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Regulation of mitochondrial respiratory activity in photosynthetic systems
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- By A.L. Moore, University of Sussex, J.N. Siedow, Duke University, A.C. Fricaud, University of Sussex, V. Vojnikov, University of Sussex, A.J. Walters, University of Sussex, D.G. Whitehouse, Polytechnic of East London
- Edited by Alyson K. Tobin, University of Manchester
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- Book:
- Plant Organelles
- Published online:
- 05 December 2011
- Print publication:
- 15 October 1992, pp 189-210
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- Chapter
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Summary
The role of mitochondria in cellular energy metabolism in both photosynthetic and non-photosynthetic tissues has been the subject of much study. In non-photosynthetic tissues most of the cell's demand for ATP is met by respiration and oxidative phosphorylation whereas in photosynthetic tissues photophosphorylation can be a major contributor to cellular ATP requirements. The pathways involved are central to metabolism and interact with many other metabolic systems. An understanding of the mechanisms that control respiration is therefore vital for a fuller comprehension of cellular metabolism and efficiency. Before attempting to answer the question of what controls respiratory activity it is important to define the system in question and its limits since there are many different levels at which control can be said to occur. Such a definition allows discrimination between internal controls of the system and the effect on the system imposed by external causes.
The scope of this chapter is restricted to the system of oxidative phosphorylation and respiration in plant mitochondria. The general properties and characteristics of plant mitochondria are well documented and the reader is therefore referred to these articles (Douce, 1985; Moore & Rich, 1985; Douce & Neuburger, 1989; Moore & Siedow, 1991) for a fuller description of their structural and functional properties. The system is defined as comprising the electron transport chain, the intramitochondrial NAD+ and phosphate pools, the adenine nucleotide translocator, the ATP synthase, the protonmotive force and the proton conductance of the inner membrane.