Identification, expression, and physiological functions of Siberian hamster gonadotropin-inhibitory hormone

Gonadotropin-inhibitory hormone (GnIH) is a hypothalamic neuropeptide that inhibits gonadotropin secretion in birds and mammals. To further understand its physiological roles in mammalian reproduction, we identified its precursor cDNA and endogenous mature peptides in the Siberian hamster brain. The Siberian hamster GnIH precursor cDNA encoded two RFamide-related peptide (RFRP) sequences. SPAPANKVPHSAANLPLRF-NH(2) (Siberian hamster RFRP-1) and TLSRVPSLPQRF-NH(2) (Siberian hamster RFRP-3) were confirmed as mature endogenous peptides by mass spectrometry from brain samples purified by immunoaffinity chromatography. GnIH mRNA expression was higher in long days (LD) compared with short days (SD). GnIH mRNA was also highly expressed in SD plus pinealectomized animals, whereas expression was suppressed by melatonin, a nocturnal pineal hormone, administration. GnIH-immunoreactive (-ir) neurons were localized to the dorsomedial region of the hypothalamus, and GnIH-ir fibers projected to hypothalamic and limbic structures. The density of GnIH-ir perikarya and fibers were higher in LD and SD plus pinealectomized hamsters than in LD plus melatonin or SD animals. The percentage of GnRH neurons receiving close appositions from GnIH-ir fiber terminals was also higher in LD than SD, and GnIH receptor was expressed in GnRH-ir neurons. Finally, central administration of hamster RFRP-1 or RFRP-3 inhibited LH release 5 and 30 min after administration in LD. In sharp contrast, both peptides stimulated LH release 30 min after administration in SD. These results suggest that GnIH peptides fine tune LH levels via its receptor expressed in GnRH-ir neurons in an opposing fashion across the seasons in Siberian hamsters.     

Pulsatile luteinizing hormone responses to intermittent N-methyl-D,L-aspartate administration in hamsters exposed to long- and short-day photoperiods

Hamsters exposed to short-day photoperiods (6-h light, 18-h darkness) develop a reversible inhibition of the reproductive axis which includes decreased LH pulse frequency, decreased FSH and testosterone levels, testicular regression, and presumably, decreased luteinizing hormone-releasing hormone (LHRH) release. The decrease in LHRH release could reflect a decrease in the ability of LHRH neurons to release the decapeptide in response to intermittent neuronal excitation. To analyze this possibility, the LHRH secretagogue, N-methyl-D-aspartate (NMA) was used to estimate relative releasability of endogenous LHRH pulses in hamsters exposed to long- and short-day photoperiods. Long-day (LD) or short-day (SD) hamsters were fitted with indwelling atrial catheters 2 days before experimentation. During 5-h sampling sessions (1300-1800 h), blood was withdrawn at 10-min intervals. In initial experiments, a NMA dose-response analysis revealed that 10 and 20 mg/kg NMA but not 2.5 and 5 mg/kg NMA, produced significant, dose-related LH responses in LD hamsters. Treatments with LHRH antagonist 4 h prior to NMA treatment completely blocked LH responses. The 10 mg/kg NMA dose was then used to directly compare LHRH responsiveness in LD and SD hamsters. NMA injections were administered to groups of LD and SD hamsters after hours 1, 2, 3, and 4 of sampling. In LD hamsters, LH responses to the first NMA pulse (2.65 +/- 0.09) were followed by diminishing responses to the second, third, and fourth NMA pulses (1.22 +/- 0.50, 1.22 +/- 0.43, and 1.15 +/- 0.42). By contrast, initial LH responses in SD hamsters (1.61 +/- 0.31) were followed by even more robust LH responses to the second, third, and fourth NMA challenges (2.89 +/- 0.34, 3.08 +/- 0.59, 2.65 +/- 0.32). Although LH responses to the first NMA pulse were slightly less in SD vs. LD animals, responses to all subsequent injections were actually greater in SD hamsters vs. their LD counterparts. Injections of 20 ng/kg LHRH in SD hamsters produced LH responses similar to those evoked by NMA. The same LHRH dose also produced continued, robust LH responses in LD hamsters, indicating that decrements in response to NMA were not due to diminished pituitary responsiveness. These results suggest that 1) the stimulatory actions of NMA are mediated by LHRH, 2) exposure to short days does not decrease the responsiveness of LHRH neurons to NMA, and 3) successive NMA challenges produce diminishing LH responses in LD hamsters, but not in SD hamsters.(ABSTRACT TRUNCATED AT 400 WORDS)     

