. Furthermore, we observed a reduced mitochondrial respiratory capacity and loss of redox homeostasis. Finally, we found a lower activity of enzymes related to mitochondrial fusion, these changes were accompanied by an increase in the number of small mitochondria. Once characterized mitochondrial function and dynamics, we evaluated the effect of exercise training in these variables in rats with cardiac dysfunction. The exercise training, currently established as an important non-pharmacological treatment for cardiovascular diseases, reversed the pathological cardiac remodeling and minimized the ventricular dysfunction in infarcted animals. Furthermore, exercise training restored the mitochondrial function by increasing respiratory capacity and reducing oxidative stress. Finally, exercise training restored the activity of mitochondrial dynamics-related enzymes and morphology. Taken together, our findings uncover the potential benefits of exercise training in reversing the cardiac mitochondriopathy observed in failing hearts, reinforcing the importance of this intervention as a non-pharmacological tool for heart failure therapy

Dinâmica mitocondrial

Disfunção cardíaca

Função mitocondrial

Treinamento físico aeróbico

Cardiac dysfunction

Exercise training

Mitochondrial dynamics

Mitochondrial function

Le rôle de l’AMPK dans le vieillissement et la perte de plasticité neuronale liée au vieillissement chez C. elegans / Role of AMPK in aging and age-related loss of behavioral plasticity in C. elegans

Escoubas-Güney, Caroline

04 May 2018

La progression de l’espérance de vie observée au cours du XXième siècle a été accompagnée par une augmentation massive de l’incidence des maladies liées à l’âge et en particulier des maladies neurodégénératives. Malheureusement, les thérapeutiques actuelles ciblant principalement les anomalies d’agrégation protéique caractérisant ces maladies, tel que la maladie d’Alzheimer, ont échoué au niveau des essais cliniques. De récentes études épidémiologiques ont suggéré un lien entre la dysfonction métabolique et les maladies neurodégénératives. Par conséquent, une approche alternative pour développer des nouveaux médicaments serait se cibler les voies de signalisation métaboliques perturbées dans les modèles de maladie d’Alzheimer. L’AMPK (AMP activated protein kinase) est une enzyme activée par les bas niveaux d’énergie cellulaire via la détection du taux AMP : ATP. Une fois activée, l’AMPK allonge la durée de vie d’organismes modèles et protège contre le développement de pathologies liées à l’âge telle que les maladies neurodégénératives. De plus, l’AMPK régule l’homéostasie mitochondriale et les réseaux mitochondriaux chez les mammifères. Cependant, il reste à savoir si l’AMPK protège contre le développement de pathologies neurodégénératives via la régulation de la structure mitochondriale. Lors de ces travaux, nous avons utilisé un protocole d’apprentissage et de mémoire chez C. elegans pour mesurer la fonction neuronale. Nous avons montré que les nématodes exprimant le peptide amyloïde Aβ1-42 dans les neurones avait une capacité d’apprentissage détériorée. Ce déficit a pu être restauré par l’activation constitutionnelle de l’AMPK. Nous montrons également que l’activation de l’AMPK améliore les capacités d’apprentissage des nématodes sauvages en induisant la fusion des mitochondries. En effet, les vers mutés pour le gène responsable de la fusion mitochondriale ont une capacité d’apprentissage diminuée, laquelle peut être restaurée par le rétablissement de la fusion mitochondriale, spécifiquement dans les neurones. Des résultats supplémentaires suggèrent que l’AMPK induirait ses effets bénéfiques sur la fonction neuronale en inhibant le facteur de transcription CRTC-1 (CREB-regulated transcriptional co-activator 1). Nos résultats tendent à montrer que cibler le métabolisme cellulaire neuronal représenterait une option thérapeutique viable afin de maintenir les fonctions neuronales dans le cadre de pathologies neurodégénératives. / The dramatic increase in life expectancy during the 20th century was accompanied by a resultant epidemic of age-related pathologies including neurodegenerative diseases. Unfortunately, current therapeutics primarily focusing on protein misfolding aspects of diseases such as Alzheimer’s Disease (AD) have been unsuccessful in the clinical trials. Recent epidemiological studies have suggested a strong association between metabolic dysfunction and neurodegeneration. Therefore, an alternative approach is to target metabolic pathways disrupted in AD models for therapeutics. AMP activated protein kinase (AMPK) is activated in a low energy state via sensing the AMP: ATP ratio. Once active, AMPK promotes longevity in model organism and protects against a wide range of age related diseases including neurodegenerative diseases. In addition, AMPK regulates mitochondrial homeostasis and mitochondrial networks in mammals. However, whether mitochondrial regulation causally links AMPK to protection against neurodegenerative disease is unknown. Here we use a learning and memory protocol in C. elegans as readout of neuronal function. We show that nematodes expressing the toxic amyloid peptide Aβ1-42 in the neurons display impaired learning ability, which can be rescued by constitutive activation of AMPK (CA-AMPK). We further show that CA-AMPK enhances learning ability in wild type nematodes by promoting mitochondrial fusion. Indeed, fusion deficient worms show impaired learning, which can be rescued by restoring mitochondrial fusion specifically in the neurons. Additional results suggest that AMPK might promote its beneficial effects on neuronal function via inhibition of CREBregulated transcriptional co-activator 1 (CRTC-1). Our results show that targeting neuronal metabolism may be a viable therapeutic option to restore neuronal function in the context of neurodegenerative diseases.

