Neuropeptide Y rapidly reduces Period 1 and Period 2 mRNA levels in the hamster suprachiasmatic nucleus.

The mammalian suprachiasmatic nucleus (SCN) contains the main circadian clock. Neuropeptide Y (NPY) that is released from the intergeniculate leaflet of the lateral geniculate body to the SCN, acts in the SCN to advance circadian phase in the subjective day via the NPY Y2 receptor. We used semi-quantitative in situ hybridization to determine the effect of NPY on circadian clock genes, Period 1 (Per1) and Period 2 (Per2), expression in SCN slices. Addition of NPY to the brain slices in the subjective day resulted in reduction of Per1 and Per2 mRNA levels 0.5 and 2 h after treatment. NPY Y1/Y5 and Y2 agonists decreased Per1 within 0.5 h. These results suggest that NPY may induce phase shifts by mechanisms involving or resulting in reduction of Per1 and Per2 mRNA levels.

Co-expression of melatonin (MEL1a) receptor and arginine vasopressin mRNAs in the Siberian hamster suprachiasmatic nucleus.

Durational melatonin signals, cued by the photoperiod and generated by the pineal gland, are processed in the brain to induce seasonally appropriate physiological and behavioural adaptations. The melatonin receptor subtype MEL1a (also known as mt1) appears to regulate seasonal responses. Single label in situ hybridization for MEL1a receptor mRNA revealed labelled cells in several brain regions of Siberian hamsters, including the suprachiasmatic nucleus, the paraventricular nucleus of the thalamus, and the reuniens nucleus of the thalamus. To characterize suprachiasmatic nucleus cells containing MEL1a receptor mRNA, we used 35S-labelled cRNA probes for MEL1a receptor mRNA in combination with digoxigenin-labelled cRNA probes for vasopressin, somatostatin, or orphan retinoid Z receptor beta (RZRbeta; a putative nuclear melatonin receptor). Cells in the suprachiasmatic nucleus that contained MEL1a receptor mRNA also contained mRNAs for vasopressin and RZRbeta, but not for somatostatin. These data suggest that suprachiasmatic nucleus vasopressin cells may respond to melatonin signals, raising the possibility that suprachiasmatic nucleus vasopressin output mediates some of the effects of melatonin on seasonal or circadian responses.

Oestrogen receptor-alpha-immunoreactive neurones project to the suprachiasmatic nucleus of the female Syrian hamster.

Ovarian steroid hormones regulate circadian period and phase, but classical receptors for these hormones are absent in the circadian pacemaker localized in the suprachiasmatic nucleus of the hypothalamus (SCN). In order to determine whether effects of oestrogen may be exerted through steroid-binding systems afferent to the SCN we have performed double label immunocytochemistry for oestrogen receptor-alpha(ER-alpha) and the retrograde tracer cholera toxin B subunit (CtB) after its application to the SCN. Most of the areas that contain ER-alpha-immunoreactive (ERalpha-ir) cells also contained cells afferent to the SCN. The percentage of neurones afferent to the SCN which show ERalpha-immunoreactivity varies between areas. As many as one-third of the neurones afferent to the SCN in some parts of the preoptic area and the corticomedial amygdala are ERalpha-ir. Very few of the afferent neurones from the septum and the central grey are ERalpha-ir, whereas an intermediate proportion of afferents from the bed nucleus of the stria terminalis and the arcuate nucleus are ERalpha-ir. Our retrograde tracing results were compared with results of anterograde tracing from some of the sites containing SCN afferents. Using a combined retrograde and anterograde tracing technique we tested the possibility that single ERalpha-ir neurones afferent to the SCN could receive reciprocal innervation by SCN efferents. Although we found SCN input to some SCN afferent neurones, we found no evidence of reciprocity between single ERalpha-ir cells and the SCN. Our results indicate the existence of oestrogen binding systems afferent to the SCN. These neuroanatomical pathways may mediate effects of gonadal steroid hormones on circadian rhythms.

Effects of photoperiod and androgen on proopiomelanocortin gene expression in the arcuate nucleus of golden hamsters.

