Regular firing patterns of suprachiasmatic neurons maintained in vitro

Fast regular firings induced by intra- and inter-time delays in two clustered neuronal networks

In this paper, we consider two clustered neuronal networks with dense intra-synaptic links within each cluster and sparse inter-synaptic links between them. We focus on the effects of intra- and inter-time delays on the spiking regularity and timing in both clusters. With the aid of simulation results, we show that intermediate intra- and inter-time delays are able to separately induce fast regular firing - spiking activity with a high firing rate as well as a high spiking regularity. Moreover, when both intra- and inter-time delays are present, we find that fast regular firings are induced much more frequently than if only a single type of delay is present in the system. Our results indicate that appropriately adjusted intra- and inter-time delays can significantly facilitate fast regular firing in neuronal networks. Based on a detailed analysis, we conjecture that this is most likely when the largest value of common divisors of the intra- and inter-time delays falls into a range where fast regular firings are induced by suitable intra- or inter-time delays alone.

Effects of 17beta-estradiol on neuronal cell excitability and neurotransmission in the suprachiasmatic nucleus of rat

17beta-Estradiol receptors have been found in several brain nuclei including the suprachiasmatic nucleus (SCN) of mammalian species. The SCN is believed to act as brain clock regulating circadian and circannual biological rhythms, such as body temperature, sleep, and mood. Here, we examined whether 17beta-estradiol (E2) could affect cell excitability and synaptic transmission in the SCN. Bath application of E2 (0.03-3 microM) increased the spontaneous firing frequency and depolarized cell membrane of the SCN neurons significantly. Furthermore, E2 (0.03-3 microM) increased (by about 25-150% of control) frequency of the miniature excitatory postsynaptic currents. Amplitude of the evoked excitatory postsynaptic currents was enhanced (by about 32% of control) after exposure to 1 microM E2. The paired-pulse ratio was reduced by E2. These effects were prevented by the estrogen receptor antagonist, ICI 182780. Exposure to the biologically inactive 17alpha-estradiol did not cause any significant changes in the parameters mentioned above. These findings are in favor of an implication of estrogen in modulation of neuronal activity in SCN and possibly regulating circadian rhythms.

Ryanodine receptor Ca2+-release channels are an output pathway for the circadian clock in the rat suprachiasmatic nuclei

Ryanodine-sensitive intracellular Ca2+ channels (RyRs) are present in suprachiasmatic nuclei (SCN) neurons, but the functions served by these channels are not known. Here we addressed whether mobilization of intracellular Ca2+ stores through the RyRs may be a link between the molecular clock and the firing rate in SCN neurons. Activation of the RyRs by administration of either 1 mM caffeine or 100 nM ryanodine increased the firing frequency, whereas inhibition of RyRs by 10 microM dantrolene or 80 microm ryanodine decreased firing rate. Similar results were obtained in experiments conducted at either midday or midnight. Furthermore, these effects were not mediated by synaptic transmission as blockade of GABA A, AMPA and NMDA receptors did not prevent the excitatory or inhibitory effects induced by either dose of ryanodine on SCN firing. We conclude that gating of RyRs is a key element of the intricate output pathway from the circadian clock within SCN neurons in rats.

Electrophysiology of the suprachiasmatic circadian clock

In mammals, an internal timekeeping mechanism located in the suprachiasmatic nuclei (SCN) orchestrates a diverse array of neuroendocrine and physiological parameters to anticipate the cyclical environmental fluctuations that occur every solar day. Electrophysiological recording techniques have proved invaluable in shaping our understanding of how this endogenous clock becomes synchronized to salient environmental cues and appropriately coordinates the timing of a multitude of physiological rhythms in other areas of the brain and body. In this review we discuss the pioneering studies that have shaped our understanding of how this biological pacemaker functions, from input to output. Further, we highlight insights from new studies indicating that, more than just reflecting its oscillatory output, electrical activity within individual clock cells is a vital part of SCN clockwork itself.