The effects of short photoperiod, pinealectomy, and melatonin treatment on oxytocin synthesis and release in the male syrian hamster

The pineal gland has been shown to affect plasma oxytocin (OT) levels, but the mechanism of this action is not apparent. In the present study, the ability of the photoperiod to affect plasma OT levels, neurointermediate lobe (NIL) OT content, and hypothalamic OT mRNA levels was studied in male Syrian hamsters. In addition, the ability of pinealectomy to prevent and melatonin (MEL) to mimic the short photoperiod-induced changes were also determined. Exposure to short days (SD) led to the expected decrease in testes weight and plasma PRL levels, but plasma OT levels were unchanged. However, NIL OT content was increased in the SD-exposed animals. Hypothalamic OT mRNA levels were not significantly altered by SD exposure. Pinealectomy blocked the effects of SD on testes weight, whereas afternoon MEL injections mimicked the effects of SD. In long day (LD)-exposed hamsters, pinealectomy induced a decrease in NIL OT content without altering hypothalamic OT mRNA levels. In SD-exposed animals, NIL OT content was not affected by pinealectomy. Melatonin injections had no significant effect on NIL OT content or hypothalamic OT mRNA levels. The data from the present study suggest that exposure of male Syrian hamsters to short photoperiods influences some aspects of OT synthesis and/or transport to produce its increased accumulation in the NIL, but does not affect OT release. These changes are apparently not the result of SD-induced changes in MEL secretion, but conceivably could be related to the previously documented effects of SD on hypothalamic catecholamine turnover.     

Simulation of peak pineal melatonin release restores sensitivity to evening melatonin injections in pinealectomized hamsters

In intact hamsters held on LD 14:10, pineal melatonin production and release peaks late in the evening. If these animals receive a daily injection of melatonin approximately 8 h before the endogenous peak (at the time of lights out), they respond with testicular regression. Pinealectomized hamsters receiving only this evening injection do not respond. The hypothesis tested here is very simple: replacement of the pineal melatonin rhythm in pinealectomized hamsters with a daily melatonin injection at the time of peak melatonin release in intact hamsters should reestablish sensitivity to evening (lights out) injections of melatonin. Conversely, melatonin replacement at times other than this should be ineffective. Pinealectomized hamsters maintained on LD 14:10 (lights 0600 - 2000 h) were injected with melatonin (15 microgram) at the time of the endogenous melatonin peak (2 h prior to lights on) and in the evening (0.5 h prior to lights out). This injection paradigm produced a rapid testicular regression that appears to be dependent on the timing of melatonin injections with respect to the animal's circadian system. Two daily injections given with the same frequency (8.5 h apart) but during a different time of the day were not effective. The results suggest that rhythmic sensitivity to melatonin is not affected by removal of the pineal, and that this gland serves as the source of endogenous melatonin, which must be present at the proper time for exogenous injections of melatonin to produce testicular regression.     