In golden hamsters, seasonal changes in day length act via a pineal-dependent mechanism to regulate feedback and behavioral effects of androgen. Endogenous opiates participate in photoperiodically regulated neuroendocrine functions, but the effects of androgen on expression of the gene encoding POMC, the precursor of beta-endorphin, have been controversial. We used quantitative in situ hybridization to examine regulation of POMC messenger RNA (mRNA) by testosterone and to test the hypothesis that short day lengths act through the pineal gland to amplify POMC mRNA expression. We studied intact hamsters and castrates with or without androgen treatment held in long (14 h of light, 10 h of darkness) or short (5 h of light, 19 h of darkness) days for 10 weeks. POMC gene expression differed with rostral-caudal plane, photoperiod, and surgical treatment (castration and testosterone administration). Testosterone increased the number of silver grains in labeled cells throughout the arcuate nucleus, and short day castrates given androgen consistently had more silver grains per labeled cell than did their long day counterparts. Testosterone exerted an inhibitory effect, however, on the number of POMC mRNA-positive cells, and more POMC mRNA-labeled cells were found in the arcuate nucleus of long than short day castrates treated with testosterone. Photoperiod had no significant influence in castrates not receiving androgen. Testosterone treatment had generally similar effects whether it was begun at the time of castration or 5 weeks later. Pinealectomy blocked the influence of photoperiod on both the mean number of silver grains per labeled cell and the number of labeled cells. The results indicate that day length regulates POMC gene expression when androgen levels are held constant, but that androgen is necessary for photoperiod effects to be expressed.

Effects of suprachiasmatic transplants on circadian rhythms of neuroendocrine function in golden hamsters.

Grafts of fetal tissue including the suprachiasmatic nucleus (SCN) of the hypothalamus restore locomotor rhythmicity to behaviorally arrhythmic, SCN-lesioned Syrian hamsters. We sought to determine whether such transplants also reinstate endocrine rhythms in SCN-lesioned hamsters. In Exp 1, SCN lesions interrupted estrous cycles in a 14 h light, 10 h dark photoperiod and locomotor rhythms in constant dim red light (DD). SCN grafts that reinstated behavioral circadian rhythms consistently failed to reestablish estrous cycles. After ovariectomy, estradiol implants triggered LH surges at approximately circadian time 8 in 10 of 12 brain-intact control females and 0 of 9 SCN-lesioned, grafted females. Daily rhythms of the principal urinary melatonin metabolite, 6alpha-sulfatoxymelatonin, were not reestablished by behaviorally functional grafts. In Exp 2, SCN lesions eliminated locomotor rhythmicity in adult male hamsters maintained in DD. Seven to 12 weeks after restoration of locomotor activity rhythms by fetal grafts, hosts and sham-lesioned controls were decapitated at circadian times 4, 8, 12, 16, 20, or 24. Clear circadian rhythms of both serum corticosterone and cortisol were seen in sham-lesioned males, with peaks in late subjective day. No circadian rhythms in either adrenal hormone were evident in serum from lesioned-grafted males. Testicular regression, observed in intact and sham-lesioned males maintained in DD, was absent not only in arrhythmic SCN-lesioned hamsters given grafts of cerebral cortex, but also in animals in which hypothalamic grafts had reinstated locomotor rhythmicity. The pineal melatonin concentration rose sharply during the late subjective night in control hamsters, but not in SCN-lesioned animals bearing behaviorally effective transplants. Even though circadian rhythms of locomotor activity are restored by SCN transplants, circadian endocrine rhythms are not reestablished. Endocrine rhythms may require qualitatively different or more extensive SCN outputs than those established by fetal grafts.

Photoperiod regulates neuronal bromodeoxyuridine labeling in the brain of a seasonally breeding mammal.

Seasonal changes in vertebrate brain function are pervasive, but annual cycles in the rates of neuronal incorporation are established only in songbirds. Although cell division continues in the subependymal and hippocampal subgranular zones of adult rodents, there exists no parallel evidence that seasonal plasticity in mammals extends to changes in neuronal or glial number. We examined the effect of photoperiod on incorporation of new neurons in the brain of the adult golden hamster, a long-day breeder. We administered the cell birth marker 5'-bromodeoxyuridine (BrdU) to males which had either been maintained in long days, transferred to short days for 10 weeks, or moved acutely from long to short or short to long days. The number of cells in specific brain regions immunoreactive (ir) for this thymidine analog was determined 7 weeks later. The number of BrdU-ir cells in the dentate gyrus and subependymal zone increased twofold in short days. Transfer between photoperiods 10 days before the BrdU injections produced intermediate numbers of BrdU-labeled cells in the dentate gyrus, but was as effective as long-term photoperiodic exposure in the subependymal zone. Photoperiod also had similar effects in the hypothalamus and cingulate/retrosplenial cortex, but not in the central gray or preoptic area. Double-label immunocytochemistry indicated that very few of the BrdU-ir cells were glia, but that a majority had neuronal phenotype. In the subependymal zone, short days significantly increased the number of BrdU-labeled neurons. We did not detect significant effects of photoperiod on the volume of either the granule cell layer of the hippocampus or the dentate gyrus as a whole. We conclude that short day lengths increase neuronal birth and/or survival in several brain regions of adult hamsters.

