Behavioral and Morphological Studies of Fetal Neural Transplants into SCN-Lesioned Rats

We have studied the effects of fetal neuronal grafts on the temporal pattern of drinking behavior of suprachiasmatic nuclei (SCN)-lesioned adult rats. Additionally, in an independent set of animals, the immunohistochemical staining for vasopressin, vasoactive intestinal polypeptide, and neuropeptide Y and the retinal connections to the hypothalamus were studied. The behavioral experiments indicate that anterior hypothalamic transplants induced reorganization of the temporal pattern of drinking behavior when placed in the third ventricle of adult hosts bearing complete SCN lesions, but not when placed in a cavity in the occipital cortex. Such rhythmicity persists only when the animals were recorded under constant darkness but not under constant light, indicating that the restored rhythmicity was generated endogenously but that the oscillator was extremely sensitive to light. Fetal occipital cortex induced reorganization of the temporal pattern of previously arrhythmic hosts, but it disappeared when the animals were recorded under constant light or constant darkness. It is clear that this rhythmicity was exogenous. In contrast to the cortical transplants, the hypothalamic transplants showed a morphological organization similar to that found in the normal hypothalamus regardless of their placement in the host brain. From these observations it is concluded that development of neocortex is more affected by environmental factors than that of the hypothalamus. Both hypothalamic and cortical transplants induced sprouting of retinal fibers into the anterior hypothalamus and the grafted tissue. It is possible that such fibers could be the neuroanatomical substrate by which rhythmicity is induced by cortical tissue.     

Dissociation between circadian Per1 and neuronal and behavioral rhythms following a shifted environmental cycle

The suprachiasmatic nucleus (SCN) of the anterior hypothalamus contains a major circadian pacemaker that imposes or entrains rhythmicity on other structures by generating a circadian pattern in electrical activity. The identification of "clock genes" within the SCN and the ability to dynamically measure their rhythmicity by using transgenic animals open up new opportunities to study the relationship between molecular rhythmicity and other well-documented rhythms within the SCN. We investigated SCN circadian rhythms in Per1-luc bioluminescence, electrical activity in vitro and in vivo, as well as the behavioral activity of rats exposed to a 6-hr advance in the light-dark cycle followed by constant darkness. The data indicate large and persisting phase advances in Per1-luc bioluminescence rhythmicity, transient phase advances in SCN electrical activity in vitro, and an absence of phase advances in SCN behavioral or electrical activity measured in vivo. Surprisingly, the in vitro phase-advanced electrical rhythm returns to the phase measured in vivo when the SCN remains in situ. Our study indicates that hierarchical levels of organization within the circadian timing system influence SCN output and suggests a strong and unforeseen role of extra-SCN areas in regulating pacemaker function.     

Phase response curve and light-induced fos expression in the suprachiasmatic nucleus and adjacent hypothalamus of Arvicanthis niloticus

This article describes the phase response curve (PRC), the effect of light on Fos immunoreactivity (Fos-IR) in the suprachiasmatic nucleus (SCN), and the effect of SCN lesions on circadian rhythms in the murid rodent, Arvicanthis niloticus. In this species, all individuals are diurnal when housed without a running wheel, but running in a wheel induces a nocturnal pattern in some individuals. First, the authors characterized the PRC in animals with either the nocturnal or diurnal pattern. Both groups of animals were less affected by light during the middle of the subjective day than during the night and were phase delayed and phase advanced by pulses in the early and late subjective night, respectively. Second, the authors characterized the Fos response to light at circadian times 5, 14, or 22. Light induced an increase in Fos-IR within the SCN during the subjective night but not subjective day; this effect was especially pronounced in the ventral SCN, where retinal inputs are most concentrated, but was also evident in other regions. Both light and time influenced Fos-IR within the lower subparaventricular area. Third, SCN lesions caused animals to become arrhythmic when housed in a light-dark cycle as well as constant darkness. In summary, Arvicanthis appear to be very similar to nocturnal rodents with respect to their PRC, temporal patterns of light-induced Fos expression in the SCN, and the effects of SCN lesions on activity rhythms.     