Examination of in vitro melatonin secretion from superfused trout (Salmo gairdneri) pineal organs maintained under diel illumination or continuous darkness

Melatonin secretion was measured from rainbow trout (Salmo gairdneri) pineal organs maintained individually under flow-through whole organ culture (superfusion) conditions. Radioimmunoassay of perfusate fractions collected during controlled photic conditions demonstrated that melatonin secretion in vitro remained basal during the photophase and underwent increases in titer during the scotophase. While amounts of melatonin (mel) secreted were characteristic of individual pineal organs, photophase values ranged between 0.25 and 0.75 ng mel/ml and scotophase values ranged from 6 to 10 ng mel/ml of perfusate. Diel melatonin secretion profiles reflected the illumination regimen, with light associated with low melatonin titer in the perfusate and darkness associated with high titer. Light pulses during a normal scotophase resulted in a depression in melatonin secretion regardless of whether it was administered early or late in the dark period. Pulses of darkness given early or late in a normal photophase resulted in increased melatonin secretion. Superfused trout pineal organs did not display endogenous rhythmicity in melatonin secretion when subjected to prolonged exposure to continuous darkness (DD), whether first exposed to entraining light/dark (LD) cycles prior to DD or exposed to DD at the initiation of superfusion. In both studies, elevated melatonin secretion gradually declined over time. But exposure to a 4:4LD cycle after DD resulted in decreased (with light) and increased (with darkness) melatonin secretion. These results demonstrate that the trout pineal organ can be maintained for extended periods of time in superfusion culture, that the trout pineal organ is very responsive to light or dark for regulating melatonin synthesis, and that an endogenous rhythm in melatonin synthesis when organs were maintained in DD was not detectable.     

Lesions to the anterior hypothalamus prevent the melatonin-induced lengthening of delayed implantation

The anterior hypothalamic area (AHA) has been postulated as a site of action for melatonin. We tested the hypothesis that lesions to the AHA (AHAx) would counteract the inhibitory effect of exogenous melatonin on blastocyst implantation in the spotted skunk by removing a possible site of action. Forty-seven females were treated as follows during delayed implantation. In Exp 1, five received empty Silastic capsules, five received Silastic capsules containing melatonin, six received sham AHAx plus empty capsules, none received AHAx plus empty capsules, and eight received AHAx plus capsules containing melatonin. In Exp 2, four skunks each received two empty capsules, five skunks each received two capsules containing melatonin, and five skunks received AHAx plus capsules containing melatonin. All capsules were inserted sc in the interscapular region 14-35 days after surgery in Exp 1 and 2 weeks before surgery in Exp 2. Surgery was performed between January 22 and February 12, 1988, in Exp 1 and on March 2-3, 1989, in Exp 2. The skunks were subjected to a natural photoperiod, and the duration of preimplantation was measured. In Exp 1, AHAx plus empty capsules significantly (P less than 0.05) shortened the duration of preimplantation (163 +/- 14.7 days) compared to that in sham AHAx or intact controls (193 +/- 26.1 and 188 +/- 10.6 days, respectively). Melatonin significantly (P less than 0.05) prolonged the duration of preimplantation (289 +/- 2.9 days) in intact skunks, but failed to do so in skunks with AHAx, as the preimplantation period was significantly shortened (159 +/- 6.1 days). In Exp 2, AHAx reversed the inhibitory effect of melatonin on the duration of preimplantation (191 +/- 21.5 days), as intact melatonin-treated skunks had a significantly longer preimplantation period (260 +/- 2.5 days) than skunks receiving empty capsules (191 +/- 16.4 days). The inhibitory effect of melatonin was reversible in all intact skunks, as blastocysts implanted 23 days, on the average, after cessation of treatment with melatonin. These data are consistent with the hypothesis that a portion of the AHA and/or adjacent regions play an essential role in timing blastocyst implantation in the spotted skunk. The lesions may have given this result by ablating a neural pathway controlling PRL secretion and may or may not have involved a site of action for melatonin.     