Localization and partial characterization of melatonin receptors in amphioxus, hagfish, lamprey, and skate.

Through its secretion of melatonin, the pineal complex of vertebrates exerts a range of physiological effects including regulation of circadian rhythms, seasonal reproduction, metamorphosis, and body color change. Little is known about phylogenetic differences in the distribution and characteristics of melatonin binding sites in fishes. We used in vitro autoradiography to examine binding of [2-125I]iodomelatonin (IMEL) in 20-micron frozen sections of amphioxus (Branchiostoma lanceolatum), Atlantic hagfish (Myxine glutinosa), larval and adult lamprey (Petromyzon marinus), little skate (Raja erinacea), and rainbow trout (Oncorhynchus mykiss). Tissue was incubated with IMEL in the presence or absence of unlabeled melatonin (1 muM, in order to assess nonspecific binding). A concentration of 32 pM IMEL was used for single point assays and competition studies. No specific binding was found in hagfish or amphioxus, which lack a pineal complex. In the optic tecta of lamprey, skate, and trout, IMEL binding is highly specific (melatonin >> N-acetylserotonin > 5- methoxytryptophol >> serotonin). Scatchard analysis revealed that the tectal binding sites are of high affinity (Kd = 36, 38, and 50 pM) and low capacity (Bmax = 8.1, 19.8, and 21.8 fmol/mg protein) in lamprey, skate, and trout, respectively. In adult lampreys, intense specific IMEL binding is found in the optic tectum (layer I > II > III) and preoptic nucleus (pars parvocellularis > magnocellularis). Binding was less intense and consistent in the same areas of ammocoete brain. In skates and trout, intense specific binding is found in optic tectum, lateral geniculate body, diencephalic preoptic and suprachiasmatic nuclei, basal hypothalamus, and the medial pallium. These results indicate that specific melatonin binding sites are present in all craniate taxa examined except in hagfish. Although we cannot rule out the possibility that melatonin receptors are secondarily lost in hagfish, their absence in amphioxus makes this unlikely. We speculate that melatonin actions in early vertebrates may have included regulation of visual and endocrine responses to light.

Effects of photoperiod duration and melatonin signal characteristics on the reproductive system of male Syrian hamsters.

Three experiments tested effects of photoperiod and the pineal hormone melatonin (MEL) on reproductive function among male Syrian-hamsters. In Experiment 1, hamsters were exposed for 32 weeks to 1 of 4 short photoperiods which varied in duration (11.5 L; 10 L; 8 L; 6 L). A fifth group was shifted from 11.5 L to 6 L after 6 weeks. Shorter photoperiods were associated with more rapid regression of the testes, but all groups eventually regressed to the same extent. In contrast, the temporal profile of testicular recrudescence, expressed as males became photorefractory, was not significantly different between groups. A decrease in photoperiod from 11.5 L to 6 L after 6 weeks did not delay the onset of recrudescence. The 11.5 L group was subdivided at week 32 and transferred to either 13 L or 16 L for the next 8 weeks to break photorefractoriness. Upon subsequent exposure to 8 L, both subgroups regressed their testes in similar fashion over weeks 40-52, indicating that the two long photoperiods were equally effective in breaking photorefractoriness. Nevertheless, FSH and prolactin were more consistently suppressed in the 16 L group following the switch to 8 L. Experiment 2 tested whether differing durations of MEL, administered s.c. each night for 9 weeks, elicit graded rates of reproductive regression in pinealectomized males. Testicular regression was more rapid in the group receiving MEL for 12 h than it was in the group receiving MEL for 8.5 h, thus supporting the hypothesis that the faster rates of testicular regression in the shorter photoperiods of Experiment 1 were due to their concomitant longer durations of nightly MEL secretion. Experiment 3 tested the hypothesis that rates of testicular regression in males receiving exogenous MEL would be affected by their prior photoperiodic history. Males were exposed to 18 L or 14 L for 7 weeks, then pinealectomized and administered 9.5 h MEL infusions s.c. each night for 9 weeks. In contrast to predictions, photoperiodic history had only transitory effects on MEL-induced testicular regression. Although the differences in MEL duration that accompany different short photoperiods have reproductive consequences (Experiment 1), the extent to which MEL duration expands during the transition from stimulatory to inhibitory photoperiods appears to be a less significant variable (Experiment 3).

