Observation on the influence of changing photoperiod on spontaneous wheel-running activity of neonatally pinealectomized rats

Common Genetic Variation Near Melatonin Receptor 1A Gene Linked to Job-Related Exhaustion in Shift Workers

Study Objectives

Tolerance to shift work varies; only some shift workers suffer from disturbed sleep, fatigue, and job-related exhaustion. Our aim was to explore molecular genetic risk factors for intolerance to shift work.

Methods

We assessed intolerance to shift work with job-related exhaustion symptoms in shift workers using the emotional exhaustion subscale of the Maslach Burnout Inventory-General Survey, and carried out a genome-wide association study (GWAS) using Illumina's Human610-Quad BeadChip (n = 176). The most significant findings were further studied in three groups of Finnish shift workers (n = 577). We assessed methylation in blood cells with the Illumina HumanMethylation450K BeadChip, and examined gene expression levels in the publicly available eGWAS Mayo data.

Results

The second strongest signal identified in the GWAS (p = 2.3 × 10E-6) was replicated in two of the replication studies with p < .05 (p = 2.0 × 10E-4 when combining the replication studies) and indicated an association of job-related exhaustion in shift workers with rs12506228, located downstream of the melatonin receptor 1A gene (MTNR1A). The risk allele was also associated with reduced in silico gene expression levels of MTNR1A in brain tissue and suggestively associated with changes in DNA methylation in the 5' regulatory region of MTNR1A.

Conclusions

These findings suggest that a variant near MTNR1A may be associated with job-related exhaustion in shift workers. The risk variant may exert its effect via epigenetic mechanisms, potentially leading to reduced melatonin signaling in the brain. These results could indicate a link between melatonin signaling, a key circadian regulatory mechanism, and tolerance to shift work.

Alterations in Metabolism and Diurnal Rhythms following Bilateral Surgical Removal of the Superior Cervical Ganglia in Rats

Mammalian circadian rhythms are controlled by a master pacemaker located in the suprachiasmatic nuclei (SCN), which is synchronized to the environment by photic and nonphotic stimuli. One of the main functions of the SCN is to regulate peripheral oscillators to set temporal variations in the homeostatic control of physiology and metabolism. In this sense, the SCN coordinate the activity/rest and feeding/fasting rhythms setting the timing of food intake, energy expenditure, thermogenesis, and active and basal metabolism. One of the major time cues to the periphery is the nocturnal melatonin, which is synthesized and secreted by the pineal gland. Under SCN control, arylalkylamine N-acetyltransferase (AA-NAT)-the main enzyme regulating melatonin synthesis in vertebrates-is activated at night by sympathetic innervation that includes the superior cervical ganglia (SCG). Bilateral surgical removal of the superior cervical ganglia (SCGx) is considered a reliable procedure to completely prevent the nocturnal AA-NAT activation, irreversibly suppressing melatonin rhythmicity. In the present work, we studied the effects of SCGx on rat metabolic parameters and diurnal rhythms of feeding and locomotor activity. We found a significant difference between SCGx and sham-operated rats in metabolic variables such as an increased body weight/food intake ratio, increased adipose tissue, and decreased glycemia with a normal glucose tolerance. An analysis of locomotor activity and feeding rhythms showed an increased daytime (lights on) activity (including food consumption) in the SCGx group. These alterations suggest that superior cervical ganglia-related feedback mechanisms play a role in SCN-periphery phase coordination and that SCGx is a valid model without brain-invasive surgery to explore how sympathetic innervation affects daily (24 h) patterns of activity, food consumption and, ultimately, its role in metabolism homeostasis.