Afternoon injections of melatonin in the Djungarian hamster Phodopus sungorus: Long lasting sex-specific effects and influence of acute treatment on the endogenous pineal melatonin rhythm

Abstract: The effects of exogenous melatonin on gonadal function and on the endogenous melatonin profiles of male and female Djungarian hamsters were investigated. Daily afternoon subcutaneous injections of melatonin (50 μ.g) in hamsters kept in long photoperiods (LD 16: 8) led to gonadal inhibition in all the treated females (n=13) but in only 2 of 13 males within the treatment period of 8 weeks (uteri: 244±11 mg in controls vs. 79±4 mg in treated hamsters, P <0.001; ovaries: 13.6±0.6 mg in controls vs. 7.9±0.7 mg in treated hamsters, P <0.001; testes: 1,021±54 mg in controls vs. 732±100 mg in treated hamsters, P <0.05; and accessory glands: 641±38 mg in controls vs. 548±70 mg in treated hamsters, P >0.05). These results indicate that there are some circumstances under which the gonadal responses of the reproductive organs of male and female Djungarian hamsters differ. Interestingly, pineal concentrations of melatonin were found to be significantly higher in males ( P <0.01), possibly indicating a more robust endogenous supply with the hormone, whereas serum melatonin levels were not significantly different between males and females. However, the subcutaneous injection of melatonin (5, 25, and 125 μg) exerted no acute effect on the endogenous, circadian melatonin-profile, independent of dosage and sex.     

Does melatonin alter pituitary responsiveness to gonadotropin-releasing hormone in the ewe?

The diurnal secretion of melatonin from the pineal gland transduces information about day length to the reproductive axis of many seasonal breeders including the ewe. In the sheep the target for melatonin is thought to be neural, such that the hormone acts through the GnRH pulse generator to produce seasonal alterations in the frequency of pulsatile LH secretion. These effects on the pulse generation mechanism take approximately 50 days to become evident. It is possible that melatonin also exerts direct effects at the level of the pituitary gland to alter responsiveness to GnRH. Such effects have been noted in other species. The site of action of melatonin to regulate pulsatile LH secretion was assessed in the ewe by determining whether the animal's endogenous melatonin acutely modifies pituitary responsiveness to sustained pulsatile administration of GnRH. Using an animal model in which endogenous GnRH was blocked, pituitary responsiveness to hourly pulses of exogenous GnRH was assessed under conditions of both high (dark period) and low (light period) melatonin. No evidence for acute effects of melatonin on pituitary response to GnRH was found. In another experiment, the amplitude and frequency of endogenously generated LH pulses in ovariectomized ewes was found not to change during the 24-hour light/dark cycle. These data lead to the conclusion that melatonin does not act at the pituitary gland to produce acute effects on LH secretion. Rather, our findings are consistent with the hypothesis that the action of melatonin, in this short-day breeder is long term, and is directed towards the neural elements of the hypothalamic pulse-generating mechanism.     

RFamide-related peptide gene is a melatonin-driven photoperiodic gene

In seasonal species, various physiological processes including reproduction are organized by photoperiod via melatonin, but the mechanisms of melatonin action are still unknown. In birds, the peptide gonadotropin-inhibiting hormone (GnIH) has been shown to have inhibitory effects on reproductive activity and displays seasonal changes of expression. Here we present evidence in mammals that the gene orthologous to GnIH, the RFamide-related peptide (RFRP) gene, expressed in the mediobasal hypothalamus, is strongly regulated by the length of the photoperiod, via melatonin. The level of RFRP mRNA and the number of RFRP-immunoreactive cell bodies were reduced in sexually quiescent Syrian and Siberian hamsters acclimated to short-day photoperiod (SD) compared with sexually active animals maintained under long-day photoperiod (LD). This was contrasted in the laboratory Wistar rat, a non-photoperiodic breeder, in which no evidence for RFRP photoperiodic modulation was seen. In Syrian hamsters, the reduction of RFRP expression in SD was independent from secondary changes in gonadal steroids. By contrast, the photoperiodic variation of RFRP expression was abolished in pinealectomized hamsters, and injections of LD hamsters with melatonin for 60 d provoked inhibition of RFRP expression down to SD levels, indicating that the regulation is dependent on melatonin. Altogether, these results demonstrate that in these hamster species, the RFRP neurons are photoperiodically modulated via a melatonin-dependent process. These observations raise questions on the role of RFRP as a general inhibitor of reproduction and evoke new perspectives for understanding how melatonin controls seasonal processes via hypothalamic targets.     