Effects of photoperiod and androgen on pituitary function and neuropeptide staining in Siberian hamsters.

Short photoperiods decrease gonadotropin secretion in Siberian hamsters, but it is unknown whether the negative feedback effects of androgens are amplified under such conditions, as is the case in other species. Photoperiod regulates the synthesis and secretion of gonadotropin-releasing hormone (GnRH), beta-endorphin, and arginine vasopressin (AVP), which influence gonadotropin release and sexual behavior but are themselves regulated by gonadal steroid hormones. To determine the role of androgen in these effects of daylength, immunostaining and gonadotropin concentrations were examined after 8 wk of exposure to long or short days (LD or SD). Animals were either left intact, castrated, or castrated with immediate or delayed replacement of testosterone (T). We also investigated effects of age on photoperiodic influences on brain peptides and serum hormone levels. Serum prolactin concentrations were regulated by photoperiod and by gonadal status in LD hamsters. Effects of T on follicle-stimulating hormone secretion were more pronounced in SD hamsters. Older hamsters were generally less responsive to effects of daylength on pituitary function. Photoperiod and gonadal status regulated the number of AVP-immunoreactive (ir) cells in the bed nucleus of the stria terminalis and the medial amygdala. Androgen treatment yielded more AVP-ir neurons in LD than in SD. Photoperiod influenced the number of GnRH-ir cells only in the medial septum of castrated hamsters. Daylength regulated beta-endorphin-ir neurons in intact hamsters, but not in castrates. Only among old hamsters did photoperiod affect the influence of T on beta-endorphin staining in neurons and fibers. Such fiber staining was unaffected by photoperiod in intact and T-treated castrate hamsters, but was reduced in SD castrates. We conclude that daylength modulates the effects of androgen on gonadotropin secretion and influences the effect of T on neuropeptide staining in regionally specific patterns that depend on the age of the animal and its history of prior steroid exposure.

Regulation of the phase and period of circadian rhythms restored by suprachiasmatic transplants.

The influence of exogenous signals on circadian rhythms restored by transplants of the suprachiasmatic nucleus (SCN) of the hypothalamus has received little study. The authors tested the responsiveness of hamsters bearing SCN transplants to photic and pharmacological treatments. Light intensities as high as 6,500 lux were insufficient to produce entrainment, although masking was observed frequently. Triazolam failed to produce statistically significant phase shifts when administered during the subjective day, but 2 animals bearing functional SCN grafts responded to this benzodiazapine during the subjective night. The authors next tested the hypothesis that the host can retain circadian aftereffects that influence the period of the circadian system reconstituted by the graft. Intact hamsters were entrained to light:dark cycles of short (23.25-h) and long (25-h) period (T) for at least 3 months. Control hamsters released into constant darkness exhibited profound and long-lasting aftereffects of entrainment to T cycles. Hamsters that received SCN lesions after exposure to these T cycles and SCN grafts 3 weeks later exhibited marginal but statistically significant aftereffects that disappeared within 3 months. On subsequent transfer to constant light, tau lengthened by 0.25 +/- 0.6 h in hamsters with intact SCN (p < .05). Animals bearing SCN grafts continued to free run in constant light but differed from intact animals in that circadian period did not lengthen. Functional SCN grafts contained vasoactive intestinal polypeptide (VIP), neurophysin (NP), and cholecystokinin (CCK) immunoreactive (ir) cells. Inputs of neuropeptide Y-and serotonin-ir fibers from the host brain to grafted SCN peptide cell clusters were variable. Limited observations using retrograde and anterograde tracers do not support the existence of extensive input to the graft. Retinal input overlapped only rarely with clusters of VIP-ir, CCK-ir, or NP-ir cells. The authors conclude that the circadian system reinstated by SCN transplants is relatively impervious to photic influences that exert parametric and nonparametric influences in intact hamsters. The transient expression of aftereffects induced in the host before transplantation indicates that extra-SCN systems of the host can influence the period of the reconstituted circadian system to at least a limited degree.