Melatonin administration: effects on rodent circadian rhythms

Previous research has demonstrated a lack of effect of pinealectomy upon the generation of rodent circadian activity rhythms and only a subtle effect upon their reentrainment after phase-shifts of the light-dark cycle. In contrast, our pharmacological studies on melatonin indicate that the pineal gland may be more important than hitherto believed. The main outcome of a preliminary pilot experiment on the effect of daily injections of melatonin, arginine vasotocin, melanocyte-stimulating hormone and a beta-blocker on rat free-running activity rhythms in constant darkness was that melatonin appeared to have entrainment properties. This was clearly demonstrated in a second experiment although entrainment did not occur until the onset of the activity rhythm coincided with the daily injection. In contrast, when melatonin was administered ad lib, in the drinking water to six rats housed in constant dim light, there was apparently a lengthening of the free-running period. The effects of 17 days of melatonin injections given at four different times of day to different groups of rats on re-entrainment of activity rhythms after a 5 h phase-advance of darkness were assessed. Results were confounded by the response of some control rats. However, after an 8 h advance of darkness and daily injection at the time of day of the previous dark onset, melatonin-injected rats phase-advanced, whereas vehicle-injected and uninjected control rats phase-delayed. Thus melatonin can alter the direction, but not necessarily the rate, of re-entrainment. The relevance of some of these findings with pharmacological doses of melatonin to the function of endogenous melatonin is discussed.

Effect of stimulation of endogenous melatonin secretion during constant light exposure on 6-sulphatoxymelatonin rhythmicity in rats

When light is presented unexpectedly at night to rats, melatonin production and secretion is acutely inhibited and the time of onset of production on the subsequent night is altered. In a series of experiments, we examined the effects of 6-12 hr light (200 lux) at night on melatonin metabolite excretion (6-sulphatoxymelatonin, aMT.6S). During the light exposure, we administered isoproterenol to stimulate endogenous production of melatonin by the pineal gland to determine if replacement of melatonin would block any phase shifting effects of the light. Exposure to 6 hr of light either during the first or second half of the night suppressed aMT.6S excretion during the light treatment and delayed the onset of melatonin secretion by 3.7 +/- 0.6 and 2.5 +/- 0.6 hr, respectively, compared to a change of 0.5 +/- 0.1 hr in animals maintained in darkness. Twelve hours light exposure (i.e. one night of continuous light) suppressed aMT.6S excretion completely and resulted in a delay in the onset the next night of 2.1 +/- 0.7 hr. When propranolol (10 mg/kg) was administered at 2-hr intervals during darkness, aMT.6S excretion was suppressed throughout the night, but on the subsequent release into constant darkness the onset of excretion was not delayed (0.6 +/- 0.1 hr delay). Administration of isoproterenol (10 mg/kg) to animals in constant light, at the time of expected lights off (CT12), and 5 hr later (CT17) resulted in an increase in melatonin production and aMT.6S excretion that was similar in duration and amount to the control night. The stimulation of endogenous melatonin production failed to block the phase shifting effects of the light exposure and, in fact, appeared to potentiate the delay at least on the first night (4.2 +/- 0.9 hr). The timing of the release into constant darkness following the light treatment had an unexpected effect on melatonin production on the cycle after treatment. Thus, animals exposed to 12 hr light and released into darkness at the normal time of lights off as above had a delay of about 2 hr and excreted 71 +/- 18% of the aMT.6S excreted on a control night. Animals released into darkness at the expected time of lights on failed to excrete more than 20 pmol/hr(i.e. no onset of excretion could be determined) at any time on the first subjective night after light treatment, which was no different from the excretion during the light treatment. On the next subjective night, the onset was delayed as expected and the amount of aMT.6S produced was restored. Treatment with isoproterenol at CT12 and CT17 failed to affect either the amount of aMT.6S excreted on the first subjective night after light treatment or the phase delay on the second night after treatment. The failure to produce melatonin on the first subjective night after 12 hr light exposure and release into darkness at CTO was not due to failure at the level of the pineal gland since injection ofisoproterenol at CT12 and CT17 on the first subjective night after light restored the normal amount of melatonin production. These results suggest that the absence of melatonin during light stimulation at night is not responsible for the phase delay in melatonin production and excretion on subsequent nights. The basis of the failure of the rats to commence melatonin production following 12 hr extended light exposure followed immediately by continuous darkness is not known.

