Feeding rhythm and ornithine decarboxylase activity in hereditary microphthalmic rats

Immunohistochemical detection of tyrosine hydroxylase and concentrations of monoamines in the substantia nigra and hypothalamus of hereditary microphthalmic rats

We compared tyrosine hydroxylase immunoreactivity in the substantia nigra and hypothalamus of hereditary microphthalmic rats with that of normal rats. A considerable number of neuronal cell bodies expressing tyrosine hydroxylase were present in the substantia nigra of the microphthalmic mutant as well as normal rats. Neuronal cells positive for tyrosine hydroxylase in the hypothalamus were fewer than in the substantia nigra in both rats. The concentrations of monoamines (dopamine, noradrenaline, adrenaline, and serotonin) in the substantia nigra and hypothalamus in the microphthalmic mutant were approximately the same as those of normal rats, although the diurnal fluctuation of a few monoamines was observed in normal rats. These results suggest that the metabolic aspects of catecholamine in the substantia nigra and hypothalamus of the microphthalmic mutant rat do not markedly differ from those of normal rats.

Effects of restricted food access on circadian fluctuation of serotonin N-acetyltransferase activities in hereditary microphthalmic rats

The characteristics in diurnal fluctuation of serotonin N-acetyltransferase activity were examined in normal and microphthalmic mutant rats of the Donryu strain under ad lib or restricted feeding conditions. Under a 12:12-h light:dark (12-h LD) cycle with free access to food, normal-sighted rats exhibited typical nocturnal increases in the activity of pineal serotonin N-acetyltransferase, being more than 50-fold higher in the dark period than that in the light period, but hereditary blind rats showed nonperiodic change in the pineal enzyme activity in the average, suggesting that the rhythms in individuals have become free-running, asynchronous. When the subjective night or subjective day of the mutants was discerned by active or inactive in the locomotor activity, the pineal enzyme activities in the mutants increased at the subjective night but depressed at the subjective daytime. When food access was restricted only for 6 h in the light period of the LD cycle, normal rats still showed the nocturnal increases in the pineal enzyme activity, but hereditary blind rats manifested a blunt peak in the activity of the pineal enzyme at eating time in the light period. The results suggest that microphthalmic mutant rats maintain the ability to shift and to synchronize their circadian phases induced by restricted access to food, even if they completely lack their optic nerve and visual input to the circadian clock.

Effects of restricted food access on diurnal fluctuation of behaviors and biochemical functions in hereditary microphthalmic rats

The characteristics in circadian rhythms of spontaneous locomotor activity, and some metabolic properties were examined in microphthalmic mutant rats of the Donryu strain under ad lib or restricted food access conditions. The growth of microphthalmic rats was retarded compared to that of normal-sighted rats from the same strain. Under a 12:12-h light:dark (LD) cycle with free access to food, normal-sighted rats showed basically nocturnal patterns of the locomotor activity rhythms, but most of microphthalmic rats manifested free-running rhythms and a few of them showed arrhythmic. When food access was restricted only for 6 h in the light period of the LD cycle, the normal and hereditary blind rats generated gradually new patterns of the locomotor activities in which the animals showed to be more active in the light period. Plasma glucose concentration in normal rats showed a peak after food consumption, but microphthalmic mutants exhibited no periodic changes of the glucose levels. Responses of the biochemical parameters of protein and mineral metabolism to restricted food access in the mutants did not differ from those in normal rats. These results suggest that microphthalmic mutant rats show the free-running circadian rhythm of locomotor activity due to a complete lack of their optic nerve and visual input to the circadian clock, but the mutants maintained the ability to shift their circadian phase induced by restricted food access similar to that in control rats, and also that the mutants have almost normal properties of biochemical and physiological functions except for glucose metabolism.