Abstract
Plants are sessile organisms that often receive excessive amounts of light energy. This excess energy can be exported from the chloroplasts and dissipated by the mitochondrial respiratory chain. The inner membrane of plant mitochondria possesses unique non-phosphorylating pathways, involving alternative oxidase and type II NAD(P)H dehydrogenases. There are accumulating amounts of evidence showing that these energy-wasteful pathways are up-regulated under excess light conditions, suggesting that they play key roles in efficient photosynthesis. Based on recent advances in our understanding about the metabolic interaction between chloroplasts and mitochondria, we discuss the importance of the respiratory chain for stabilizing the photosynthetic system.
MeSH terms
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Adenosine Triphosphate / metabolism
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Chloroplast Proteins
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Chloroplasts / physiology*
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Chloroplasts / radiation effects
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Citric Acid Cycle / physiology
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Cytosol / metabolism
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Electron Transport / physiology*
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Electron Transport / radiation effects
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Electron Transport Complex II / metabolism
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Gene Expression Regulation, Plant / physiology
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Ion Channels / physiology
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Light
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Malates / metabolism
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Membrane Transport Proteins / metabolism
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Metabolic Networks and Pathways
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Mitochondria / metabolism*
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Mitochondrial Proteins / physiology
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NADP / metabolism*
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Oxaloacetic Acid / metabolism
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Oxidative Stress / physiology
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Oxidoreductases / metabolism
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Oxygen / metabolism*
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Photosynthesis / physiology*
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Plant Leaves / physiology*
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Plant Leaves / radiation effects*
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Plant Proteins / metabolism
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Ribulose-Bisphosphate Carboxylase / metabolism
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Sucrose / metabolism
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Uncoupling Protein 1
Substances
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Chloroplast Proteins
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Ion Channels
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Malates
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Membrane Transport Proteins
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Mitochondrial Proteins
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Plant Proteins
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Uncoupling Protein 1
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Oxaloacetic Acid
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NADP
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Sucrose
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malic acid
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Adenosine Triphosphate
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Oxidoreductases
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alternative oxidase
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Electron Transport Complex II
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Ribulose-Bisphosphate Carboxylase
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Oxygen