Your search keyword '"Mitochondrial Turnover"' showing total 12 results

1. Unravelling mitochondrial pathways to <scp>P</scp> arkinson's disease

Author

S Gandhi, Ivana Celardo, and L M Martins

Subjects

Mitochondrial Diseases, Mitochondrial Turnover, Parkinson's disease, respiratory chain, Mitochondrial Degradation, free radicals, PINK1, Mitochondrion, Biology, DNA, Mitochondrial, Mitochondrial Dynamics, Models, Biological, PARKIN, Mitophagy, medicine, Animals, Homeostasis, Humans, oxidative stress, Inflammation, Neurons, Pharmacology, calcium, Neurodegeneration, Parkinson Disease, medicine.disease, Cell biology, mitochondria, mitochondrial fusion, Mitochondrial biogenesis, Nerve Degeneration, Themed Issue: Mitochondrial Pharmacology: Energy, Injury & Beyond, Neuroscience

Abstract

Mitochondria are essential for cellular function due to their role in ATP production, calcium homeostasis and apoptotic signalling. Neurons are heavily reliant on mitochondrial integrity for their complex signalling, plasticity and excitability properties, and to ensure cell survival over decades. The maintenance of a pool of healthy mitochondria that can meet the bioenergetic demands of a neuron, is therefore of critical importance; this is achieved by maintaining a careful balance between mitochondrial biogenesis, mitochondrial trafficking, mitochondrial dynamics and mitophagy. The molecular mechanisms that underlie these processes are gradually being elucidated. It is widely recognized that mitochondrial dysfunction occurs in many neurodegenerative diseases, including Parkinson's disease. Mitochondrial dysfunction in the form of reduced bioenergetic capacity, increased oxidative stress and reduced resistance to stress, is observed in several Parkinson's disease models. However, identification of the recessive genes implicated in Parkinson's disease has revealed a common pathway involving mitochondrial dynamics, transport, turnover and mitophagy. This body of work has led to the hypothesis that the homeostatic mechanisms that ensure a healthy mitochondrial pool are key to neuronal function and integrity. In this paradigm, impaired mitochondrial dynamics and clearance result in the accumulation of damaged and dysfunctional mitochondria, which may directly induce neuronal dysfunction and death. In this review, we consider the mechanisms by which mitochondrial dysfunction may lead to neurodegeneration. In particular, we focus on the mechanisms that underlie mitochondrial homeostasis, and discuss their importance in neuronal integrity and neurodegeneration in Parkinson's disease. LINKED ARTICLES This article is part of a themed issue on Mitochondrial Pharmacology: Energy, Injury & Beyond. To view the other articles in this issue visit http://dx.doi.org/10.1111/bph.2014.171.issue-8

Published

2014

2. Mitochondrial protein quality control in health and disease

Author

Diana Stojanovski, Michael J. Baker, and Catherine S Palmer

Subjects

Pharmacology, education.field_of_study, Mitochondrial Turnover, Population, Mitochondrial Degradation, Disease, Biology, Mitochondrion, Bioinformatics, Cell biology, mitochondrial fusion, Mitophagy, DNAJA3, education

Abstract

Progressive mitochondrial dysfunction is linked with the onset of many age-related pathologies and neurological disorders. Mitochondrial damage can come in many forms and be induced by a variety of cellular insults. To preserve organelle function during biogenesis or times of stress, multiple surveillance systems work to ensure the persistence of a functional mitochondrial network. This review provides an overview of these processes, which collectively contribute to the maintenance of a healthy mitochondrial population, which is critical for cell physiology and survival. Linked Articles This article is part of a themed issue on Mitochondrial Pharmacology: Energy, Injury & Beyond. To view the other articles in this issue visit http://dx.doi.org/10.1111/bph.2014.171.issue-8

Published

2014

3. Changes in mitochondrial function are pivotal in neurodegenerative and psychiatric disorders: How important is BDNF?

Author

Paul Franklin, Anthony Markham, R. Bains, and Michael Spedding

Subjects

Pharmacology, Brain-derived neurotrophic factor, medicine.medical_specialty, biology, Mitochondrial Turnover, Oxidative phosphorylation, Mitochondrion, Proinflammatory cytokine, Neurotrophic factors, Neuroplasticity, biology.protein, medicine, Psychiatry, Psychology, Neuroscience, Neurotrophin

