Michael N. Lehman

The suprachiasmatic nucleus and the circadian time-keeping system revisited.

Many physiological and behavioral processes show circadian rhythms which are generated by an internal time-keeping system, the biological clock. In rodents, evidence from a variety of studies has shown the suprachiasmatic nucleus (SCN) to be the site of the master pacemaker controlling circadian rhythms. The clock of the SCN oscillates with a near 24-h period but is entrained to solar day/night rhythm by light. Much progress has been made recently in understanding the mechanisms of the circadian system of the SCN, its inputs for entrainment and its outputs for transfer of the rhythm to the rest of the brain. The present review summarizes these new developments concerning the properties of the SCN and the mechanisms of circadian time-keeping. First, we will summarize data concerning the anatomical and physiological organization of the SCN, including the roles of SCN neuropeptide/neurotransmitter systems, and our current knowledge of SCN input and output pathways. Second, we will discuss SCN transplantation studies and how they have contributed to knowledge of the intrinsic properties of the SCN, communication between the SCN and its targets, and age-related changes in the circadian system. Third, recent findings concerning the genes and molecules involved in the intrinsic pacemaker mechanisms of insect and mammalian clocks will be reviewed. Finally, we will discuss exciting new possibilities concerning the use of viral vector-mediated gene transfer as an approach to investigate mechanisms of circadian time-keeping.

Coexpression of opsin- and VIP-like-immunoreactivity in CSF-contacting neurons of the avian brain

SummaryCerebrospinal fluid-contacting (CSF) cells in both the septal and the tuberal areas in the brain of the ring dove are labeled by RET-P1, a monoclonal antibody to opsin that reacts with inner and outer segment membranes of rod photoreceptors in a variety of vertebrates. Immunoblot analysis of proteins from diverse brain regions, however, revealed bands of anti-RET-P1 immunoreactivity that did not correspond to opsin. Binding of RET-P1 to opsin-containing membranes, was not inhibited by membranes rich in muscarinic and β-adrenergic receptor proteins (red blood cells, heart, lung) taken from doves. RET-P1-immunoreactive CSF-contacting cells emit a dendritic process that penetrates the ependyma and ends in a knob-like terminal suspended in the ventricle. These cells also possess other processes that penetrate more or less deeply into the neuropil. Additionally, a band of labeled fibers occurs in the external layer of the median eminence. A double-label technique demonstrated that RET-P1-positive cells coexpress VIP-like immunoreactivity. VIP-positive cells in other brain areas are not RET-P1-positive.

Suprachiasmatic Regulation of Circadian Rhythms of Gene Expression in Hamster Peripheral Organs: Effects of Transplanting the Pacemaker

Neurotransplantation of the suprachiasmatic nucleus (SCN) was used to assess communication between the central circadian pacemaker and peripheral oscillators in Syrian hamsters. Free-running rhythms of haPer1, haPer2, and Bmal1 expression were documented in liver, kidney, spleen, heart, skeletal muscle, and adrenal medulla after 3 d or 11 weeks of exposure to constant darkness. Ablation of the SCN of heterozygote tau mutants eliminated not only rhythms of locomotor activity but also rhythmic expression of these genes in all peripheral organs studied. The Per:Bmal ratio suggests that this effect was attributable not to asynchronous rhythmicity between SCN-lesioned individuals but to arrhythmicity within individuals. Grafts of wild-type SCN to heterozygous, SCN-lesioned tau mutant hamsters not only restored locomotor rhythms with the period of the donor but also led to recovery of rhythmic expression of haPer1, haPer2, and haBmal1 in liver and kidney. The phase of these rhythms most closely resembled that of intact wild-type hamsters. Rhythmic gene expression was also restored in skeletal muscle, but the phase was altered. Behaviorally effective SCN transplants failed to reinstate rhythms of clock gene expression in heart, spleen, or adrenal medulla. These findings confirm that peripheral organs differ in their response to SCN-dependent cues. Furthermore, the results indicate that conventional models of internal entrainment may need to be revised to explain control of the periphery by the pacemaker.

