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¹ Division of Biomedical Sciences, School of Biology, Bute Building, University of St Andrews, St Andrews, Fife KY16 9TS, UK

All cells respond to metabolic stress. However, a variety of specialized cells, commonly referred to as O₂-sensing cells, are acutely sensitive to relatively small changes in P_O2. Within a variety of organisms such O₂-sensing cells have evolved as vital homeostatic mechanisms that monitor O₂ supply and alter respiratory and circulatory function, as well as the capacity of the blood to transport O₂. Thereby, arterial P_O2 may be maintained within physiological limits. In mammals, for example, two key tissues that contribute to this process are the pulmonary arteries and the carotid bodies. Constriction of pulmonary arteries by hypoxia optimizes ventilation–perfusion matching in the lung, whilst carotid body excitation by hypoxia initiates corrective changes in breathing patterns via increased sensory afferent discharge to the brain stem. Despite extensive investigation, the precise mechanism(s) by which hypoxia mediates these responses has remained elusive. It is clear, however, that hypoxia inhibits mitochondrial function in O₂-sensing cells over a range of P_O2 that has no such effect on other cell types. This raised the possibility that AMP-activated protein kinase might function to couple mitochondrial oxidative phosphorylation to Ca²⁺ signalling mechanisms in O₂-sensing cells and thereby underpin pulmonary artery constriction and carotid body excitation by hypoxia. Our recent investigations have provided significant evidence in support of this view.

(Received 24 February 2006; accepted after revision 9 May 2006; first published online 11 May 2006)
Corresponding author A. M. Evans: Division of Biomedical Sciences, School of Biology, Bute Building, University of St Andrews, St Andrews, Fife KY16 9TS, UK. Email: ame3{at}st-andrews.ac.uk

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