Temporal phasing of locomotor activity, heart rate rhythmicity, and core body temperature is disrupted in VIP receptor 2-deficient mice

Neurons of the brain's biological clock located in the hypothalamic suprachiasmatic nucleus (SCN) generate circadian rhythms of physiology (core body temperature, hormone secretion, locomotor activity, sleep/wake, and heart rate) with distinct temporal phasing when entrained by the light/dark (LD) cycle. The neuropeptide vasoactive intestinal polypetide (VIP) and its receptor (VPAC2) are highly expressed in the SCN. Recent studies indicate that VIPergic signaling plays an essential role in the maintenance of ongoing circadian rhythmicity by synchronizing SCN cells and by maintaining rhythmicity within individual neurons. To further increase the understanding of the role of VPAC2 signaling in circadian regulation, we implanted telemetric devices and simultaneously measured core body temperature, spontaneous activity, and heart rate in a strain of VPAC2-deficient mice and compared these observations with observations made from mice examined by wheel-running activity. The study demonstrates that VPAC2 signaling is necessary for a functional circadian clock driving locomotor activity, core body temperature, and heart rate rhythmicity, since VPAC2-deficient mice lose the rhythms in all three parameters when placed under constant conditions (of either light or darkness). Furthermore, although 24-h rhythms for three parameters are retained in VPAC2-deficient mice during the LD cycle, the temperature rhythm displays markedly altered time course and profile, rising earlier and peaking ～4-6 h prior to that of wild-type mice. The use of telemetric devices to measure circadian locomotor activity, temperature, and heart rate, together with the classical determination of circadian rhythms of wheel-running activity, raises questions about how representative wheel-running activity may be of other behavioral parameters, especially when animals have altered circadian phenotype.     

Differential elimination of circadian and ultradian rhythmicity by hypothalamic lesions in the common vole, Microtus arvalis

Effects of hypothalamic lesions on the ultradian and circadian organization of wheel running and feeding were studied in the common vole, Microtus arvalis. Circadian organization broke down within 30 days in continuous darkness in 24% of intact voles (n = 135). Ultradian rhythmicity of feeding (period 2-3 hr) persisted in constant conditions in all intact voles. Following lesions of the suprachiasmatic nuclei (SCN), circadian rhythmicity disappeared when lesions were complete (n = 8) or more extensive than 25% of the total SCN volume (n = 5). Absence of circadian rhythmicity was also found in animals with substantial lesions in the diencephalic paraventricular area (PVA) and in the retrochiasmatic area (RCA) and/or adjacent arcuate nucleus (Arc). Complete loss of ultradian and circadian organization occurred in eight voles with damage to the RCA and/or Arc. In three of these, the SCN was intact. The SCN is a likely candidate for a circadian pacemaker in voles (as in other rodents), while the loss of circadian rhythmicity following PVA and RCA/Arc lesions may be due to destruction of efferent pathways from the SCN. The RCA/Arc area is apparently necessary for the expression of ultradian rhythms. The intact SCN is neither necessary nor sufficient for the generation of ultradian rhythmicity.     

Feeding rhythms in constant light and constant darkness: the role of the eyes and the effect of melatonin infusion

Exposure to constant light abolishes circadian behavioral rhythms of locomotion and feeding as well as circulating melatonin rhythms in pigeons (Columba livia). To determine if feeding rhythmicity could be maintained in pigeons exposed to constant light, periodic infusions (10h/day) of melatonin were administered to pinealectomized and bilaterally retinectomized/pinealectomized pigeons under conditions of both constant darkness and constant light. The infusions were sufficient to entrain rhythmicity in pinealectomized pigeons in constant darkness and to restore and maintain rhythmicity in bilaterally retinectomized/pinealectomized pigeons in constant darkness. On subsequent exposure to constant light, rhythmicity remained phase locked to the melatonin infusions in bilaterally retinectomized/pinealectomized pigeons but was abolished in sighted pinealectomized birds. These results suggest that while endogenous melatonin rhythms are both necessary and sufficient to maintain behavioral rhythms in DD, their effect can be overridden by constant light but only if perceived by the eyes. Thus, constant light may abolish behavioral rhythmicity in intact pigeons (and perhaps in other species) by a mechanism other than suppression of endogenous melatonin rhythmicity. Such a mechanism might involve direct stimulation of locomotor or feeding activity by retinally perceived (but not by extra-retinally perceived) light, or alternatively by suppression of a hypothalamic oscillator that receives its major light input from the retinae.Abbreviations PX pinealectomized - EX bilaterally enucleated - LD light:dark cycle - LL constant light - DD constant darkness - DD_b constant darkness before exposure to constant light - DD_a constant darkness after exposure to constant light     

Circadian locomotor rhythms, but not photoperiodic responses, survive surgical isolation of the SCN in hamsters.