In vitro extracellular recording of spontaneous activity of the intergeniculate leaflet neurons

In the view of importance of intergeniculate leaflet in circadian rhythms processes and lack of information about electrophysiological properties of isolated intergeniculate leaflet (IGL) neurons, we carried out extracellular recordings of the spontaneous activity of rat IGL cells in vitro. Unlike other structures of visual thalamus, IGL neurons have the ability to generate a robust spontaneous neuronal activity when maintained in vitro. We have observed that in a standard incubation fluid IGL neurons display at least three distinct firing patterns: continuously irregular-with a wide variety of firing rates, tonic-with a very stable level of activity, and phasic (slow bursts)-with intermittent silent periods. Our study is the first electrophysiological demonstration of IGL neuronal activity in vitro.

Mechanism of Irregular Firing of Suprachiasmatic Nucleus Neurons in Rat Hypothalamic Slices

The mechanisms of irregular firing of spontaneous action potentials in neurons from the rat suprachiasmatic nucleus (SCN) were studied in hypothalamic slices using cell-attached and whole cell recording. The firing pattern of spontaneous action potentials could be divided into regular and irregular, based on the interspike interval (ISI) histogram and the membrane potential trajectory between action potentials. Similar to previous studies, regular neurons had a firing rate about >3.5 Hz and irregular neurons typically fired about <3.5 Hz. The ISI of irregular-firing neurons was a linear function of the sum of inhibitory postsynaptic potentials (IPSPs) between action potentials. Bicuculline (10–30 μM) suppressed IPSPs and converted an irregular pattern to a more regular firing. Bicuculline also depolarized SCN neurons and induced bursting-like activity in some SCN neurons. Gabazine (20 μM), however, suppressed IPSPs without depolarization, and also converted irregular activity to regular firing. Thus GABAA receptor–mediated IPSPs appear responsible for irregular firing of SCN neurons in hypothalamic slices.

Effect of orexin-A on discharge rate of rat suprachiasmatic nucleus neurons in vitro

The suprachiasmatic nuclei (SCN) constitute the principal pacemaker of the circadian timing system in mammals. The generated rhythm is forwarded mostly through projections to various hypothalamic nuclei. On the other hand, the regulated processes feedback to the SCN. One of the possible feedback pathways is the orexinergic projection from the lateral hypothalamus. Orexins are recently identified neuropeptides with an overall facilitatory effect on waking behaviors. Orexinergic fibers are widely distributed throughout the brain and are also present in the SCN. In this study we examined the effect of orexin-A on the spontaneous activity of rat SCN cell in vitro. Neurons showed 2 different firing pattern (continuous-regular, intermittent-irregular). Orexin-A increased firing rate in both cell types at 10(-8) M concentration, but caused a clear suppression of neuronal activity at 10(-7) M. Continuously firing neurons were less responsive than those firing intermittently. These results show that orexin-A may play a role in the modulation of the circadian pacemaker function. The neuropeptide might exert both direct, postsynaptic effects on SCN neurons and indirect, presynaptic effects on excitatory and inhibitory terminals. The dose-dependent modification of the firing rate indicate that the weight of these factors changes with the concentration of orexin-A.

Responses of neurones of the rat suprachiasmatic nucleus to retinal illumination under photopic and scotopic conditions