Molecular Mapping of the Neural Pathways Linking Leptin to the Neuroendocrine Reproductive Axis

Negative energy balance and insufficient adipose energy stores decrease the production of leptin, thereby diminishing the leptin-supported secretion of GnRH from the hypothalamus and promoting decreased reproductive function. Leptin acts via its receptor (LepRb) to support the neuroendocrine reproductive axis, but the nature and location of the relevant LepRb neurons remain poorly understood. Possibilities include the direct or indirect action of leptin on hypothalamic GnRH neurons, or on kisspeptin (Kiss1) neurons that are major regulators of GnRH neurons. To evaluate these potential mechanisms, we employed immunohistochemical analysis of the female brain from various molecular mouse models and sheep. Our analysis revealed no LepRb in GnRH neurons or in anteroventral periventricular Kiss1 neurons, and very limited (0-6%) colocalization with arcuate nucleus Kiss1 cells, suggesting that leptin does not modulate reproduction by direct action on any of these neural populations. LepRb neurons, primarily in the hypothalamic ventral premammillary nucleus and a subregion of the preoptic area, lie in close contact with GnRH neurons, however. Furthermore, an unidentified population or populations of LepRb neurons lie in close contact with arcuate nucleus and anteroventral periventricular Kiss1 neurons. Taken together, these findings suggest that leptin communicates with the neuroendocrine reproductive axis via multiple populations of LepRb neurons that lie afferent to both Kiss1 and GnRH neurons.

The eye is necessary for a circadian rhythm in the suprachiasmatic nucleus.

In mammals, the suprachiasmatic nucleus (SCN) is the site of the pacemaker that is responsible for circadian rhythms in behavior and physiology, and it is currently believed that all rhythms of SCN cells are endogenously driven and independent of extra-SCN tissues. The eye has also been shown to contain an independent circadian oscillator, but the role of the ocular clock and whether it influences the SCN are unknown. Here we found that a rhythm of phosphorylation of mitogen-activated protein (MAP) kinase in an anatomically distinct subdivision of the SCN was completely abolished by bilateral enucleation in hamsters and mice, indicating that the eye is necessary for a circadian rhythm within the SCN.

Dispersed cell suspensions of fetal SCN restore circadian rhythmicity in SCN-lesioned adult hamsters

Overt circadian rhythms are permanently disrupted following lesions of the suprachiasmatic nucleus (SCN) in hamsters. It has previously been demonstrated that whole tissue grafts which include the fetal SCN restore circadian locomotor rhythms to hamsters previously made arrhythmic by SCN lesions. In the present study, we ask whether the intrinsic peptidergic organization of the SCN is a prerequisite for functional recovery of circadian rhythms of locomotor activity. To this end, dispersed cell suspensions of [3H]thymidine-labelled fetal anterior hypothalamic tissue which contains the SCN, were injected stereotaxically into the brain of adult hamsters. Dispersed cell suspensions restored free-running locomotor rhythms, but not entrainment or gonadal regression. The period of the restored free-running rhythms following injections of SCN cell suspensions was shorter than 24 h, in contrast to intact hamsters and SCN-lesioned hamsters whose rhythms are restored by whole tissue grafts. In animals with restored rhythms, a majority of [3H]thymidine-labelled cells were located within nuclei of the midline thalamus and zona incerta. In a few individuals, donor cells were also deposited along the injection tract as far ventrally as the medial hypothalamus. Restoration of free-running locomotor rhythmicity was correlated with the presence of small numbers of isolated VIP cells along with small plexuses of VIP fibers. In animals which did not recover locomotor rhythmicity, grafts were identical in location and size to those in recovered hamsters, but did not contain peptidergic cells characteristic of the SCN. The results suggest that structural integrity of the fetal SCN is not necessary for restoration of rhythmicity after grafting.

Kisspeptin, Neurokinin B, and Dynorphin Act in the Arcuate Nucleus to Control Activity of the GnRH Pulse Generator in Ewes

Recent work has led to the hypothesis that kisspeptin/neurokinin B/dynorphin (KNDy) neurons in the arcuate nucleus play a key role in GnRH pulse generation, with kisspeptin driving GnRH release and neurokinin B (NKB) and dynorphin acting as start and stop signals, respectively. In this study, we tested this hypothesis by determining the actions, if any, of four neurotransmitters found in KNDy neurons (kisspeptin, NKB, dynorphin, and glutamate) on episodic LH secretion using local administration of agonists and antagonists to receptors for these transmitters in ovariectomized ewes. We also obtained evidence that GnRH-containing afferents contact KNDy neurons, so we tested the role of two components of these afferents: GnRH and orphanin-FQ. Microimplants of a Kiss1r antagonist briefly inhibited LH pulses and microinjections of 2 nmol of this antagonist produced a modest transitory decrease in LH pulse frequency. An antagonist to the NKB receptor also decreased LH pulse frequency, whereas NKB and an antagonist to the receptor for dynorphin both increased pulse frequency. In contrast, antagonists to GnRH receptors, orphanin-FQ receptors, and the N-methyl-D-aspartate glutamate receptor had no effect on episodic LH secretion. We thus conclude that the KNDy neuropeptides act in the arcuate nucleus to control episodic GnRH secretion in the ewe, but afferent input from GnRH neurons to this area does not. These data support the proposed roles for NKB and dynorphin within the KNDy neural network and raise the possibility that kisspeptin contributes to the control of GnRH pulse frequency in addition to its established role as an output signal from KNDy neurons that drives GnRH pulses.