Surgical isolation of the suprachiasmatic nuclei (SCN) within a hypothalamic island is reported to produce loss of circadian rhythmicity. The results have been interpreted to indicate that SCN efferents are necessary for the expression of circadian rhythms. It is not clear, however, whether the loss of circadian rhythms in behavioral responses following SCN isolation is attributable to transection of efferents, to loss of cells within the island, or to gliosis produced by the knife cut. To explore this issue, we examined locomotor activity and gonadal state of male golden hamsters housed in constant darkness (DD, with a dim red light for maintenance) for at least 10 weeks following isolation of the SCN from the rest of the brain by cuts by means of a Halasz wire microknife. Brain sections were immunocytochemically stained for the peptides vasoactive intestinal polypeptide (VIP), vasopressin (VP) or neurophysin II (NP II), and neuropeptide Y (NPY) to localize the SCN and to assess its viability, and for glial fibrillary acidic protein (GFAP) to delimit the border of the knife cut. Experimental animals with VIP and VP/NP II immunoreactivity in the SCN within the island retained free-running locomotor rhythms following transection of SCN efferents. Animals with cuts that failed to sever SCN efferents, and sham-operated animals (in which the Halasz knife was lowered but not rotated), also maintained circadian rhythmicity. Hamsters sustaining severe damage to the SCN showed disrupted locomotor activity. In those hamsters that retained circadian locomotor rhythmicity following SCN isolation, gonads failed to regress in DD, demonstrating the absence of an appropriate photoperiodic response. The results suggest a multiplicity of SCN coupling mechanisms in the control of circadian rhythms.     

Increased neuropeptide Y concentrations in the lateral hypothalamic area of the rat after the onset of darkness: possible relevance to the circadian periodicity of feeding behavior

Neuropeptide Y (NPY) is a major hypothalamic peptide which powerfully stimulates feeding when injected into the hypothalamus and is implicated in circadian rhythmicity. To investigate whether NPY is involved in the increased feeding that follows the onset of darkness in rats, NPY levels were measured in discrete hypothalamic areas before and after darkness. Four groups of eight adult female Wistar rats were habituated to a 12:12 hour light:dark cycle, with food presented at the onset of darkness (19.00 hours). One group was sacrificed during the 3 hours before darkness and another in the first 2.5 hours after darkness, with food provided as usual. To distinguish any effects of feeding itself, the study was repeated with two further groups, but food was not provided after darkness. Seven hypothalamic regions were microdissected from slices of fresh brain and acid-extracted for radioimmunoassay of NPY. NPY levels (fmol/microgram protein) were significantly higher (p less than 0.01) in the lateral hypothalamic area (LHA) of the dark-phase group in both studies. In the other six regions, NPY levels did not differ between light and dark phases. The LHA regulates the circadian rhythmicity of feeding and NPY injection here stimulates feeding. Alterations in NPY in the LHA around the onset of darkness may be related to the initiation of dark-phase feeding.     

Food ingestion and circadian rhythmicity

Feeding is organised within the 24-h of the light - dark (LD) cycle. Food is ingested in a circadian manner in nature and in laboratory animals kept under constant conditions. The circadian rhythmicity in food ingestion is driven by a biological clock located in the suprachiasmatic nuclei (SCN) of the hypothalamus. The circadian organisation of food ingestion not only allows animals to live in harmony with their environment but food intake could also act as a zeitgeber for other rhythmic functions. Lesions in the area of the SCN result in the loss of most rhythmic functions as well as to a disrupted circadian rhythmicity of food and water intake. These findings, together with observations from daytime feeding experiments conducted in nocturnal animals, suggest that food intake may serve as a temporal signal for some peripheral organs to oscillate in phase with the SCN. This paper overviews and discusses how food intake interacts with the circadian system.     

Light-dependent induction of cFos during subjective day and night in PACAP-containing ganglion cells of the retinohypothalamic tract.