1. We have examined the responses of neurones in the suprachiasmatic nuclei (SCN) of the rat to retinal illumination under photopic and scotopic conditions to identify the types of photoreceptor input to these nuclei. 2. The majority of visually responsive SCN neurones studied under dark adaptation received rod input (48 of 52, 92 %). The action spectrum conformed to the sensitivity of rhodopsin, with maximal sensitivity at around 505 nm. 3. When also studied under light adaptation, most visually responsive SCN neurones (20 out of 26, 77 %) responded to input from cones. The action spectra conformed to the spectrum of green cone opsin, with a main sensitivity peak at 510 nm and a significant secondary peak in the near-ultraviolet region of the spectrum. 4. The frequency of spontaneous activity was typically low under scotopic conditions (range 0.2-17.2 Hz) and higher under photopic conditions (range 0.6-40 Hz) for any given neurone. The most common response under scotopic conditions was an 'on-excitation' (32 of 48, 62.5 %), which changed under photopic conditions to an on-excitation followed by a more prominent off-inhibition. 5. Responses also changed due to endogenous ultradian cycles. Depending on the phase, responses could be altogether absent and even reverted from excitation to inhibition on opposite phases of a cycle. Ultradian cycles had a circadian dependence and were most common at around the light phase:dark phase (L:D) and D:L transition points of the circadian cycle. 6. Under photopic conditions, SCN neurones showed rhythmic electrical activity, with a preferred firing interval that had a value between 18 and 39 ms. This rhythmic activity was probably the result of endogenous subthreshold membrane potential oscillations. 7. In conclusion, light acting either via rod or cone pathways could have powerful, opposing actions on SCN neurones. These actions were state dependent. The presence of these neuronal responses suggests a role for rod and cone photoreceptors in SCN function.

Light responsiveness of the suprachiasmatic nucleus: long-term multiunit and single-unit recordings in freely moving rats

The suprachiasmatic nuclei (SCN) of the hypothalamus contain a pacemaker that generates circadian rhythms in many functions. Light is the most important stimulus that synchronizes the circadian pacemaker to the environmental cycle. In this paper we have characterized the baseline neuronal firing patterns of the SCN as well as their response to light in freely moving rats. Multiunit and single-unit recordings showed that SCN neurons increase discharge during daytime and decrease discharge at night. Discharge levels of individual neurons that were followed throughout the circadian cycle appeared in phase with the population and were characterized by low discharge rates (often below 1 Hz), with a twofold increase during the day. The effect of light on the multiunit response was dependent on the duration of light exposure and on light intensity, with light thresholds of approximately 0.1 lux. The light response level showed a strong dependency on time of day, with large responsiveness at night and low responsiveness during day. At both phases of the circadian cycle, the response level could be raised by an increase in light intensity. Single-unit measurements revealed that the time-dependent light response of SCN neurons was present also at the level of single units. The results show that the basic light response characteristics that were observed at the multiunit level result from an integrated response of similarly behaving single units. Research at the single-unit level is therefore a useful approach for investigating the basic principles of photic entrainment.

Hierarchically coupled ultradian oscillators generating robust circadian rhythms

Ensembles of mutually coupled ultradian cellular oscillators have been proposed by a number of authors to explain the generation of circadian rhythms in mammals. Most mathematical models using many coupled oscillators predict that the output period should vary as the square root of the number of participating units, thus being inconsistent with the well-established experimental result that ablation of substantial parts of the suprachiasmatic nuclei (SCN), the main circadian pacemaker in mammals, does not eliminate the overt circadian functions, which show no changes in the phases or periods of the rhythms. From these observations, we have developed a theoretical model that exhibits the robustness of the circadian clock to changes in the number of cells in the SCN, and that is readily adaptable to include the successful features of other known models of circadian regulation, such as the phase response curves and light resetting of the phase.

Neuronal subpopulations in the suprachiasmatic nuclei based on their response to retinal and intergeniculate leaflet stimulation

In order to characterize how suprachiasmatic nuclei (SCN) neurons integrate its visual inputs, extracellular responses from SCN and adjacent hypothalamic neurons were recorded after stimulation of either the retina, the intergeniculate leaflet (IGL) or both simultaneously. Individual stimulation of either structure elicited excitatory or inhibitory responses in 36% of SCN and 20% of non-SCN neurons. Three subpopulations of SCN neurons were found, the first two responding exclusively either to the retina or the IGL, and the third responding to both the retina and the IGL. Simultaneous stimulation of the retina and the IGL induced a change in the firing pattern of some SCN neurons, which suggests modulatory regulation of SCN neuronal activity by synaptic interactions between its visual inputs.