Abstract

The brain is at the very limit of its energy supply and has evolved specific means of adapting function to energy supply, of which mitochondria form a crucial link. Neurotrophic and inflammatory processes may not only have opposite effects on neuroplasticity, but also involve opposite effects on mitochondrial oxidative phosphorylation and glycolytic processes, respectively, modulated by stress and glucocorticoids, which also have marked effects on mood. Neurodegenerative processes show marked disorders in oxidative metabolism in key brain areas, sometimes decades before symptoms appear (Parkinson's and Alzheimer's diseases). We argue that brain-derived neurotrophic factor couples activity to changes in respiratory efficiency and these effects may be opposed by inflammatory cytokines, a key factor in neurodegenerative processes. Linked Articles This article is part of a themed issue on Mitochondrial Pharmacology: Energy, Injury & Beyond. To view the other articles in this issue visit http://dx.doi.org/10.1111/bph.2014.171.issue-8

Published

2014

4. Turn up the power - pharmacological activation of mitochondrial biogenesis in mouse models

Author

David R. Thorburn and Jasper C. Komen

Subjects

Pharmacology, Genetics, biology, Sirtuin 1, Mitochondrial Turnover, Genetic heterogeneity, Mitochondrial disease, Oxidative phosphorylation, Mitochondrion, Bioinformatics, medicine.disease, Mitochondrial biogenesis, AMP-activated protein kinase, biology.protein, medicine

Abstract

The oxidative phosphorylation (OXPHOS) system in mitochondria is responsible for the generation of the majority of cellular energy in the form of ATP. Patients with genetic OXPHOS disorders form the largest group of inborn errors of metabolism. Unfortunately, there is still a lack of efficient therapies for these disorders other than management of symptoms. Developing therapies has been complicated because, although the total group of OXPHOS patients is relatively large, there is enormous clinical and genetic heterogeneity within this patient population. Thus there has been a lot of interest in generating relevant mouse models for the different kinds of OXPHOS disorders. The most common treatment strategies tested in these mouse models have aimed to up-regulate mitochondrial biogenesis, in order to increase the residual OXPHOS activity present in affected animals and thereby to ameliorate the energy deficiency. Drugs such as bezafibrate, resveratrol and AICAR target the master regulator of mitochondrial biogenesis PGC-1α either directly or indirectly to manipulate mitochondrial metabolism. This review will summarize the outcome of preclinical treatment trials with these drugs in mouse models of OXPHOS disorders and discuss similar treatments in a number of mouse models of common diseases in which pathology is closely linked to mitochondrial dysfunction. In the majority of these studies the pharmacological activation of the PGC-1α axis shows true potential as therapy; however, other effects besides mitochondrial biogenesis may be contributing to this as well. Linked Articles This article is part of a themed issue on Mitochondrial Pharmacology: Energy, Injury & Beyond. To view the other articles in this issue visit http://dx.doi.org/10.1111/bph.2014.171.issue-8

Published

2014

5. Adaptability to hypobaric hypoxia is facilitated through mitochondrial bioenergetics: anin vivostudy

Author

Rathanam Boopathy and Loganathan Chitra

Subjects

Pharmacology, FIS1, Mitochondrial DNA, Biochemistry, Mitochondrial biogenesis, Mitochondrial Turnover, MFN2, Mitochondrial fission, Mitochondrion, Biology, Lung injury, Cell biology

Abstract

Background and Purpose High-altitude pulmonary oedema (HAPE) experienced under high-altitude conditions is attributed to mitochondrial redox distress. Hence, hypobaric hypoxia (HH)-induced alteration in expression of mitochondrial biogenesis and dynamics genes was determined in rat lung. Further, such alteration was correlated with expression of mitochondrial DNA (mtDNA)-encoded oxidative phosphorylation (mtOXPHOS) genes. The prophylactic effect of dexamethasone (DEX) in counteracting the HH-induced mitochondrial distress was used as control to understand adaptation to high-altitude exposure. Experimental Approach Rats pretreated with DEX were exposed to normobaric normoxia (NN) or HH. HH-induced injury was assessed as an increase in lung water content, tissue damage and oxidant generation. Mitochondrial number, mtDNA content and mtOXPHOS activities were measured to determine mitochondrial function. The expression of mitochondrial biogenesis, dynamics and mtOXPHOS genes was studied. Key Results HH-induced lung injury was associated with decreased mitochondrial number, mtDNA content and mtOXPHOS activities. HH exposure decreased the nuclear gene oestrogen-related receptor-α (ERRα), which interacts with PPAR-γ coactivator-1α (PGC-1α) in controlling mitochondrial metabolism. Consequently, mtOXPHOS transcripts are repressed under HH. Further, HH modulated mitochondrial dynamics by decreasing mitofusin 2 (Mfn2) and augmenting fission 1 (Fis1) and dynamin-related protein 1 (Drp1) expression. Nevertheless, DEX treatment under NN (i.e. adaptation to HH) did not affect mitochondrial biogenesis and dynamics, but increased mtOXPHOS transcripts. Further, mtOXPHOS activities increased together with reduced oxidant generation. Also, DEX pretreatment normalized ERRα along with mitochondrial dynamics genes and increased mtOXPHOS transcripts to elicit the mitochondrial function under HH. Conclusions and Implications HH stress (HAPE)-mediated mitochondrial dysfunction is due to repressed ERRα and mtOXPHOS transcripts. Thus, ERRα-mediated protection of mitochondrial bioenergetics might be the likely candidate required for lung adaptation to HH.

