Modeling mitochondrial dysfunctions in the brain: from mice to men.
Publication year
2012Source
Journal of Inherited Metabolic Disease, 35, 2, (2012), pp. 193-210ISSN
Annotation
01 maart 2012
Publication type
Article / Letter to editor
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Organization
Biochemistry (UMC)
Pharmacology-Toxicology
IMM - Institute for Molecules and Materials
Cell Biology (UMC)
Paediatrics - OUD tm 2017
Laboratory of Genetic, Endocrine and Metabolic Diseases
Journal title
Journal of Inherited Metabolic Disease
Volume
vol. 35
Issue
iss. 2
Page start
p. 193
Page end
p. 210
Subject
IGMD 8: Mitochondrial medicine NCMLS 4: Energy and redox metabolism; NCMLS 4: Energy and redox metabolism; NCMLS 4: Energy and redox metabolism IGMD 8: Mitochondrial medicine; NCMLS 5: Membrane transport and intracellular motility IGMD 9: Renal disorder; Laboratory Medicine Radboud University Medical CenterAbstract
The biologist Lewis Thomas once wrote: "my mitochondria comprise a very large proportion of me. I cannot do the calculation, but I suppose there is almost as much of them in sheer dry bulk as there is the rest of me". As humans, or indeed as any mammal, bird, or insect, we contain a specific molecular makeup that is driven by vast numbers of these miniscule powerhouses residing in most of our cells (mature red blood cells notwithstanding), quietly replicating, living independent lives and containing their own DNA. Everything we do, from running a marathon to breathing, is driven by these small batteries, and yet there is evidence that these molecular energy sources were originally bacteria, possibly parasitic, incorporated into our cells through symbiosis. Dysfunctions in these organelles can lead to debilitating, and sometimes fatal, diseases of almost all the bodies' major organs. Mitochondrial dysfunction has been implicated in a wide variety of human disorders either as a primary cause or as a secondary consequence. To better understand the role of mitochondrial dysfunction in human disease, a multitude of pharmacologically induced and genetically manipulated animal models have been developed showing to a greater or lesser extent the clinical symptoms observed in patients with known and unknown causes of the disease. This review will focus on diseases of the brain and spinal cord in which mitochondrial dysfunction has been proven or is suspected and on animal models that are currently used to study the etiology, pathogenesis and treatment of these diseases.
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- Faculty of Medical Sciences [93367]
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