Exposure to short days,but not short-term melatonin,enhances humoral immunity of male Syrian hamsters (Mesocricetus auratus)

Many non-tropical rodent species rely on photoperiod as the primary cue to co-ordinate seasonally appropriate changes in physiology and behavior. Among these seasonal changes, several rodent species (e.g. deer mice, prairie voles, Siberian hamsters) adjust immune function in response to changes in ambient day lengths. The goals of the present study were to examine the effects of photoperiod on immune function of Syrian hamsters (Mesocricetus auratus), and to determine the role of melatonin in mediating photoperiodic changes in immunity. In Experiment 1, male Syrian hamsters were housed in long (LD 14:10) or short days (LD 10:14) for 10 wk. In Experiment 2, hamsters were housed in long days and half of the animals were given 10 consecutive days of i.p. melatonin injections (15 microg) in the early evening, while the remaining animals received injections of the vehicle alone. After the respective experimental manipulations, animals were injected with the antigen, keyhole limpet hemocyanin (KLH), blood samples were obtained and anti-KLH IgG antibody production was assessed. In Experiment 1, short-day hamsters underwent gonadal regression and reduced serum testosterone as well as displayed increased humoral immune function compared with long-day animals. In Experiment 2, short-term melatonin treatment did not affect gonadal mass, testosterone or humoral immune function. These results confirm previous findings of photoperiodic changes in immunity in rodents and suggest that changes in humoral immunity are not due to short-term changes in melatonin.     

Melatonin mediates photoperiod control of endocrine adaptations and humoral immunity in male Siberian hamsters

Effects of photoperiod are mediated by the pineal gland in male Siberian hamsters. The hypothesis that the pineal hormone melatonin mediates the effects of short days (SD) to blunt select humoral and endocrine functions was tested. In the first study, regressed testes were found in pineal-intact controls transferred from long days (LD) to SDs (16 hr to 8 hr light/day); the rise in antigen-induced serum immunoglobulin (Ig) M was blunted and serum cortisol concentrations elevated compared with long-day controls. These effects of short-day were blocked in pinealectomized males moved from long to SDs, but restored by melatonin treatments. In a second study, males in LD were exposed to constant light (LL) to abolish the nighttime melatonin rhythm. In hamsters in LL, melatonin induced testicular regression as in males in SDs. Large testes were present in vehicle-treated controls in LL and in males that remained in LDs. Antigen-induced increases in serum IgM in vehicle and melatonin treatment males in LL were intermediate between concentrations in long- or short-day controls and not significantly different from each other. However, serum cortisol was again elevated in hamsters in SDs or in LL when treated with melatonin compared with males in LL or LDs. These findings indicate that melatonin treatments mimicked the effects of SDs to regulate adaptive physiologic functions in hamsters lacking the nocturnal melatonin rhythm. Thus, the photoneuroendocrine mechanism regulating reproductive responses to photoperiod also mediates short-day effects on T cell-dependent B-cell antibody production and processes that regulate cortisol in circulation.     

Photoperiod-dependent regulation of inhibin in Siberian hamsters: II. Regulation of inhibin production and secretion by pregnant mare serum gonadotropin

Inhibin production differs in ovaries of Siberian hamsters (Phodopus sungorus) exposed to long days (LD) or short days (SD). We believe that seasonal differences in serum follicle-stimulating hormone contribute to this difference. However, given the profound photoperiodic differences in follicle maturation, serum gonadotropins alone may not account for all of the observed differences in inhibin processing. To test this hypothesis, we challenged LD and SD female hamsters with exogenous gonadotropins. While both groups responded with increased inhibin expression, the effects were muted in ovaries of SD females and there was no evidence of ovulation in these animals. These data indicate that the ovaries of SD females are not immediately equipped to respond to gonadotropin stimulation. More generally, these data suggest that photoperiodic history affects ovarian inhibin production and secretion in response to gonadotropins.     