Published

2013

6. Development of pharmacological strategies for mitochondrial disorders

Author

M, Kanabus, S J, Heales, and S, Rahman

Subjects

Clinical Trials as Topic, mitochondrial diseases, mitochondrial biogenesis, nutritional and cofactor support in mitochondrial disorders, Genetic Therapy, Mitochondrial Turnover, models for mitochondrial disorders, Models, Biological, Antioxidants, Oxidative Phosphorylation, treatments for mitochondrial disorders, Mitochondria, clinical trials for mitochondrial disorders, gene therapy for mitochondrial diseases, Disease Models, Animal, Animals, Humans, Themed Issue: Mitochondrial Pharmacology: Energy, Injury & Beyond, Molecular Targeted Therapy, Energy Metabolism

Abstract

Mitochondrial diseases are an unusually genetically and phenotypically heterogeneous group of disorders, which are extremely challenging to treat. Currently, apart from supportive therapy, there are no effective treatments for the vast majority of mitochondrial diseases. Huge scientific effort, however, is being put into understanding the mechanisms underlying mitochondrial disease pathology and developing potential treatments. To date, a variety of treatments have been evaluated by randomized clinical trials, but unfortunately, none of these has delivered breakthrough results. Increased understanding of mitochondrial pathways and the development of many animal models, some of which are accurate phenocopies of human diseases, are facilitating the discovery and evaluation of novel prospective treatments. Targeting reactive oxygen species has been a treatment of interest for many years; however, only in recent years has it been possible to direct antioxidant delivery specifically into the mitochondria. Increasing mitochondrial biogenesis, whether by pharmacological approaches, dietary manipulation or exercise therapy, is also currently an active area of research. Modulating mitochondrial dynamics and mitophagy and the mitochondrial membrane lipid milieu have also emerged as possible treatment strategies. Recent technological advances in gene therapy, including allotopic and transkingdom gene expression and mitochondrially targeted transcription activator-like nucleases, have led to promising results in cell and animal models of mitochondrial diseases, but most of these techniques are still far from clinical application. Linked Articles This article is part of a themed issue on Mitochondrial Pharmacology: Energy, Injury & Beyond. To view the other articles in this issue visit http://dx.doi.org/10.1111/bph.2014.171.issue-8

Published

2013

7. Changes in mitochondrial function are pivotal in neurodegenerative and psychiatric disorders: how important is BDNF?

Author

A, Markham, R, Bains, P, Franklin, and M, Spedding

Subjects

Aging, Neuronal Plasticity, Brain-Derived Neurotrophic Factor, Mental Disorders, Neurogenesis, Models, Neurological, Brain, Apoptosis, Neurodegenerative Diseases, Mitochondrial Turnover, Mitochondrial Dynamics, Mitochondria, Cognition, Neuroprotective Agents, Animals, Humans, Calcium, Themed Issue: Mitochondrial Pharmacology: Energy, Injury & Beyond, Energy Intake, Exercise, Glucocorticoids

Abstract

The brain is at the very limit of its energy supply and has evolved specific means of adapting function to energy supply, of which mitochondria form a crucial link. Neurotrophic and inflammatory processes may not only have opposite effects on neuroplasticity, but also involve opposite effects on mitochondrial oxidative phosphorylation and glycolytic processes, respectively, modulated by stress and glucocorticoids, which also have marked effects on mood. Neurodegenerative processes show marked disorders in oxidative metabolism in key brain areas, sometimes decades before symptoms appear (Parkinson's and Alzheimer's diseases). We argue that brain-derived neurotrophic factor couples activity to changes in respiratory efficiency and these effects may be opposed by inflammatory cytokines, a key factor in neurodegenerative processes.