Synaptic input from the retina to the suprachiasmatic nucleus changes with the light-dark cycle in the Syrian hamster

1. Single cell extracellular recordings were made from the suprachiasmatic nucleus (SCN) in urethane-anaesthetized Syrian hamsters at different times of the light-dark cycle. Peristimulus time histograms (PSTHs) were created following stimulation of the optic nerve. 2. Both short-latency (< 50 ms) and long-latency (> 50 ms) excitatory responses were seen. Almost all inhibitory responses had a short latency. 3. A total of 288 SCN neurones were recorded. Taking all types of response together, 55 (36.9%) of the 149 neurones tested in the dark period responded to optic nerve stimulation while only 23 (16.6%) of the 139 neurones tested in the light period responded. The difference between the proportion of all responsive and non-responsive neurones in the dark and light periods was highly significant (P < 0.01, Fisher's exact probability test). The difference in the proportion of excitatory responses was also significant (P < 0.01). 4. During the dark period, the mean spontaneous firing rate (5.00 +/- 0.88 spikes s-1; mean +/- S.E.M., n = 55) of the responsive cells was significantly higher than that of the non-responsive cells (2.65 +/- 0.33 spikes s-1; mean +/- S.E.M., n = 74; P < 0.01; Student's unpaired t test). 5. Injection of APV (20 mM, 2 microliters, I.C.V.; n = 6), an antagonist for the NMDA receptor, or CNQX (10 mM, 2 microliters, I.C.V.; n = 5), an antagonist of the non-NMDA receptor, significantly reduced the responses of all the neurones tested. 6. We conclude that there is daily variation in the firing of SCN neurones in vivo and the variation is restricted to those cells receiving optic nerve inputs. The change in the responsiveness of the SCN to optic nerve stimulation at different times of day suggests that there is a rapidly changing cycle of synaptic function in the SCN. The action of the antagonists suggests that the excitatory retinal projections to the SCN which show this variation are mediated by glutamate and that both NMDA and non-NMDA receptors are involved.

Reentrainment of motor activity and spontaneous neuronal activity in the suprachiasmatic nucleus of Djungarian hamsters

Neurons in the suprachiasmatic nucleus (SCN) of the hypothalamus exhibit a daily rhythm in spontaneous electrical activity. Essentially two methods have been employed to record this circadian rhythm: (1) an in vitro brain slice technique and (2) in vivo multiunit recordings. Reentrainment of a circadian output to a shifted light:dark cycle commonly takes several cycles (depending on the amount of shift) until completed. Such a resetting kinetic has also been shown to be valid for SCN electrical activity if recorded in vivo. In an in vitro slice preparation, however, pharmacologically induced resetting is much faster and lacks transients; that is, a shift is completed within one cycle. This study was designed to probe for the presence of transients in the neuronal activity of the SCN in a brain slice preparation. The authors exposed Djungarian hamsters to an 8-h advanced or delayed light:dark cycle and monitored wheel-running activity during reentrainment. Additional groups of identically treated hamsters were used to record the pattern of spontaneous neuronal activity within the SCN using the brain slice preparation. Neuronal activity exhibited the usual rhythm with high firing rates during the projected day and low firing rates during the projected night. However, following 1 day of exposure to the 8-h advanced light:dark cycle, this rhythm disappeared in 6 of 7 slices. Rhythmicity was still absent following 3 days of exposure to the advanced light:dark cycle (n = 4). By contrast, 3 of 7 slices prepared from hamsters exposed to a delayed light:dark cycle for 3 days exhibited a daily rhythm in electrical activity. Although pharmacological agents reset the in vitro SCN neuronal activity almost instantaneously and in in vivo studies a stable phase relationship to a shifted light:dark cycle occurs gradually over several cycles, the authors did not detect either of these patterns. Such differences in resetting kinetics (e.g., rapid resetting, gradual reentrainment, temporary lack of measurable rhythmicity) may be due to (a) application of a resetting stimulus in vivo versus in vitro, (b) duration of the resetting stimulus, (c) the nature of the resetting stimulus, or (d) the recording technique employed.