Photoperiod History, Melatonin, and Reproductive Responses of Male Syrian Hamsters

The action of melatonin (MEL) in mediating photoperiodic history (PPH) effects among male Syrian hamsters was investigated. In Exp. 1, pineal intact males in LD 14:10 received daily injections of MEL (15 micrograms) or ethanol:saline vehicle (SAL) 1 h before lights off for 8 wk to generate two groups experiencing identical photoperiods but distinctly different MEL histories. Following the cessation of injections, males were transferred to either LD 12:12 or LD 8:16 for 8 wk to evaluate whether their reproductive response to the new photoperiod would be more influenced by prior PPH or prior MEL history; MEL history was the significant variable. LD 12:12 caused gradual recrudescence in hamsters that were gonadally regressed following MEL injections. In contrast, LD 12:12 caused gonadal regression in hamsters that had large testes following SAL injections. Exp. 2 evaluated whether PPH influences might be mediated by aftereffects on the period (tau) of the circadian pacemaker regulating many behavioral and physiological rhythms. Pineal intact hamsters were exposed to long or short T cycles consisting of an 8 h photoperiod, repeated every 24.67 h (long T) or 23.33 h (short T) to mimic the aftereffects generated by short or long photoperiods. After 5 wk in these T-cycle conditions, all males were transferred to LD 12:12 for 11 wk. The reproductive response to LD 12:12 was modestly influenced by T-cycle history, even though each T-cycle generated different patterns of entrainment to LD 12:12. These findings support the hypothesis that the response of the reproductive system of male hamsters to an intermediate-duration photoperiod depends upon the duration of nocturnal melatonin secretion associated with hamsters' previous PPH.     

Identification and functional characterization of melatonin Mel 1a receptors in pancreatic beta cells: potential role in incretin-mediated cell function by sensitization of cAMP signaling

Melatonin receptors are expressed within the pancreatic islets of Langerhans, and melatonin induces a direct effect on insulin secretion ex-vivo. Here, we report the endogenous expression of the melatonin Mel 1a receptor in the INS-1 pancreatic beta cell line. Pharmacological characterization of the receptor using a CRE-luciferase reporter gene demonstrated its functional activity in INS-1 cells, displaying the characteristic signaling properties of the G(i/o) coupled receptor. Acute melatonin treatment of INS-1 cells in the presence of either forskolin or the incretin hormone glucagon-like peptide 1 (GLP-1) caused an attenuation of the responses in insulin secretion, insulin promoter activity, and CRE mediated gene expression, consistent with its effects in inhibiting cAMP mediated signal transduction. However, prolonged exposure (12 h) of INS-1 cells to melatonin treatment resulted in a sensitization of cAMP mediated responses to forskolin and GLP-1. Insulin secretion, insulin promoter activity and CRE mediated gene expression levels were augmented compared with responses without melatonin pre-treatment in INS-1 cells. In isolated rat islets, insulin secretion was enhanced following melatonin pre-treatment both in the absence and presence of GLP-1 or forskolin. This phenomenon reflects observations reported in other cell types expressing the melatonin Mel 1a receptor, and may represent the first evidence of a specific physiological role for melatonin-induced sensitization.     

Diurnal Changes in Sensitivity to Melatonin in Intact and Pinealectomized Djungarian Hamsters: Effects on Thermogenesis, Cold Tolerance, and Gonads