Melatonin and light induce phase shifts of circadian activity rhythms in the C3H/HeN mouse

This study examines the effect of light pulses and administration of the pineal hormone melatonin on the circadian activity rhythm of C3H/HeN mice. Mice were housed in constant dark in cages equipped with running wheels. Phase shifts in the circadian rhythm of wheel-running activity were measured following treatment with a 15-min pulse of light (300 lux) or administration of vehicle (ethanol/saline) or melatonin (90 micrograms, sc). Light treatment induced phase changes in circadian activity rhythms; specifically, delays during early subjective night (circadian time [CT] 12.5 to CT 18.5) and advances during late subjective night (CT 0.5). A single dose of melatonin administered at various CTs had no consistent effect on free-running circadian activity rhythms. By contrast, melatonin administration for 3 consecutive days at the same clock time induced advances in circadian activity rhythms by more than 1 h when the first dose was administered at CT 10 and induced delays in circadian activity rhythms by up to 1 h when the first dose was administered between CT 24 and CT 2. With the caveat that multi- ple melatonin treatments are required to induce phase shifts, the results suggest that the circadian timing system controlling the rhythm of wheel-running activity in the C3H/HeN mouse is responsive to both light and melatonin.

Melatonin receptors in the mammalian suprachiasmatic nucleus

The SCN of the hypothalamus, the site of the circadian pacemaker in mammals, is endowed with melatonin receptors of the ML-1 subtype. Here, we present evidence suggesting that activation of melatonin receptors in the SCN regulates circadian rhythms of behavior in the mouse. In a paradigm simulating a eastbound transmeridian flight, timed administration of melatonin may either accelerate or decrease the rate of reentrainment. Moreover, under constant environmental conditions, exogenous melatonin phase shifts circadian rhythms only during times when the production of the hormone is inhibited. Similarly, light shows periods of circadian sensitivity only at times when light is not present in a natural photoperiod. The maximal phase shifts elicited by melatonin and light coincide with the subjective light-dark (dusk) and subjective dark-light (dawn) transitions. The periods of sensitivity for melatonin, occur at the same circadian times in mouse and in man. Under a short photoperiod the duration of the nocturnal melatonin production may overlap with periods of sensitivity for the hormone, and therefore, melatonin, may be important in synchronizing circadian rhythms to changes in the natural photoperiod. It follows that the identification of periods of circadian sensitivity to melatonin in mammals is important for the development of effective treatments with melatonin and related analogues for sleep disorders characterized by alterations of circadian rhythmicity.

Maternal coordination of the daily rhythm of malate dehydrogenase activity in testes from young rats: effect of maternal sympathetic denervation of the pineal gland and administration of melatonin

Chronic sympathetic denervation of the pineal gland by bilateral removal of the superior cervical ganglia (SCG) was performed on female rats 30 days before impregnation. The offspring, maintained in the dark from birth, had disruption of the malate dehydrogenase circadian rhythm in the testes at 25 days of age. A daily injection of melatonin (1 mg/kg s.c. at 10:00 or 18:00 h) to denervated mothers from the 14th day of pregnancy up to the 10th day postpartum produced one daily phase in the enzyme activity of tests in the offspring. Entrainment of daily enzyme activity also was obtained when the hormone was administered orally to the pups during the postnatal period or when pups were reared by intact (not denervated) foster mothers. The results indicate the involvement of the maternal pineal gland in the maternal transfer of photoperiodic information necessary for the coordination of the circadian system in young rats.

Effect of sympathetic denervation of the pineal gland on maternal co-ordination of the circadian rhythm of alpha-amylase in parotid gland from young rats

Twenty-five-day-old rats maintained in constant darkness since birth and born from mothers kept in the dark since the 14th day of pregnancy showed a circadian rhythm of alpha-amylase content in parotid glands, which may be explained by a mechanism of maternal co-ordination. Rats in the same conditions, except that their mothers had been submitted to bilateral excision of the superior cervical ganglia 30 days before mating, did not show diurnal variations of alpha-amylase activity in the parotid glands. When ganglionectomized mothers were treated with a daily dose of melatonin (1 mg/kg) from the 14th day of gestation up to the 10th day of lactation, their litters showed significant diurnal variations of amylase in the parotid glands, suggesting a role of the maternal pineal gland in the maternal-fetal and/or maternal-neonatal transfer of photoperiodic information.