Published

2013

8. Turn up the power - pharmacological activation of mitochondrial biogenesis in mouse models

Author

J C, Komen and D R, Thorburn

Subjects

Mitochondrial Diseases, Mitochondrial Turnover, AMP-Activated Protein Kinases, Ribonucleotides, Aminoimidazole Carboxamide, Peroxisome Proliferator-Activated Receptor Gamma Coactivator 1-alpha, Mitochondria, Up-Regulation, Disease Models, Animal, Sirtuin 1, Resveratrol, Stilbenes, Animals, Themed Issue: Mitochondrial Pharmacology: Energy, Injury & Beyond, Bezafibrate, Energy Metabolism, Transcription Factors

Abstract

The oxidative phosphorylation (OXPHOS) system in mitochondria is responsible for the generation of the majority of cellular energy in the form of ATP. Patients with genetic OXPHOS disorders form the largest group of inborn errors of metabolism. Unfortunately, there is still a lack of efficient therapies for these disorders other than management of symptoms. Developing therapies has been complicated because, although the total group of OXPHOS patients is relatively large, there is enormous clinical and genetic heterogeneity within this patient population. Thus there has been a lot of interest in generating relevant mouse models for the different kinds of OXPHOS disorders. The most common treatment strategies tested in these mouse models have aimed to up-regulate mitochondrial biogenesis, in order to increase the residual OXPHOS activity present in affected animals and thereby to ameliorate the energy deficiency. Drugs such as bezafibrate, resveratrol and AICAR target the master regulator of mitochondrial biogenesis PGC-1α either directly or indirectly to manipulate mitochondrial metabolism. This review will summarize the outcome of preclinical treatment trials with these drugs in mouse models of OXPHOS disorders and discuss similar treatments in a number of mouse models of common diseases in which pathology is closely linked to mitochondrial dysfunction. In the majority of these studies the pharmacological activation of the PGC-1α axis shows true potential as therapy; however, other effects besides mitochondrial biogenesis may be contributing to this as well.

Published

2013

9. Mitochondrial protein quality control in health and disease

Author

Michael J, Baker, Catherine S, Palmer, and Diana, Stojanovski

Subjects

Mitochondrial Proteins, Cell Death, Mitophagy, Homeostasis, Humans, Neurodegenerative Diseases, Themed Issue: Mitochondrial Pharmacology: Energy, Injury & Beyond, Mitochondrial Turnover, Models, Biological

Abstract

Progressive mitochondrial dysfunction is linked with the onset of many age-related pathologies and neurological disorders. Mitochondrial damage can come in many forms and be induced by a variety of cellular insults. To preserve organelle function during biogenesis or times of stress, multiple surveillance systems work to ensure the persistence of a functional mitochondrial network. This review provides an overview of these processes, which collectively contribute to the maintenance of a healthy mitochondrial population, which is critical for cell physiology and survival.

Published

2013

10. Mitochondrial protein quality control in health and disease.

Author

Baker MJ, Palmer CS, and Stojanovski D

Subjects

Cell Death, Humans, Mitophagy, Models, Biological, Homeostasis, Mitochondrial Proteins metabolism, Mitochondrial Turnover, Neurodegenerative Diseases metabolism

Abstract

Progressive mitochondrial dysfunction is linked with the onset of many age-related pathologies and neurological disorders. Mitochondrial damage can come in many forms and be induced by a variety of cellular insults. To preserve organelle function during biogenesis or times of stress, multiple surveillance systems work to ensure the persistence of a functional mitochondrial network. This review provides an overview of these processes, which collectively contribute to the maintenance of a healthy mitochondrial population, which is critical for cell physiology and survival., (© 2013 The British Pharmacological Society.)