Djungarian hamsters kept in long photoperiod (16:8 L:D) were injected daily at 0800, 1200, or 1600 with 25 micrograms of melatonin. During 90 days of treatment, body weight and fur coloration were checked at weekly intervals, and at the end of the treatment the reproductive status of the hamsters and their thermoregulatory properties (could limit, maximum thermoregulatory heat production, nonshivering thermogenesis, cytochrome oxidase activity in brown adipose tissue) were measured. Hamsters injected at 1600 changed from summer to winter status with regard to all functions investigated responding simultaneously; i.e., their body weights decreased, their fur became white, their gonads regressed, and their thermoregulatory properties improved. All these changes were identical to the effects of short photoperiod (8:16 L:D) exposure. Injections of melatonin at 0800 and 1200 were ineffective for reproductive functions, but the injection of melatonin at 0800 caused slight improvements of thermogenesis. The response to melatonin injected at 1600 could be suppressed by an additional injection of melatonin at 0800 (75 micrograms). Pinealectomized or ganglionectomized hamsters kept in long photoperiod did not respond to daily injections of melatonin at 1600 for the first 60 days of treatment, but during a prolonged treatment their sensitivity to melatonin was restored. Similarly, pinealectomized or ganglionectomized hamsters failed to respond to short photoperiod for about 40 days, but during prolonged exposure their sensitivity to short photoperiod was restored.     

Naloxone-induced secretion of LH in the male Syrian hamster: modulation by photoperiod and gonadal steroids

The role of endogenous opiates in the regulation of photoperiodically induced testicular regression was studied in the male Syrian hamster. In reproductively active hamsters exposed to a long photoperiod (LD; 16 h light: 8 h darkness) or to short days (SD; 8 h light: 16 h darkness) for 20 weeks or to SD after pinealectomy, administration of naloxone, a competitive opiate receptor antagonist, at doses of 2.5-20 mg/kg, significantly increased serum LH concentrations. In marked contrast, these doses of naloxone did not produce any change in LH levels in reproductively quiescent hamsters exposed to SD for 8 weeks. The influence of gonadal steroids on the LH response to naloxone was studied in hamsters castrated or castrated and implanted s.c with a capsule containing testosterone. Naloxone did not induce LH release in castrated hamsters maintained in LD or in SD, but this response was restored in LD but not SD when serum testosterone concentrations were maintained at levels similar to those observed in intact reproductively active hamsters. These results show that inhibition of reproduction by the photoperiod prevents naloxone-induced LH release in the male hamster. This lack of response to naloxone is not due, however, to the lower testosterone titres present in these animals compared with reproductively active animals. Responsiveness to naloxone can be restored when the animal is rendered insensitive to the inhibitory photoperiod either by removal of the pineal gland or by induction of photorefractoriness by extended exposure to SD.     

The endogenous rhythm of plasma melatonin and its regulation by light in the highveld mole-rat (Cryptomys hottentotus pretoriae): a microphthalmic, seasonally breeding rodent

Abstract:  The day- and night-time levels of plasma melatonin were measured in adult male and female highveld mole-rats, Cryptomys hottentotus pretoriae . This study aimed to assess whether melatonin secretion in this nocturnal, strictly subterranean but seasonally breeding rodent has a day-night rhythm and whether that rhythm is circadian and can be modified by photoperiod. In experiment 1, a day-night rhythm of plasma melatonin was found in all animals housed on a 12L:12D schedule, with significantly higher concentrations in the dark (D) compared with the light (L) phase. The increment of plasma melatonin concentration at night was the same on days 1 and 2 for animals in the control group and animals transferred to constant dark. The animals transferred to constant light substantially reduced the amplitude of the melatonin rhythm on day 2. This suggests that the endogenous melatonin rhythm in C. h. pretoriae has a circadian pattern, which can be synchronized by photoperiod and inhibited by exposure to light at night. In experiment 2, the concentration of plasma melatonin in animals kept under 14L:10D (long day, LD) conditions differed significantly from animals on 10L:14D (short day, SD). This finding supports the notion that C. h. pretoriae is sensitive to changes in day length.     