Splitting of locomotor circadian rhythmicity in hamsters is facilitated by pinealectomy

The role of the pineal gland in the mammalian circadian system has not been well established, in contrast to a fair number of reports indicating pharmacological effects of melatonin in the circadian organization. In order to establish the effects of pinealectomy on the time course of splitting of circadian rhythmicity, the wheel running locomotor activity was continuously recorded in golden hamsters under light-dark conditions or constant light. The analysis of transients from the actograms shows that removal of the pineal gland induces a reduction in the latency and an increase in the duration of transients before the splitting occurs. The power spectral analysis from selected segments of the data shows that concomitant to the development of the splitting there is an increase in the power of ultradian components. In pinealectomized animals the changes in the power spectrum occurs at least 30 days before that in the control animals. These observations suggest that pineal gland could be involved in the coupling mechanism among the different oscillators of the rodent circadian system. Furthermore, since the light intensity used in this study is enough to completely suppress the melatonin synthesis from the pineal, the present results suggest that a signal from the pineal other than melatonin is involved in the process.

The circadian activity rhythms of rats with mid- and parasagittal 'split-SCN' knife cuts and pinealectomy

To explore the multioscillator nature of the neurohumoral circuitry controlling the expression of circadian rhythmicity, rats' wheel running circadian activity rhythms were compared following sagittal knife cuts in the region of the suprachiasmatic nucleus (SSCN), following pinealectomy (PX) and following the combination of SSCN and PX. 25% of animals with knife cuts that passed through one SCN had disturbed running activity under constant illumination; rhythmic disturbances were seen neither in animals with sham knife cuts nor in rats with knife cuts on the midline or lateral to the SCN. Animals with both SSCN and PX were twice as likely to show severe rhythmic disruptions under free-running conditions as rats with SSCN and sham PX. Rats with PX and sham SSCN did not display disrupted activity rhythms. When animals with PX alone or SSCN alone were first observed under free-running conditions and then subjected to a second surgical procedure so that all animals underwent both PX and SSCN, all PX and most SSCN animals demonstrated coherent activity rhythms after the first operation, but 35% showed disruptions in circadian activity patterns only following the second surgery. The activity rhythms of rats with knife cuts placed either on the midline or lateral to the SCN did not deteriorate when combined with PX. Rats with coherent rhythms following knife cuts damaging one SCN had rhythm disruptions after the addition of PX. The effects of pinealectomy may indicate that the pineal gland plays a role in maintaining the coupling relationships in the multioscillator system controlling circadian activity rhythms. The results of this study also suggest that neither the direct commissural connection of the SCNs nor the humoral output of the pineal gland is indispensable for the expression of coherent circadian activity rhythms in the rat.

Circannual serum creatine kinase patterns after ganglionectomy and pinealectomy of the Wistar rat

Previous investigations have shown that an inverse correlation exists between serum thyroxine levels (T4) and serum creatine kinase activity (CK) both in hypothyroid and hyperthyroid states. In the present study, serum T4 levels and total serum CK activity were analysed after thyroidectomy (TX), ganglionectomy (extirpation of the superior cervical sympathetic ganglion) (GX), or pinealectomy (PX) four times a year (March, June, September, and December). Blood samples were taken four times daily (at midlight, middark, and at 1 hour after the onset of the light and dark periods). Animals were kept under an artificial light schedule that simulated natural light-dark periods. The annual main values of serum T4 levels were significantly decreased after the operations, whereas serum CK activities were increased. Our circannual investigations demonstrated an inverse correlation between serum T4 levels and total serum CK activity (under hypothyroid circumstances). In addition, the circannual pattern of the serum CK activity demonstrated maxima under short-day (winter) conditions and minima under long-day (summer) conditions. GX and PX provoke an unimportant shift (a little longer than 2 months) in maxima and minima of the annual rhythm. Circannual curves exhibited differences in the degree of the increase of serum CK activity of GX and PX groups. These results indirectly confirm the assumption that experimental sympathetic denervation or removal of the pineal gland will induce a hypothyroid state over the long term.

