Circadian rhythms of photorefractory siberian hamsters remain responsive to melatonin

Short day lengths increase the duration of nocturnal melatonin (Mel) secretion, which induces the winter phenotype in Siberian hamsters. After several months of continued exposure to short days, hamsters spontaneously revert to the spring-summer phenotype. This transition has been attributed to the development of refractoriness of Mel-binding tissues, including the suprachiasmatic nucleus (SCN), to long-duration Mel signals. The SCN of Siberian hamsters is required for the seasonal response to winter-like Mel signals, and becomes refractory to previously effective long-duration Mel signals restricted to this area. Acute Mel treatment phase shifts circadian locomotor rhythms of photosensitive Siberian hamsters, presumably by affecting circadian oscillators in the SCN. We tested whether seasonal refractoriness of the SCN to long-duration Mel signals also renders the circadian system of Siberian hamsters unresponsive to Mel. Males manifesting free-running circadian rhythms in constant dim red light were injected with Mel or vehicle for 5 days on a 23.5-h T-cycle beginning at circadian time 10. Mel injections caused significantly larger phase advances in activity onset than did the saline vehicle, but the magnitude of phase shifts to Mel did not differ between photorefractory and photosensitive hamsters. Similarly, when entrained to a 16-h light/8-h dark photocycle, photorefractory and photosensitive hamsters did not differ in their response to Mel injected 4 h before the onset of the dark phase. Activity onset in Mel-injected hamsters was masked by light but was revealed to be significantly earlier than in vehicle-injected hamsters upon transfer to constant dim red light. The acute effects of melatonin on circadian behavioral rhythms are preserved in photorefractory hamsters.     

Circadian rhythms of melatonin in European starlings exposed to different lighting conditions: relationship with locomotor and feeding rhythms

In passerine birds, the periodic secretion of melatonin by the pineal organ represents an important component of the pacemaker that controls overt circadian functions. The daily phase of low melatonin secretion generally coincides with the phase of intense activity, but the precise relationship between the melatonin and the behavioral rhythms has not been studied. Therefore, we investigated in European starlings (Sturnus vulgaris) (1) the temporal relationship between the circadian plasma melatonin rhythm and the rhythms in locomotor activity and feeding; (2) the persistence of the melatonin rhythm in constant conditions; and (3) the effects of light intensity on synchronized and free-running melatonin and behavioral rhythms. There was a marked rhythm in plasma melatonin with high levels at night and/or the inactive phase of the behavioral cycles in almost all birds. Like the behavioral rhythms, the melatonin rhythm persisted for at least 50 days in constant dim light. In the synchronized state, higher daytime light intensity resulted in more tightly synchronized rhythms and a delayed melatonin peak. While all three rhythms usually assumed a rather constant phase relationship to each other, in one bird the two behavioral rhythms dissociated from each other. In this case, the melatonin rhythm retained the appropriate phase relationship with the feeding rhythm. Accepted: 10 December 1999     

Effects of ovariectomy on clock-timed daily gonadotropin rhythms in prepubertal golden hamsters

Daily rhythms of luteinizing hormone (LH) and follicle-stimulating hormone (FSH) are measurable in the serum of prepubertal female golden hamsters by 17 days after birth. These rhythms, which are characterized by peak levels at 1700 h, persist until they are replaced by a 4-day rhythm as ovulatory cycles begin, approximately 3 wk later. We have tested the proposition that the ovaries are required for the onset and maintenance of clock-timed gonadotropin release by removing the ovaries and measuring the levels of LH and FSH in prepubertal hamsters. Ovariectomy was performed both before and after the onset of the rhythm and the effect of removal was determined by subsequent collection of blood samples during the mid- to late-prepubertal period. Ovariectomy on 7, 10 or 13 days after birth results in tonic levels of LH and FSH in blood samples collected at 1400, 1700 and 2000 h on Days 17 through 29. Sham-operated or intact controls had significantly elevated levels of these hormones at 1700 h. Ovariectomy on Day 21 and killing on Day 25 at the same times of day abolished the rhythm of serum LH measured in sham-ovariectomized controls. Ovariectomy on Day 21 and killing on Days 26, 28 or 30 at hourly intervals resulted in variable but nonrhythmic patterns of circulating LH. Thus, ovariectomy before the initiation of clock-timed gonadotropin release prevented its initiation; ovariectomy after its initiation abolished the rhythm. These results show that the ovary provides an essential "message" to the brain-pituitary axis for the initiation and maintenance of clock-timed gonadotropin release in prepubertal females.     