Photoperiod influences the effects of exercise and food restriction on an antigen-specific immune response in Siberian hamsters

Environmental conditions influence the onset and severity of illness and infection and may compromise survival. Energetically challenging conditions during winter may directly induce death through hypothermia, starvation, or shock. The ability to forecast and prepare for the arrival of challenging conditions associated with winter (e.g. low temperatures, decreased food) likely confers survival advantages. Siberian hamsters (Phodopus sungorus) stop reproduction and reduce body mass (approximately 25%) during short, winter-like day lengths, resulting in energetic savings. Hamsters also increase circulating glucocorticoids and lymphocytes (e.g. T cells, NK cells), and exhibit enhanced antigen-specific delayed-type-hypersensitivity (DTH) responses in the skin during short days (SDs). We tested the hypothesis that Siberian hamsters use SD lengths to signal the onset of winter to mediate the energetic trade-offs among body mass, reproductive function, and immune function. Long-day (LD; 16 h light, 8 h dark) and SD (8 h light, 16 h dark) hamsters were either food restricted (25%) or provided ad libitum (ad lib) food for 4 wk; half of all hamsters in each food condition had voluntary access to a running wheel, and half remained sedentary. SD hamsters enhanced DTH responses compared with LD hamsters under sedentary ad lib conditions. Exercise enhanced DTH in LD hamsters regardless of food intake. Furthermore, food-restriction did not significantly influence DTH in LD hamsters. In contrast, food-restriction suppressed DTH in SD hamsters regardless of activity condition, and exercise modestly enhanced DTH only in SD hamsters with ad lib access to food. In sum, moderate energetic deficiency suppressed DTH in SD (but not LD) hamsters, and this suggests that hamsters may have evolved to enhance immune responses during winter in preparation for increased metabolic stressors.     

Melatonin and the coding of day length in male Syrian hamsters

Two experiments investigated the response of the pituitary-gonadal axis of pinealectomized male Syrian hamsters to programmed systemic administration of melatonin. In the first experiment, castrated male Syrian hamsters were housed in a short photoperiod (8L:16D) and maintained on subcutaneous testosterone implants for 7 weeks. These males were then pinealectomized or sham-pinealectomized and their testosterone capsules removed. Daily infusions of melatonin 250 ng/infusion) or its vehicle were administered for 3 weeks; infusion duration was long (11 or 12 hr) or short (6 hr). Measurement of serum luteinizing hormone (LH) following this 3-week period indicated that long-duration melatonin infusions mimicked short-day conditions (LH levels were low), but short-duration infusions did not (LH levels were significantly elevated). In the second experiment, pinealectomized, gonadally intact males were housed in a 12L:12D photoperiod and injected once daily with melatonin or its vehicle, either 3 or 5 hr after dark onset for 11 weeks. These times were chosen to coincide with the light:dark cycle phase that according to published reports is optimally responsive to exogenous melatonin for the induction of short-photoperiodic effects. Melatonin injections did not induce gonadal regression in pinealectomized hamsters. Melatonin and vehicle-treated males responded similarly; their testis widths and serum testosterone levels were not significantly different at the end of the experiment. These results support the hypothesis that the duration of melatonin secretion each night is an important variable in conveying photoperiodic information, but that the circadian phase during which melatonin is present is not.     

Melatonin regulates energy balance and attenuates fever in Siberian hamsters

Fever is considered an important host defense response but requires significant metabolic energy. During winter many animals must balance immune function with competing physiological demands (i.e. thermoregulation) to survive. Winterlike patterns of melatonin secretion induce a number of energy-saving adaptations. For instance, Siberian hamsters attenuate the duration of fever during simulated short winter day lengths, presumably to conserve energy. To determine the proximate role of melatonin in mediating this photoperiodic response, hamsters housed in long days were injected with saline or melatonin 4 h before lights off for either 1 or 6 wk and assessed for fever following injections of bacterial lipopolysaccharide. Fever duration was attenuated (32%) only in hamsters that decreased body mass, increased cortisol, and exhibited gonadal regression in response to 6 wk of melatonin. Because melatonin-treated hamsters lost significant body mass, fever was assessed in a second long-day group following ad libitum food intake, food restriction, or 24-h food deprivation. Food restriction sufficient to reduce body mass by approximately 25%, but not to reduce leptin, did not influence fever, and 24-h food deprivation virtually abolished fever. Our data suggest that long-term exposure to long-duration melatonin signals is required to induce the physiological changes necessary for short-day immune responses, perhaps involving interactions with hormones such as cortisol and leptin.