Reentrainment of rat circadian activity rhythms: effects of melatonin

Experiments were conducted to determine whether daily melatonin injections could influence reentrainment of circadian locomotor activity rhythms in male Long-Evans rats after phase shifts of the light dark (LD) cycle. When exposed to a 5-h advance of the LD cycle, six out of 15 rats injected daily with melatonin at the new dark onset reentrained by a phase delay of the activity rhythm. The remaining nine melatonin-injected rats and 14 of the 15 control injected rats phase advanced. Daily melatonin injections administered at the old dark onset did not alter direction of reentraining transients but decreased latency to reach steady-state entrainment. In contrast, the effects of melatonin injections given at the end of both the old and new dark periods are difficult to interpret due to the effects of the injection procedure itself at these times. Following an 8-h advance of the LD cycle, all melatonin-injected rats phase advanced while all vehicle and uninjected control rats phase delayed when injections were given at the old dark onset. As has been found in other research areas, the time of day of melatonin administration appears to be a critical factor in its mode of action. It is yet to be established whether these results from the use of pharmacological doses of melatonin are indicative of endogenous melatonin's involvement in the circadian reentrainment mechanism.

Dose-dependent entrainment of rat circadian rhythms by daily injection of melatonin

Previous work in our laboratory has shown that daily injection of large doses of the pineal hormone melatonin entrains the free-running locomotor rhythms of rats held in constant darkness and synchronizes the disrupted patterns of rats maintained in constant bright light. The present experiments determined the dose-response characteristics of entrainment to daily melatonin injections and made preliminary biochemical estimates of blood melatonin levels and half-lives after two critical doses of the hormone. The data indicated that the median effective dose for melatonin as an entraining agent in free-running rats was 5.45 +/- 1.33 micrograms/kg, considerably lower than doses previously employed and lower than doses employed in reproductive and metabolic studies in rats and hamsters. The data further indicated that the response to melatonin was quantal; rats either entrained to melatonin or they did not. No "partial entrainment" was evident, nor were there differences in phase angle, activity, or period among all effective doses. Biochemical estimates of blood melatonin after either 1 mg/kg or 1 microgram/kg of melatonin indicated that all effective doses resulted in supraphysiological levels of blood melatonin, although doses of 1 microgram/kg resulted in blood levels that were within one order of magnitude of normal nighttime values. Together, the data suggest that the rat circadian system is sensitive to the pineal hormone melatonin at or below doses required to effect rodent reproduction. Whether this sensitivity reflects a role for the pineal gland in rat circadian organization, however, still remains to be determined.

Effect of pinealectomy and circadian rhythm on avoidance behavior in the male rat

Male adult albino rats were divided into six groups: two pinealectomized (Px); two sham-operated (Sh) and two serving as controls (C). Half of these groups were studied in daylight and the other half at night. The animals were open-field tested and then conditioned by the avoidance behavior test in the appropriate light period. No differences were observed among the groups when they were conditioned in the dark; however, the Px were conditioned significantly more rapidly than Sh or C in daylight. Intragroup comparisons between night/day conditioning showed them to be similar in Px but more rapid at night in both Sh and C. The Sh group is unique and not comparable to controls.

Phase shift of daily profiles of N-acetyltransferase in the rat pineal gland

Pineal N-acetyltransferase activity (NAT) has a circadian rhythm with peak values in the dark time and low values in the light time. NAT time profiles were measured in rats exposed to LD 14:10, to constant dark, and to acute (less than 48 hr) light-dark treatments. In all experiments, imposition of light suppressed NAT. The phase of the dark time NAT cycle was altered 2 hr or less by the following treatments: 3 hr light in the early subjective night, 3 hr light in the late subjective night, 2 hr or 6 hr light in the early subjective day, 4 hr early lights-on, 1 day of constant dark, or 1 day of constant light. When light was extended 4 hr into the dark time, NAT rose at lights out but fell again as the time of "expected" dawn approached. In contrast, the phase of the NAT cycle was shifted 12 hr (180 degrees) within 72 hr by reversing the phase of the light-dark cycle. NAT did not rise in the first dark period (coincident with the time of the subjective light time). The amplitude of the first shifted cycle was less than four control NAT profiles measured in rats kept in the original (unshifted) light-dark cycle.