Environmental light stimulation via the retinohypothalamic tract (RHT) is necessary for stable entrainment of circadian rhythms generated in the suprachiasmatic nucleus (SCN). In the current report, the authors characterized the functional activity and phenotype of retinal ganglion cells that give rise to the RHT of the rat. Retinal ganglion cells that give rise to the RHT were identified by transsynaptic passage of an attenuated alpha herpesvirus known to have selective affinity for this pathway. Dual labeling immunocytochemistry demonstrated co-localization of viral antigen and pituitary adenylate cyclase activating polypeptide (PACAP) in retinal ganglion cells. This was confirmed using the anterograde tracer cholera toxin subunit B (ChB). In normal and retinally degenerated monosodium glutamate (MSG)-treated rats, ChB co-localized with PACAP in axons of the retinorecipient zone of the SCN. Light-induced Fos-immunoreactivity (Fos-IR) was apparent in all PACAP-containing retinal ganglion cells and a population of non-PACAP-containing retinal ganglion cells at dawn of normal and MSG-treated animals. Within the next 3 h, Fos disappeared in all non-PACAP-immunoreactive cells but persisted in all PACAP-containing retinal ganglion cells until dusk. When animals were exposed to constant light, Fos-IR was sustained only in the PACAP-immunoreactive (PACAP-IR) retinal ganglion cells. Darkness eliminated Fos-IR in all PACAP-IR retinal ganglion cells, demonstrating that the induction of Fos gene expression was light dependent. When animals were maintained in constant darkness and exposed to light pulses at ZT 14, ZT 19, or ZT 6, Fos-IR was induced in PACAP-IR retinal ganglion cells in a pattern similar to that seen at dawn. Collectively, these data indicate that PACAP is present in ganglion cells that give rise to the RHT and suggest a role for this peptide in the light entrainment of the clock.     

Circadian rhythmicity in dopamine content of mammalian retina: role of the photoreceptors

Dopamine, the predominant retinal catecholamine, is a neurotransmitter and neuromodulator known to regulate light-adaptive retinal processes. Because dopamine influences several rhythmic events in the retina it is also a candidate for a retinal circadian signal. Using high performance liquid chromatography (HPLC), we have tested whether dopamine and its breakdown products are rhythmic in Royal College of Surgeons (RCS) rats with normal and dystrophic retinas. In both normal and mutant animals entrained to a 12-h light/12-h dark cycle, we found robust daily rhythms of dopamine and its two major metabolites. To address circadian rhythmicity of dopamine content, rats were entrained to light/dark cycles and released into constant darkness, using the circadian rhythm of wheel-running activity as a marker of each individual's circadian phase. Circadian rhythms of dopamine and metabolite content persisted in both wild type and retinally degenerate animals held for two weeks in constant darkness. Our results demonstrate for the first time clear circadian rhythms of dopamine content and turnover in a free-running mammal, and suggest that rods and cones are not required for dopamine rhythmicity.     

Emergence of circadian and photoperiodic system level properties from interactions among pacemaker cells

Daily patterns of behavior and physiology in animals in temperate zones often differ substantially between summer and winter. In mammals, this may be a direct consequence of seasonal changes of activity of the suprachiasmatic nucleus (SCN). The purpose of this study was to understand such variation on the basis of the interaction between pacemaker neurons. Computer simulation demonstrates that mutual electrical activation between pacemaker cells in the SCN, in combination with cellular electrical activation by light, is sufficient to explain a variety of circadian phenomena including seasonal changes. These phenomena are: self-excitation, that is, spontaneous development of circadian rhythmicity in the absence of a light-dark cycle; persistent rhythmicity in constant darkness, and loss of circadian rhythmicity in pacemaker output in constant light; entrainment to light-dark cycles; aftereffects of zeitgeber cycles with different periods; adjustment of the circadian patterns to day length; generation of realistic phase response curves to light pulses; and relative independence from day-to-day variation in light intensity. In the model, subsets of cells turn out to be active at specific times of day. This is of functional importance for the exploitation of the SCN to tune specific behavior to specific times of day. Thus, a network of on-off oscillators provides a simple and plausible construct that behaves as a clock with readout for time of day and simultaneously as a clock for all seasons.     

