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AJP - Regulatory, Integrative and Comparative Physiology, Vol 266, Issue 1 50-R58, Copyright © 1994 by American Physiological Society
ARTICLES |
M. Zatz, G. D. Lange and M. D. Rollag
Section on Biochemical Pharmacology, National Institute of Mental Health, National Institutes of Health, Bethesda 20892.
Chick pineal cells in static culture display a persistent, photosensitive circadian rhythm of melatonin production and release. We previously described the effects of light, the major physiological regulator of circadian rhythms, on the amplitude, period, and phase of the melatonin rhythm. Here we describe the effects of temperature, another physiological regulator of circadian rhythms, on the amplitude, period, and phase of this rhythm. Maintaining cells at 40.0-43.3 degrees C (104-110 degrees F) instead of 36.7 degrees C (98 degrees F) doubled the amplitude of the melatonin rhythm. In contrast, amplitude was reduced by about half at 33.3 degrees C (92 degrees F), and at 46.7 degrees C (116 degrees F) melatonin production was stopped within a few hours. Although temperatures of 40.0-43.3 degrees C raised melatonin output (unlike light, which suppresses it), they lengthened the period of the rhythm (as does constant light). Exposure of cells to 8-h pulses of these temperatures (40.0-43.3 degrees C) induced both phase delays and phase advances of the rhythm in subsequent cycles, with a phase dependence similar to that for the phase shifts induced by light pulses. Pulses of 40.0-43.3 degrees C were, however, weaker in their phase-shifting effects than light pulses. Pulses at still higher temperatures (46.7 degrees C) markedly inhibited melatonin output and delayed or disrupted the rhythm. The relationships (physiological and mechanistic) between the effects of temperature and light on the melatonin rhythm remain to be determined.
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