Vieillissement

C. elegans

Maladie d'Alzheimer

Mémoire associative

AMPK

Dynamique mitochondriale

Aging

C. elegans

Alzheimer’s disease

Associative learning

AMPK

Mitochondrial dynamics

Muscle Stem Cell Fate is Directed by the Mitochondrial Fusion Protein OPA1

Baker, Nicole

06 April 2021

During aging there is a decline in (MuSCs) and muscle regeneration, though the underlying reason is unknown. Interestingly, mitochondrial fragmentation is a common feature in aging, however, how this impacts MuSC function and maintenance has not been investigated. To address the effect of mitochondrial fragmentation in MuSCs, we generated a knockout mouse model using the Pax7CreERT2 inducible system to target deletion of the mitochondrial fusion protein Opa1 specifically within MuSCs (Opa1-KO). Analysis of MuSC function following muscle injury revealed a defect in the regenerative potential of Opa1-KO MuSCs. Moreover, following injury there was a substantial decrease in the number of MuSC in Opa1-KO animals with a concomitant increase in the number of committing cells, illustrating that loss of Opa1 drives MuSC towards commitment at the expense of self-renewal. Furthermore, loss of Opa1 in MuSCs alters the quiescence state, priming MuSCs for activation, as indicated by a reduction in quiescence-related genes, increased EdU incorporation, and enhanced cell cycle kinetics. To address the impact of mitochondrial dysfunction on muscle stem cell capacity, we generated a model of chronic Opa1 loss. Analysis of muscle stem cell function 3 months after Opa1 ablation revealed mitochondrial dysfunction and a defect in proliferation upon activation, leading to failed muscle regeneration. These data are the first to demonstrate a novel role for mitochondrial structure in the regulation of MuSC maintenance and regenerative capacity.

Muscle Stem Cells

Mitochondrial Dynamics

Stem Cell Fate

OPA1

Quiescence

Activation

Metabolism

Gene Expression

Muscle Regeneration

Aging

Neuronal Mitofusin 2 Modulates Neuroinflammation in Acute Systemic Inflammation and Alleviates Pathologies in a Mouse Model for Neurodegenerative Diseases

Harland, Micah Thomas

01 June 2020

No description available.

Pathology

Immunology

Biology

Neurosciences

LPS

Mfn2

mitofusin

mitochondria

mitochondrial dynamics

CX3CL1

fractalkine

neurodegeneration

tauopathy

neuroinflammation

acute systemic inflammation

sickness behavior

Overexpression of the human optic atrophy-associated OPA1 gene induces mitochondrial and cellular fitness defects in yeast

Almazan, Annabel Vivian P.

07 June 2020

No description available.