Melatonin-induced suppression of gonadotropin titers in male golden hamsters: Effect on gonadal feedback mechanisms

Daily subcutaneous injections of melatonin cause testicular regression and a decline in circulating gonadotropin levels in male hamsters maintained on long photoperiods. We examine here if a reduction in gonadotropin levels also occurs in castrates administered melatonin and if melatonin-regressed hamsters respond to castration with an increased release of pituitary gonadotropins — a typical “castration response.” Groups of intact and castrated male hamsters maintained on a photoperiod of LD 14:10 received subcutaneous injections of 15 ug melatonin/day. Controls received vehicle only. After 7 weeks of injections the intact males were castrated. All animals were sacrificed a few days later and serum was assayed for gonadotropin titers. Melatonin injections caused a marked decline in serum gonadotropins in castrates and in intact males also caused testicular regression. In the latter, no “castration response” was observed upon removal of the testes. Thus, daily injections of melatonin depress serum gonadotropins in castrate and intact males and block the castration-associated rise in circulating gonadotropins in the latter.     

Circadian activity rhythms in hamsters and rats treated with imipramine in the drinking water

Circadian rhythms of locomotor activity were recorded in 15 male golden hamsters and in 15 rats. The animals were exposed alternatingly to a variety of conditions with either light-dark cycles (LD) or continuous illumination (LL). The hamsters were split into two groups: 7 animals received plain water, and 8 animals water together with imipramine hydrochloride. The rats received plain water or water with imipramine in alternation. In all animals the addition of imipramine resulted in a reduction of water uptake and in a concomitant reduction of the daily amount of activity. Otherwise, no significant effects of imipramine could be observed: in LD, the phase-angle differences between rhythm and zeitgeber were not changed by imipramine, and, in the hamsters, the upper limits of entrainability and the rates of re-entrainment were identical in the two groups of animals; in LL, the period of the free-running rhythm was slightly lengthened by imipramine in the hamsters, but remained unchanged in the rats.     

Circadian rhythms: from gene expression to behavior

Circadian rhythms regulate the functions of living systems at virtually every level of organization, from molecule to organism. In the past year, our understanding of the cellular and molecular processes involved in the generation and regulation of circadian rhythms has advanced considerably. New in vitro model systems for studying circadian oscillators have been developed, a potential regulatory role for cellular immediate-early genes in circadian behavior has been discovered, critical periods for macromolecular synthesis for progression of the circadian clock through its cycle have been defined, and studies of the Drosophila period gene have offered new insight into the clock mechanism. These findings are of particular interest because independent approaches using vertebrates, mollusks and Drosophila all point to a common theme that involves the expression of 'clock proteins' as the basis of the timing mechanism.     

Circadian rhythms in disaccharidases of rat small intestine and its relation to food intake.

The activities of maltase and sucrase of the small intestine were low at night and high in the daytime in rats which had been fed from 09.00 h to 15.00 h for 2 weeks. A remarkable rise of enzyme activities was observed at 08.00 h, 1 h before the start of feeding. The rhythmic changes in disaccharidase activities continued for at least 2 days after starvation, but completely disappeared after 5 days of starvation. It was suggested that the disaccharidase rhythms are not a direct consequence of food intake, but that anticipation of food intake acts as a trigger for initiation of the disaccharidase rhythms.     