Circadian Locomotor Activity Rhythms in the African Clawed Frog, Xenopus laevis: The Role of the Eye and the Hypothalamus

The effects of hypothalamic lesioning and removal of the eyes on locomotor activity rhythms of African clawed frog, Xenopus laevis were examined under light-dark cycles (LD12:12) and constant conditions. Frogs were kept individually and the activity rhythms at the bottom layer of water tank were recorded by means of the infrared photocells. Intact frogs displayed clear entrained nocturnal activity and expressed freerunning activity rhythms in constant darkness (DD), while some frogs did not freerun under co nstant dim light (dimLL) and constant light (LL). Freerunning periods in intact frogs were significantly shorter in dimLL than in DD. Although freerunning periods were shortened after blinding in same individuals, no significant changes in the freerunning periods were observed after blinding under dimLL and LL. When electrolytic lesions to the hypothalamus were performed, all frogs with more than 70% damage of the SCN abolished freerunning rhythms and in frogs with less than 70% damage, 57% of the animals became arrhythmic. In conclusion, (1) There is a circadian pacemaker somewhere outside the eyes, and it is probably situated in the hypothalamusincluding the SCN. (2) Both the eyes and the SCN are involved in the circadian system of the frogs.     

Circadian Locomotor Activity Rhythms in the African Clawed Frog,Xenopus laevis: The Role of the Eye and the Hypothalamus

The effects of hypothalamic lesioning and removal of the eyes on locomotor activity rhythms of African clawed frog, Xenopus laevis were examined under light-dark cycles (LD12:12) and constant conditions. Frogs were kept individually and the activity rhythms at the bottom layer of water tank were recorded by means of the infrared photocells. Intact frogs displayed clear entrained nocturnal activity and expressed freerunning activity rhythms in constant darkness (DD), while some frogs did not freerun under co nstant dim light (dimLL) and constant light (LL). Freerunning periods in intact frogs were significantly shorter in dimLL than in DD. Although freerunning periods were shortened after blinding in same individuals, no significant changes in the freerunning periods were observed after blinding under dimLL and LL. When electrolytic lesions to the hypothalamus were performed, all frogs with more than 70% damage of the SCN abolished freerunning rhythms and in frogs with less than 70% damage, 57% of the animals became arrhythmic. In conclusion, (1) There is a circadian pacemaker somewhere outside the eyes, and it is probably situated in the hypothalamusincluding the SCN. (2) Both the eyes and the SCN are involved in the circadian system of the frogs.     

Assembling a clock for all seasons: are there M and E oscillators in the genes?

The hypothesis is advanced that the circadian pacemaker in the mammalian suprachiasmatic nucleus (SCN) is composed at the molecular level of a nonredundant double complex of circadian genes (per1, cry1, and per2, cry2). Each one of these sets would be sufficient for the maintenance of endogenous rhythmicity and thus constitute an oscillator. Each would have slightly different temporal dynamics and light responses. The per1/cry1 oscillator is accelerated by light and decelerated by darkness and thereby tracks dawn when day length changes. The per2 /cry2 oscillator is decelerated by light and accelerated by darkness and thereby tracks dusk. These M (morning) and E (evening) oscillators would give rise to the SCN's neuronal activity in an M and an E component. Suppression of behavioral activity by SCN activity in nocturnal mammals would give rise to adaptive tuning of the endogenous behavioral program to day length. The proposition-which is a specification of Pittendrigh and Daan's E-M oscillator model-yields specific nonintuitive predictions amenable to experimental testing in animals with mutations of circadian genes.     

Aging alters circadian and light-induced expression of clock genes in golden hamsters

Aging alters numerous aspects of circadian biology, including the amplitude of rhythms generated by the suprachiasmatic nuclei (SCN) of the hypothalamus, the site of the central circadian pacemaker in mammals, and the response of the pacemaker to environmental stimuli such as light. Although previous studies have described molecular correlates of these behavioral changes, to date only 1 study in rats has attempted to determine if there are age-related changes in the expression of genes that comprise the circadian clock itself. We used in situ hybridization to examine the effects of age on the circadian pattern of expression of a subset of the genes that comprise the molecular machinery of the circadian clock in golden hamsters. Here we report that age alters the 24-h expression profile of Clock and its binding partner Bmal1 in the hamster SCN. There is no effect of age on the 24-h profile of either Per1 or Per2 when hamsters are housed in constant darkness. We also found that light pulses, which induce smaller phase shifts in old animals than in young, lead to decreased induction of Per1, but not of Per2, in the SCN of old hamsters.     