Circadian pineal modulation of pituitary effect on murine corticosterone in vitro

An old controversy is resolved as a novel effect: In a rhythmic fashion, aqueous pineal homogenate (APH) enhances, attenuates or leaves unaffected the production of corticosterone by mouse adrenals incubated with pituitary media. All glands stem from the same circadian stage in these (isophasic) studies on 72 female CD2F1 mice, standardized for two weeks in L 0600-1800 and D 1800-0600. Every 4 hours during a 24-hour span, 12 mice were killed. Pineals were removed for the preparation of APH and stored at 4 degrees C. Hypothalami, pituitaries and adrenals were removed, bisected and placed in wells containing 1 ml Krebs-Ringer buffer (K), at 4 degrees C, until incubation. At each circadian stage, bisected adrenals were incubated with 95% O2 and 5% CO2 at 37 +/- 1 degree C for 5 hours, with K only or with the addition of 0.05 IU ACTH 1-17 or APH or with isophasic pituitary or hypothalamic preincubation media with and without APH or muscle. Media were stored at -20 degrees C until corticosterone RIA. A circadian rhythm (p less than 0.05) characterized corticosterone production after stimulation by the pituitary alone or with APH. The overall modulatory effect of APH is an increased circadian amplitude of adrenal corticosterone production, in response to the isophasic pituitary.

Free-running activity rhythms in the rat: entrainment by melatonin

The pineal gland hormone melatonin may play a role in synchronization of rat circadian rhythms. Free-running activity rhythms of the rat were entrained by a daily melatonin injection, with entrainment occurring when the onset of activity coincided with the time of daily injections. When injections were stopped, activity rhythms became free-running again. Thus in pharmacological experiments, the time of day of melatonin administration is crucial.

Pineal effects on metabolism and glucose homeostasis: evidence for lines of humoral mediation of pineal influences on tumor growth

Results from animal experiments support the hypothesis that pineal gland function can influence some aspects of tissue metabolism and glucose homeostasis. Evidence of pineal effects on particular endocrine and sympatheto-adrenal targets contributes to an understanding of indirect routes by which pineal activity can possibly affect the growth and activity of some kinds of tumors, in part through nutrient and metabolic effects in the tissue environment of the tumor cells.

The pineal and psychiatry: a review

The pineal body in man is an active endocrine gland throughout life. Historically the gland has been associated with speculation on the nature of mind and its disorders. Modern research is now demonstrating it to be an endocrine gland capable of affecting the brain and behaviour. The implications for future research into this aspect of pineal function are discussed in the context of a critical review of the current literature.

Negative effects of melatonin on depression

In order to test the efficacy of the pineal neurohumor melatonin on depression, the hormone was administered in varying doses to six moderately to severely depressed patients and two patients with Huntington's chorea in double-blind crossover study. Melatonin exacerbated symptoms of dysphoria in these patients, as well as causing a loss of sleep and weight and a drop in oral temperature. Melatonin increased cerebrospinal fluid 5-hydroxyindoleacetic acid and calcium in three of four patients studied. The authors discuss the implications of this finding.

Pineal function in sparrows: circadian rhythms and body temperature

Deep body temperature of the house sparrow, Passer domesticus, was monitored continuously by radio telemetry. Pinealectomy abolished the normal circadian rhythm of body temperature in constant darkness, and significantly altered the amplitude of body temperature rhythms entrained to light cycles. The body temperature minima of pinealectomized birds never fell as low as those of unoperated birds regardless of the light conditions; the temperature maxima of both normal and pinealectomized birds were higher in light than in darkness. In sparrows the pineal organ is essential to the normal function of the biological clock controlling both activity and body temperature rhythms and may be directly involved in thermoregulation.