Circadian rhythms in cockroaches

Summary The driving oscillator, which mediates circadian locomotor rhythms in cockroaches, appears to reside in the protocerebrum of the brain. The evidence indicates that the optic lobes are crucial elements in this circadian system, and that control of rhythmicity is mediated through electrical, rather than hormonal, channels. Lesions were placed at various sites within the optic lobes in order to localize the areas controlling rhythmicity. It appears that the two innermost synaptic areas (the lobula and the medulla) constitute the crucial optic lobe elements. The outer synaptic area of the optic lobe (the lamina) is not necessary for the expression of rhythmicity, but does function as a coupling through which light cycles, transduced by the compound eyes, entrain the circadian clock.I would like to thank both Dr. Sue Binkley for her helpful comments in the preparation of this report, and Mr. Eli Levine for his assistance in photography. Support for this research was provided by a grant from the National Science Foundation (NS GB-30497).     

Circadian complexes: Circadian rhythms under common gene control

Summary Circadian rhythms for food and water consumption were measured in five inbred strains of mice under a photoperiod of 16 h light and 8 h dark (16:8 LD), and under constant light (LL).Significant strain differences were observed which indicate that a common gene difference, or set of differences inMus musculus influences both the phase angle () associating the rhythms with the light-dark cycle, and the periods (_LL) of circadian rhythms for food and water consumption. The biological clock mechanism influenced by this genetic variance is common to both food and water circadian rhythms, and differs among the five inbred strains. A positive genetic correlation was observed between the phase angle () and the period (_LL) of each rhythm. This observation can be understood in terms of a functional relationship between phase and period proposed by Pittendrigh and Daan (1976b) for the entrainment of a circadian oscillator by a light-dark cycle in nocturnal rodents.These results suggest that circadian rhythms for food and water consumption in mice are regulated by a common physiological mechanism, and would respond to natural selection as a single circadian complex under common gene control.     

Circadian rhythms in serum bone markers and their relation to the effect of etidronate in rats

Circadian rhythmicity is an essential feature of bone metabolism. The present study was undertaken to (Aoshima et al., [1998]) determine the changes in bone resorption and formation in rats over 24h, (Black et al., [1999]) evaluate the effect of the consecutive administration of etidronate on circadian rhythms of serum bone markers, and (Blumsohn et al., [1994]) determine whether the effect of etidronate on bone metabolism is circadian time-dependent. One hundred twenty male Wistar rats, which had been adapted to a 12/12h light/dark cycle, were injected subcutaneously once daily with either 0.5 mgP/kg etidronate or 0.9% NaCl (control group) at 0090, 1300, 1700, 2100, 0100, or 0500h for 10d. Serum was collected and tibiae were dissected 24h after the last injection. Serum pyridinoline (Pyd), tartrate-resistant acid phosphatase (TRAP), osteocalcin (OC), alkaline phosphatase (ALP), calcium (Ca), phosphorus (Pi), calcitonin (CT), and parathyroid hormone (PTH) were determined. Bone mineral density (BMD) in the proximal tibia, and the rate of formation of longitudinal trabecular bone over the past 48h were also determined using a chronological labeling method with NTA-Pb. The results showed characteristic circadian rhythms in serum bone markers in rats, with peaks in both bone resorption and bone formation during the animals' rest span. The administration of etidronate at the different times of the day decreased the level of bone-resorption markers (Pyd and TRAP) without affecting the circadian patterns of markers of bone formation (OC and ALP). However, the magnitude of the decrease due to etidronate was not uniform throughout the day, and was greatest during the daytime. Etidronate increased the BMD in the tibial metaphysis in all of the time-treatment groups, but the magnitude of the increase did not vary with the time of etidronate administration. The present data provide a physiological basis for future studies on bone metabolism and may be important in the design of future experiments and in the interpretation of experimental data.