Circadian organization in the ruin lizard Podarcis sicula: the role of the suprachiasmatic nuclei of the hypothalamus

The effects of electrolytic lesions to the suprachiasmatic nuclei of the hypothalamus (SCN) on circadian rhythms of locomotor activity were examined in ruin lizards Podarcis sicula maintained in constant darkness and constant temperature (29°C). All lizards (N=15) in which the lesion damaged 80% or more of the SCN became behaviorally arrhythmic. On the contrary, locomotor rhythms persisted in all cases (N=11) when the SCN remained intact and lesions were confined to neighbouring regions of the preoptic area. Taken together with previous work which demonstrates that the pineal and the retinae are not essential for the persistence of circadian locomotor rhythmicity in Podarcis sicula and with recent evidence showing the homology between the SCN of lizards and those of mammals the present results strongly support the view that the SCN of Podarcis sicula contain the primary pacemaker(s) for locomotor rhythms.Abbreviations DD constant darkness - LL constant light - SCN suprachiasmatic nuclei of the hypothalamus - PH nucleus periventricularis hypothalami - OC optic chiasm - te length of circadian activity - freerunning circadian period     

RHYTHMIC cFOS EXPRESSION IN THE VENTRAL SUBPARAVENTRICULAR ZONE INFLUENCES GENERAL ACTIVITY RHYTHMS IN THE NILE GRASS RAT,ARVICANTHIS NILOTICUS

Circadian rhythms in behavior and physiology are very different in diurnal and nocturnal rodents. A pacemaker located in the suprachiasmatic nucleus (SCN) of the hypothalamus is responsible for generating and maintaining circadian rhythms in mammals, and cellular and molecular rhythms within the SCN of diurnal and nocturnal rodents are very similar. The neural substrates determining whether an animal has a diurnal or nocturnal phase preference are thus likely to reside downstream of the SCN. The ventral subparaventricular zone (vSPVZ), a major target of the SCN that is important for the expression of circadian rhythmicity in nocturnal lab rats (Rattus norvegicus), exhibits different rhythms in cFos expression in diurnal Nile grass rats compared to lab rats. We examined the effects of chemotoxic lesions of the cFos-expressing cells of the vSPVZ on activity rhythms of grass rats to evaluate the hypothesis that these cells support diurnality in this species. Male grass rats housed in a 12:12 light:dark (LD) cycle were given bilateral injections of the neurotoxin n-methyl-D-L-aspartic acid (NMA) or vehicle aimed at the vSPVZ; cells in the SCN are resistant to NMA, which kills neurons in other brain regions, but leaves fibers of passage intact. vSPVZ-damaged grass rats exhibited highly unstable patterns of activity in constant darkness (DD) and in the LD cycle that followed. However, crepuscular bouts of activity could be seen in all animals with vSPVZ lesions. Damage to the vSPVZ reduced cFos expression in this area but not in the SCN. Using correlational analyses, we found that the number of cFos-ir cells in the vSPVZ was unrelated to several parameters of the activity rhythms during the initial post-surgical period, when animals were in LD. However, the number of cells expressing cFos in the vSPVZ was positively correlated with general activity during the subjective day relative to the subjective night when the animals were switched to DD, and this pattern persisted when a LD cycle was reinstated. Also, the number of cFos-ir cells in the vSPVZ was negatively correlated with the strength of rhythmicity in DD and the number of days required to re-entrain to a LD cycle following several weeks in DD. These data suggest that the vSPVZ emits signals important for the expression of stable diurnal activity patterns in grass rats, and that species differences in these signals may contribute to differences in behavioral and physiological rhythms of diurnal and nocturnal mammals. (Author correspondence: mschw009@umaryland.edu)     

Hypothalamic circadian organization in birds. I. Anatomy,functional morphology,and terminology of the suprachiasmatic region

In mammals, the “master clock” controlling circadian rhythmicity is located in the hypothalamic suprachiasmatic nuclei (SCN). Until now, no comparable structure has been unambiguously described in the brain of any nonmammalian vertebrate. In birds, early anatomical and lesioning studies described a SCN located in the anterior hypothalamus, but whether birds possess a nucleus equivalent to the mammalian SCN remained controversial. By reviewing the existing literature it became evident that confusion in delineation and nomenclature of hypothalamic cell groups may be one of the major reasons that no coherent picture of the avian hypothalamus exists. In this review, we attempt to clarify certain aspects of the organization of the avian hypothalamus by summarizing anatomical and functional studies and comparing them to immunocytochemical results from our laboratory. There is no single cell group in the avian hypothalamus that combines the morphological and neurochemical features of the mammalian SCN. Instead, certain aspects of anatomy and morphology suggest that at least two anatomically distinct cell groups, the SCN and the lateral hypothalamic nucleus (LHN), bear some of the characteristics of the mammalian SCN.