Abstract
THE bleaching of as little as one molecule of rhodopsin can trigger hyperpolarisation of the vertebrate visual receptor cell1. A light modulated Ca2+ flux may function in the receptor cell outer segments (OS) as an intracellular messenger amplifying and transducing the photochemical signal from its disk location to the external plasma membrane2,3. In support of this hypothesis, Ca2+ has been shown to be concentrated in dark adapted disks4 and to be released on bleaching5–7. This suggests the presence of a Ca2+-dependent ATPase, an enzyme often associated with cellular Ca2+ pumps. The report that either the bleaching of a few per cent of the rhodopsin molecules within a frog rod suspension or the intra-OS elevation of Ca2+ to 10−7 M or greater, by means of ionophore A23187, can induce a rapid and very large decrease in ATP content8 provides indirect evidence for the presence of a Ca2+-activated ATPase. Interpretation of this finding is difficult, however, due to other known light-activated, ATP-dependent OS functions9. We present here direct evidence that purified bovine OS exhibit significant Ca2+-dependent ATPase activity, which seems to be independent of contributions from subcellular contamination.
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SACK, R., HARRIS, C. Ca2+-dependent ATPase activity of bovine receptor cell outer segment. Nature 265, 465–466 (1977). https://doi.org/10.1038/265465a0
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DOI: https://doi.org/10.1038/265465a0
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