Published

2014

11. Adaptability to hypobaric hypoxia is facilitated through mitochondrial bioenergetics: an in vivo study.

Author

Chitra L and Boopathy R

Subjects

Animals, DNA metabolism, Dexamethasone pharmacology, Energy Metabolism, Gene Expression Regulation drug effects, Male, Mitochondrial Turnover, Oxidative Stress, RNA, Messenger metabolism, Rats, Sprague-Dawley, ERRalpha Estrogen-Related Receptor, Hypoxia metabolism, Lung metabolism, Mitochondria metabolism, Receptors, Estrogen genetics

Abstract

Background and Purpose: High-altitude pulmonary oedema (HAPE) experienced under high-altitude conditions is attributed to mitochondrial redox distress. Hence, hypobaric hypoxia (HH)-induced alteration in expression of mitochondrial biogenesis and dynamics genes was determined in rat lung. Further, such alteration was correlated with expression of mitochondrial DNA (mtDNA)-encoded oxidative phosphorylation (mtOXPHOS) genes. The prophylactic effect of dexamethasone (DEX) in counteracting the HH-induced mitochondrial distress was used as control to understand adaptation to high-altitude exposure., Experimental Approach: Rats pretreated with DEX were exposed to normobaric normoxia (NN) or HH. HH-induced injury was assessed as an increase in lung water content, tissue damage and oxidant generation. Mitochondrial number, mtDNA content and mtOXPHOS activities were measured to determine mitochondrial function. The expression of mitochondrial biogenesis, dynamics and mtOXPHOS genes was studied., Key Results: HH-induced lung injury was associated with decreased mitochondrial number, mtDNA content and mtOXPHOS activities. HH exposure decreased the nuclear gene oestrogen-related receptor-α (ERRα), which interacts with PPAR-γ coactivator-1α (PGC-1α) in controlling mitochondrial metabolism. Consequently, mtOXPHOS transcripts are repressed under HH. Further, HH modulated mitochondrial dynamics by decreasing mitofusin 2 (Mfn2) and augmenting fission 1 (Fis1) and dynamin-related protein 1 (Drp1) expression. Nevertheless, DEX treatment under NN (i.e. adaptation to HH) did not affect mitochondrial biogenesis and dynamics, but increased mtOXPHOS transcripts. Further, mtOXPHOS activities increased together with reduced oxidant generation. Also, DEX pretreatment normalized ERRα along with mitochondrial dynamics genes and increased mtOXPHOS transcripts to elicit the mitochondrial function under HH., Conclusions and Implications: HH stress (HAPE)-mediated mitochondrial dysfunction is due to repressed ERRα and mtOXPHOS transcripts. Thus, ERRα-mediated protection of mitochondrial bioenergetics might be the likely candidate required for lung adaptation to HH., (© 2013 The Authors. British Journal of Pharmacology © 2013 The British Pharmacological Society.)

Published

2013

12. [Untitled]

Subjects

Pharmacology, Genetics, 0303 health sciences, Mitochondrial Turnover, Mitochondrial disease, Genetic enhancement, Exercise therapy, Mitochondrion, Biology, medicine.disease, Bioinformatics, 3. Good health, 03 medical and health sciences, 0302 clinical medicine, Mitochondrial biogenesis, Mitophagy, medicine, Inner mitochondrial membrane, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Mitochondrial diseases are an unusually genetically and phenotypically heterogeneous group of disorders, which are extremely challenging to treat. Currently, apart from supportive therapy, there are no effective treatments for the vast majority of mitochondrial diseases. Huge scientific effort, however, is being put into understanding the mechanisms underlying mitochondrial disease pathology and developing potential treatments. To date, a variety of treatments have been evaluated by randomized clinical trials, but unfortunately, none of these has delivered breakthrough results. Increased understanding of mitochondrial pathways and the development of many animal models, some of which are accurate phenocopies of human diseases, are facilitating the discovery and evaluation of novel prospective treatments. Targeting reactive oxygen species has been a treatment of interest for many years; however, only in recent years has it been possible to direct antioxidant delivery specifically into the mitochondria. Increasing mitochondrial biogenesis, whether by pharmacological approaches, dietary manipulation or exercise therapy, is also currently an active area of research. Modulating mitochondrial dynamics and mitophagy and the mitochondrial membrane lipid milieu have also emerged as possible treatment strategies. Recent technological advances in gene therapy, including allotopic and transkingdom gene expression and mitochondrially targeted transcription activator-like nucleases, have led to promising results in cell and animal models of mitochondrial diseases, but most of these techniques are still far from clinical application. Linked Articles This article is part of a themed issue on Mitochondrial Pharmacology: Energy, Injury & Beyond. To view the other articles in this issue visit http://dx.doi.org/10.1111/bph.2014.171.issue-8