Spatial and Temporal Aspects of Cell Signalling [and Discussion]

As new techniques are developed to measure intracellular messengers it becomes increasingly apparent that there is a remarkable spatial and temporal organization of cell signalling. Cells possess a small discrete hormone-sensitive pool of inositol lipid. In some cells such as Xenopus oocytes and Lim...

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Published in:Philosophical transactions of the Royal Society of London. Series B, Biological sciences Biological sciences, 1988-07, Vol.320 (1199), p.325-343
Main Authors: Berridge, M. J., Cobbold, P. H., Cuthbertson, K. S. R., Downes, C. P., Hanley, M. R.
Format: Article
Language:English
Subjects:
Agonists
Animals
Biological and medical sciences
Calcium
Calcium - physiology
Cell Physiological Phenomena
Cell physiology
Epithelial cells
Fundamental and applied biological sciences. Psychology
Hepatocytes
Hormonal regulation
Humans
Inositol Phosphates - physiology
Inositols
Kinetics
Lipids
Molecular and cellular biology
Neurons
Oocytes
Receptors
Second messengers
Sugar Phosphates - physiology
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Summary:As new techniques are developed to measure intracellular messengers it becomes increasingly apparent that there is a remarkable spatial and temporal organization of cell signalling. Cells possess a small discrete hormone-sensitive pool of inositol lipid. In some cells such as Xenopus oocytes and Limulus photoreceptors this phosphoinositide signalling system is highly concentrated in one region of the cell, so establishing localized calcium gradients. Another example is the hydrolysis of inositol lipids in eggs at the point of sperm entry resulting in a localized increase in Ins(1,4,5)P$_3$ and calcium which spreads like a wave throughout the egg. In hamster eggs this burst of calcium at fertilization recurs at 1-3 min intervals for over 100 min, a particularly dramatic example of spontaneous activity. Spontaneous oscillations in intracellular calcium exist in many different cell types and are often induced by agonists that hydrolyse inositol lipids. We have made a distinction between oscillations that are approximately sinusoidal and occur at a higher frequency where free calcium is probably continuously involved in the oscillatory cycle and those where calcium falls to resting levels for many seconds between transients. In the former case, the oscillations are thought to be induced through a cytoplasmic oscillator based on the phenomenon of calcium-induced calcium release. Such oscillations can be induced in Xenopus oocytes after injection with Ins(1,4,5)P$_3$. A receptor-controlled oscillator based on the periodic formation of Ins(1,4,5)P$_3$ is probably responsible for the generation of the widely spaced calcium transients. The function of such calcium oscillations is currently unknown. They may be a reflection of the feedback interactions that operate to control intracellular calcium. Another possibility emerged from observations that in some cells the frequency of calcium oscillations varied with agonist concentration, suggesting that cells might employ these oscillations as a way of encoding information. One advantage of using such a frequency-dependent mechanism may lie in an increase in fidelity, especially at low agonist concentrations. Whatever these functions might be, it is clear that uncovering the mechanisms responsible for such oscillatory activity will greatly enhance our understanding of the relation between the phosphoinositides and calcium signalling.
ISSN:0962-8436
0080-4622
1471-2970
2054-0280
DOI:10.1098/rstb.1988.0080