Lesions of the melatonin- and androgen-responsive tissue of the dorsomedial nucleus of the hypothalamus block the gonadal response of male Syrian hamsters to programmed infusions of melatonin.

The objective of this study was to characterize a site at which it is likely that melatonin mediates photoperiodic control of reproduction in the male Syrian hamster. The first experiment was a comparison of the distributions of iodomelatonin (IMEL)-binding sites and cells immunoreactive to androgen receptors (AR-ir) in the medio-basal hypothalamus (MBH). AR-ir cells extended throughout the MBH, whereas IMEL binding was restricted to the dorsomedial nucleus (DMN). Comparisons between IMEL binding and AR-ir on adjacent cryostat sections revealed a clear overlap between the IMEL-binding sites and a distinct subpopulation of AR-ir cells within the DMN. The second experiment examined whether lesions of these IMEL- and androgen-responsive cells affected the response of the hamsters to short-day (SD)-like infusions of melatonin. Animals received sham or bilateral electrolytic lesions of the IMEL-binding sites within the DMN of the hypothalamus (MBH-X). Animals were pinealectomized and 4 wk later fitted with an s.c. cannula for the daily infusion of either melatonin (50 ng/h) or saline (500 microliters/10 h). After 6 wk the animals with sham lesions showed gonadal atrophy and lower serum concentrations of LH and prolactin (PRL) after infusions with melatonin. In contrast, MBH-X animals given melatonin had large testes and long-day (LD)-like serum LH concentrations. Infusions of melatonin did, however, cause a significant decline in serum PRL level. This study shows that an intact MBH is essential for the expression of gonadotrophic but not lactotrophic responses to melatonin and/or photoperiod. It also suggests that cells responsive to both gondal steroids and melatonin may be involved in the seasonal variation in GnRH release, and indicates a site at which melatonin might influence sensitivity to steroid feedback, a hypothalamic function known to be regulated by photoperiod.

Short days increase sensitivity to methadone inhibition of male copulatory behavior.

Exposure to short, winter-like daylengths produces deficits in male golden hamster copulatory behavior, even when exogenous testosterone is administered to replicate serum concentrations typical of hamsters housed in long days. Daylength also regulates opiate receptor concentrations in limbic brain regions which control sexual behavior, and the response of gonadotropin secretion to opiate receptor antagonists is modulated by daylength. This study tests the hypothesis that short days amplify the opiatergic inhibition of copulatory behavior. Male golden hamsters were castrated and given testosterone implants before transfer to short days. Hamsters were tested for copulatory behavior after injections of saline or various doses of methadone, an opiate agonist believed to be specific for mu receptors. Locomotor activity was also measured. Hamsters housed in short days showed copulatory deficits in response to lower doses of methadone than hamsters housed in long days. Short days enhanced copulatory deficits after methadone at doses which did not affect general activity.

The suprachiasmatic area in the female hamster projects to neurons containing estrogen receptors and GnRH.

This study investigated whether the circadian regulation of luteinizing hormone (LH) release may be through direct input of the suprachiasmatic nucleus (SCN) to estrogen receptor (ER)- and/or gonadotropin releasing hormone (GnRH)-immunoreactive neurons. We used Phaseolus vulgaris leucoagglutinin (PHA-L) as an anterograde tracer of SCN efferents and performed double label immunocytochemistry for PHA-L and ER or GnRH. Between 8 and 30% of ER cells and 11-13% of the GnRH cells showed appositions with SCN efferents. Efferent projections of the subparaventricular hypothalamic nucleus and the retrochiasmatic area, relay stations of the circadian system, also made appositions with these two cell types. Results suggest that the circadian system could regulate the timing of the LH surge via two pathways, through input to GnRH and to ER cells.

Regional distribution of iodomelatonin binding sites within the suprachiasmatic nucleus of the Syrian hamster and the Siberian hamster.