Role of the hypothalamic paraventricular nucleus in neuroendocrine responses to daylength in the golden hamster.

Daylength regulates reproduction in golden hamsters through a mechanism which involves the pineal indoleamine, melatonin. Retinal input to the suprachiasmatic nucleus of the hypothalamus (SCN) and sympathetic innervation of the pineal are critical to the inhibition of reproduction by short photoperiods. Since the hypothalamic paraventricular nucleus (PVN) receives extensive input from the SCN in the rat, and may influence autonomic function via its brainstem and spinal cord projections, we studied the role of this nucleus in photoperiodically induced gonadal regression in the hamster. Bilateral electrolytic destruction of either the paraventricular nucleus (PVN) or suprachiasmatic nucleus (SCN) of the hypothalamus completely blocked testicular regression induced by either blinding or exposure to short days (10L:14D). Lesions in the retrochiasmatic hypothalamus (RCA) which may have interrupted the pathway of previously identified efferents from the SCN to the PVN were also effective in preventing short day-induced gonadal regression. Pineal melatonin content was measured in intact and lesioned hamsters sacrificed 3-5 h before lights on, at the time of the expected nocturnal peak. While SCN and RCA lesions significantly reduced pineal melatonin content, PVN lesions were still more effective in this regard. We conclude that the hamsters neuroendocrine response to photoperiod is mediated by neural pathways which include retinohypothalamic input to the SCN and efferents from this nucleus to the PVN which travel dorsocaudally through the retrochiasmatic area of the hypothalamus. Effectiveness of lesions restricted to the PVN suggests that direct projections from the PVN to spinal autonomic centers convey photoperiodic information which regulates pineal, and hence gonadal, function.

Colocalisation of dynorphin A and neurokinin B immunoreactivity in the arcuate nucleus and median eminence of the sheep

Dynorphin A (DYN)‐containing cells play a key role in conveying the negative feedback influence of progesterone upon pulsatile gonadotrophin‐releasing hormone (GnRH) secretion in the ewe. A very high percentage of DYN cells in the arcuate nucleus express the progesterone receptor; another population of arcuate nucleus cells that also express steroid receptors in the sheep are those that express the tachykinin peptide, neurokinin B (NKB). Both DYN and NKB fibres have been shown to form close contacts with ovine GnRH cells. Therefore, the present study tested the hypothesis that neurones expressing NKB and DYN represent the same neuronal population in the arcuate nucleus. Confocal microscopic analysis of brain sections processed for dual immunofluorescence revealed that a large majority of DYN neurones in the arcuate nucleus were also immunoreactive for NKB. Likewise, a similar majority of NKB neurones in the arcuate nucleus were immunoreactive for DYN. By contrast, DYN cells in the preoptic area and anterior hypothalamus did not colocalise with NKB, nor did DYN cells in the paraventricular or supraoptic nuclei. Fibres that stained positively for both DYN and NKB were seen in the arcuate nucleus, where they formed close appositions with DYN/NKB‐positive neurones, and in the external zone of the median eminence. Taken together with previous findings, these data suggest that a subpopulation of arcuate nucleus neurones coexpressing DYN and NKB mediate the negative feedback influence of progesterone on pulsatile GnRH secretion in the ewe and may also be involved in other feedback actions of gonadal steroids.

Multiple regulatory elements result in regional specificity in circadian rhythms of neuropeptide expression in mouse SCN

It is well established that the mammalian circadian system consists of pacemaker cells in the suprachiasmatic nuclei (SCN). The mouse has become increasingly important in understanding the circadian timing system, due to the availability of mutant animals with abnormal circadian rhythms. In the present paper, we describe the organization of the mouse SCN, comparing the wild type and Clock mutant animal, with a special focus on those peptides bearing an upstream E-box element (vasopressin, vasoactive intestinal peptide, cholecystokinin and substance P). To this end, we describe the distribution of the foregoing SCN peptidergic cell types as well as gastrin-related peptide, calretinin, calbindin, somatostatin, neurotensin and retinal input to the SCN (determined by both tract tracing and fos-immunoreactivity in response to a light pulse). The Clock mutant mouse has decreased expression of vasopressin mRNA and protein in the SCN, with normal patterns of expression elsewhere in the brain. No other differences were detected between the Clock mutant and the wild type mouse. The results are consistent with the hypothesis that there are multiple regulatory elements of clock-controlled genes in the SCN.