Biology

Molecular Biology

Genetics

OPA1

mitochondria

mitochondrial dynamics

mitochondrial fusion

mitochondrial fission

dominant optic atrophy

optic atrophy type 1 gene

Regulation of mitochondrial gene copy number in plants and the influence of impaired chloroplast function on mitochondrial motility

Cincu, Emilia

10 April 2014

Das mitochondriale Genom der Pflanze weist mit einer heterogenen Population linearer, häufig auch verzweigten und zusätzlichen kleineren, zirkulären Molekülen eine komplexe Struktur auf. Um Einblicke in die mitochondrialen Genkopienzahl und deren Regulation sowohl unter normalen als auch unter Stressbedingungen zu erhalten, wurde die Kopienzahl pro Zelle vier repräsentativer Gene mittels qRT-PCR und Durchflusszytometrie ermittelt. Die Bestimmung der mitochondrialen Genkopienzahl in unterschiedlichen Spezies sowie in Organen der Modellpflanze Arabidopsis thaliana zeigte, dass die Kopienzahl mitochondrialer Gene sich nicht nur in den unterschiedlichen Spezies, sondern auch zwischen den unterschiedlichen Organen unterschied, wobei die höchsten Werte in der Wurzelspitze erreicht wurden. In Arabidopsis Keimlingen, welche zur Unterdrückung der plastidären Translation auf Spectinomycin-haltigem Medium angezogen wurden, wurde im Vergleich zu Kontrollpflanzen ein dreifacher Anstieg der Genkopienzahl festgestellt. Dieser Effekt erwies sich als spezifisch für Blatt- bzw. Kotyledonengewebe und warr unabhängig vom Licht. Mutanten mit Defekten in der Respiration zeigten ebenfalls erhöhte Genkopienzahlen, die durch Anzucht der Pflanzen auf Spectinomycin noch erhöht werden konnten. Dieses Ergebnis legt ein komplexes, regulatorisches Netzwerk nahe, in welchem sowohl Respiration als auch Photosynthese die Aufrechterhaltung einer stabilen Genkopienzahl innerhalb der Pflanzenzelle beeinflussen. Die Untersuchungen einer Spectinomycin-behandelter mt-GFP Arabidopsis Pflanzenlinie mittels CLSM zeigten einen Stillstand der Motilität der Mitochondrien in den epidermalen Zellen der weißen Kotyledonen, obwohl eine TEM Analyse eine normale, interne Morphologie ergab. Weitere Untersuchungen führten zu der Schlussfolgerung, dass es auch hier die Stärke der plastidären Beeinträchtigung, welche zu einem gelb-weißen Phänotyp führt, für den Arrest der Mobilität verantwortlich ist. / The plant mitochondrial genome has a complex structure. It exists in the form of a heterogeneous population of linear, often branched molecules with smaller than genome-size circular molecules being present in low abundance. In order to study the mitochondrial genome abundance and its regulation in plants under both standard and stress conditions, we determined the gene copy number of four representative mitochondrial genes using quantitative real-time PCR and flow-cytometry. Determination of mitochondrial gene copy number in different plant species and in organs of the model plant Arabidopsis thaliana showed that the copy number of the four investigated genes varied between species and also between different organs, having the highest values in the root tips. The growth of Arabidopsis seedlings on MS medium containing spectinomycin (a plastid translation inhibitor) led to a three-fold increase in the copy number in white versus green seedlings, an effect that is leaf/cotyledon specific and light-independent. Respiration deficient mutants also showed an increase in the gene copy number, this effect being further amplified when the mutants were grown on spectinomycin. The data suggest a complex regulatory network in which both photosynthesis and respiration influence the maintenance of a stable mitochondrial gene copy number within plant cells. CLSM investigations of a spectinomycin-treated mt-GFP line showed that in epidermal cells of white cotyledons most of the mitochondria are not motile with TEM analysis presenting normal internal morphology. Further investigations led to the conclusion that the threshold level of chloroplast impairment that leads to a motility arrest is represented by the appearance of a yellow-white cotyledon phenotype. These results point to a new regulatory mechanism of mitochondrial dynamics that is directly influenced by impaired chloroplast development under standard growth conditions.

Chondriom

mitochondriale Genkopienzahlen

Signalwege

mitochondriale Dynamik

Spektinomycin

signaling

chondriome

mitochondrial gene copy number

mitochondrial dynamics

spectinomycin

570 Biowissenschaften, Biologie

32 Biologie

WE 3100

ddc:570