The pineal hormone melatonin is a potent regulator of seasonal and circadian rhythms in vertebrates. In order to characterize potential target tissues of melatonin, the distribution of iodomelatonin (IMEL)-binding sites was examined within neurochemically and anatomically defined subdivisions of the suprachiasmatic nucleus (SCN), a structure necessary for seasonal and circadian rhythms in mammals. Studies were carried out in both the adult Syrian (Mesocricetus auratus) and Siberian (Phodopus sungorus) hamster. The retinoreceptive zone of the SCN was identified anatomically by immunocytochemical (ICC) visualization of cholera toxin B subunit tracer (ChTB-ir) following its intra-ocular injection. Photically-responsive SCN cells were identified by immunostaining for the protein product of the immediate-early gene c-fos (Fos-ir) following exposure of the animal to light. The non-photoresponsive zone of the SCN was identified using in situ hybridization (ISH) for arginine vasopressin (AVP) mRNA, whilst sites of IMEL-binding in the SCN were identified by in vitro film autoradiography using the specific ligand 2-[125I]-iodomelatonin. To compare directly the distribution of IMEL-binding sites and one of the functional zones of the nucleus, alternate serial coronal sections through the SCN were processed for autoradiography for IMEL and one of the following: ICC for ChTB-ir or Fos-ir, or ISH for AVP mRNA. Overall, the regional distribution of the various markers within the SCN was comparable in the two species. The retinorecipient (ChTB-ir) and photically-responsive (Fos-ir) zones of the SCN mapped together to the middle and caudal thirds of the nucleus, predominantly in its ventro-lateral division.(ABSTRACT TRUNCATED AT 250 WORDS)

Steroidal and photoperiodic regulation of opiate binding in male golden hamsters.

This study was designed to investigate interactions between daylength and testosterone (T) in the regulation of 3H-naloxone binding which may contribute to seasonal changes in the negative feedback and behavioral effects of androgens in the golden hamster. Photoperiod influenced opiate binding in hamsters with intact gonads only in the medial amygdala. Castration elevated specific 3H-naloxone binding in the medial amygdala, medial preoptic nucleus, bed nucleus of the stria terminalis, and in the basolateral amygdaloid nucleus of hamsters exposed to either long (14L:10D) or short (5L:19D) days. Exposure to SD renders hamsters less sensitive to T maintenance in reversing these effects. Delay of T replacement until 5 weeks after castration eliminated the ability of this androgen to reverse the influence of castration upon opiate receptors in the medial amygdala. Pinealectomy markedly increased 3H-naloxone binding in short days in several brain areas. The data demonstrate that androgens and photoperiod interact to regulate 3H-naloxone binding, particularly in the medial amygdala. These effects may play a functionally relevant role in seasonal changes in the expression of sexual behavior and/or gonadotropin secretion.

Melatonin binding sites in sciurid and hystricomorph rodents: studies on ground squirrels and guinea pigs.

Little is known about the distribution of binding sites for the pineal hormone melatonin in non-myomorph rodents. We used 2-[125I]iodomelatonin (IMEL) to analyze the distribution, affinity, and specificity of binding sites in the golden-mantled ground squirrel, a sciurid rodent that reportedly lacks IMEL binding sites in the brain. Specific binding was found not only in the pars tuberalis, but also in several telencephalic and diencephalic areas including the hypothalamic suprachiasmatic region. The affinity and specificity of IMEL binding are comparable to those reported in other rodents. IMEL binding studies in a hystricomorph rodent, the guinea pig, revealed high concentrations of receptor in the nucleus accumbens and dorsolateral thalamus. Central melatonin binding sites have now been demonstrated in species of all three rodent families. The heterogeneous distribution of melatonin receptors appears similar in the species studied, and no evidence is found to link IMEL binding sites at any particular locus to photoperiodic, circannual, or non-seasonal breeding patterns.

The timed infusion paradigm for melatonin delivery: what has it taught us about the melatonin signal, its reception, and the photoperiodic control of seasonal responses?

This review summarizes the evidence showing that the duration of the nocturnal secretory profile of pineal melatonin (MEL) is critical for eliciting seasonally appropriate reproductive physiological and behavioral responses in mammals. We review experiments using the timed infusion paradigm (TIP) to deliver MEL either systemically or centrally to pinealectomized hamsters and sheep. In this paradigm, MEL is infused, usually once daily, for a specific number of hours and at a predetermined time of day. This experimental strategy tests most directly those features of the MEL signal that are necessary to trigger photoperiodic responses. The data suggest that the duration of the MEL stimulation is the critical feature of the MEL signal for both inhibitory and stimulatory effects of the hormone on the photoperiodic control of reproductive development in juvenile Siberian hamsters, and for the photoperiodic control of reproductive and metabolic responses in adult Siberian and Syrian hamsters and sheep. The use of the TIP reveals the importance of the frequency of the signal presentation of MEL and suggests the importance of a period of low-to-absent circulating concentrations of the hormone. The TIP also reveals that the characteristics of the MEL signal that regulate male sexual behavior are similar to those that are critical for reproductive and metabolic responses in Syrian hamsters. We summarize the locations of possible functional MEL target sites identified by combining the TIP with traditional brain lesion techniques. Evidence from such studies suggests that the integrity of the suprachiasmatic nucleus (SCN) region in Siberian hamsters and the anterior hypothalamus in Syrian hamsters is necessary for the response to short-day MEL signals. The TIP has been used to deliver MEL to putative target sites for the hormone in the brain of juvenile and adult Siberian hamsters. The results of these preliminary experiments suggest that the regions of specific MEL binding in this species, especially the SCN, are effective sites where MEL may stimulate short-day-type responses. In contrast, results from intracranial application of MEL in sheep suggest the medial basal hypothalamus as a critical site of action. Finally, we also discuss potential applications of the TIP for identification of brain MEL target sites, understanding of other photoperiodic phenomena and responses, and resolution of the cellular/molecular basis underlying the reception and interpretation of MEL signals.(ABSTRACT TRUNCATED AT 400 WORDS)

Photoperiodic regulation of pulsatile luteinizing hormone secretion and adenohypophyseal gene expression in female golden hamsters.

LH concentrations were measured in serum collected at 10-min intervals from chronically ovariectomized female Syrian hamsters that had been maintained for 9 wk in stimulatory (long) or inhibitory (short) photoperiods. Short days reduced the number of detectable LH pulses during both the morning and the afternoon. Most short-day hamsters experienced a gradual afternoon rise in serum LH concentrations; this rise was not composed of multiple pulses. In separate groups of similarly treated hamsters, pituitary LH-beta mRNA abundance was significantly reduced by short-day exposure at both times of day even though serum LH concentrations rose in the afternoon. Estradiol treatment induced an afternoon surge of serum LH in both photoperiods, and eliminated the effect of photoperiod on LH-beta mRNA abundance in the afternoon. Serum prolactin (PRL) concentrations were not consistently influenced by day length in castrated hamsters with or without estrogen treatment, but PRL mRNA abundance was significantly suppressed by short-day exposure in all groups. The results indicate that day length exerts profound steroid-independent effects upon hypophyseal gene expression, and that the regulation of LH-beta mRNA abundance may be due to photoperiodic control of the neural GnRH pulse generator.

SCN lesions block responses to systemic melatonin infusions in Siberian hamsters.

The role of the suprachiasmatic nuclei (SCN) in the response to short-day melatonin (MEL) signals was examined in long-day-housed pinealectomized (PINX) Siberian hamsters. Five- or ten-hour MEL infusions that mimicked the peak nocturnal durations of serum MEL levels in long or short days, respectively, or control saline infusions were given for 5 wk. Half the hamsters in each infusion group also received bilateral electrolytic SCN lesions. The 10-h MEL infusions reduced testes weight, body and fat pad weights, and serum prolactin (PRL) and follicle-stimulating hormone (FSH) concentrations in unoperated controls. These short-day-type effects were blocked by SCN lesions, which often produced hyperprolactinemia. Circadian rhythms of locomotor activity were disrupted or sparse in hamsters with lesions in or near the SCN. In a second experiment, 5 wk of long-day-like, short-duration (5-h) MEL infusions were administered to hamsters that had been PINX after 8 wk of short-day exposure. Control hamsters given 5-h MEL infusions, but not 10-h MEL or saline infusions, exhibited testicular growth and increased serum PRL levels. Hamsters with SCN lesions showed similar responses, regardless of the duration or type of infusion. Although the blockade of 10-h MEL infusion-induced testicular regression by SCN lesions in experiment 1 may have been due to stimulation of the testes by PRL, it is unlikely that the hyperprolactinemia accounted for the ability of SCN lesions to block effects of 10-h MEL infusions on fat pad and body weights. Therefore, the SCN and/or neighboring structures may participate in the response to short-day MEL signals in Siberian hamsters.