Ionic currents in cultured rat suprachiasmatic neurons

Whole-cell voltage-clamp recordings were made from cultured neurons obtained by dissociation of the suprachiasmatic area of rat fetuses. Neurons were held for seven to 14 days in culture. These neurons possessed several voltage-dependent ionic currents. A transient inward Na+ current was present, which could be completely blocked by tetrodotoxin. No inward Ca2+ currents were detected. Three types of outward K+ currents were recorded, which could be separated to a reasonable extent by their differences in voltage sensitivity and pharmacology. These K+ currents corresponded to the transient current IA, the delayed rectifier current IKo and a calcium-dependent current IK(Ca) as described in other neurons. The A current activated at -50 mV, reached half-maximal conductance at about -30 mV and maximum conductance between 0 and 30 mV. During depolarizing steps it inactivated completely within 100 ms and steady-state inactivation was half-maximal at -66 mV. The outward rectifier activated at -30 mV, reached half-maximal conductance close to 0 mV and maximum conductance at about 70 mV. Slow inactivation of IKo occurred with 50% reduction in amplitude at the end of 2 s depolarizations above 0 mV. The K+ channel blocker 4-amino-pyridine (4 mM) reduced the amplitude of IA by 21% and of IKo by 32%, whereas tetraethylammonium (10 mM) decreased IA by 27% and IKo by 83%. The calcium-dependent K+ component was also voltage dependent and was present at voltages more positive than 0 mV. No inward rectifying K+ current was present. Considering its voltage dependence, IA must play a role in determining the excitability of these neurons, through its probable influence on the action potential threshold and interspike interval. Both IA and IKo should take part in membrane repolarization following an action potential. The Ca(2+)-dependent current should also contribute to repolarization following any event which gives rise to an increase in intracellular Ca2+. Apart from IA, which may make a slight contribution, none of these currents appear to be involved in determining the resting membrane potential. All three outward current components will act together in suprachiasmatic neurons to control their spontaneous firing frequency, which is the major feature of the output of these neurons in vivo. Variations in properties of these conductances could contribute to the circadian rhythm in firing frequency described in suprachiasmatic hypothalamic neurons.

Ionophoretically applied substance P activates hamster suprachiasmatic nucleus neurons

ionophoretic ejection of substance P (SP) activated 31% and suppressed 9% of hamster suprachiasmatic nucleus (SCN) cells in vitro. Hamster SCN cells did not demonstrate variation in sensitivity to SP across the circadian phases tested. SP modulated the response of 47% of hamster SCN cells to the excitatory amino acid (EAA) agonists glutamate and N-methyl-D-aspartate (NMDA). The results indicate that SP can alter both the spontaneous and EAA-evoked firing rate characteristics of hamster SCN neurons.

Rhythmic firing patterns in suprachiasmatic nucleus (SCN): the rôle of circuit interactions

The suprachiasmatic nucleus (SCN) is believed to contain the main generator of circadian rhythmicity in mammals. In order to obtain further functional details of this, electrophysiological extracellular measurements in vitro were made. By means of an interspike interval distribution analysis, it is shown that there is a novel kind of neuronal firing pattern: the harmonic pattern. From these observations, we have developed a theoretical model based on possible filtering processes occurring during synaptic transmission. The model suffices to infer that regular ultradian oscillators could be an emergent property of circuit interactions of cells in the suprachiasmatic nucleus.

Inward rectifier and low-threshold calcium currents contribute to the spontaneous firing mechanism in neurons of the rat suprachiasmatic nucleus

Intracellular and voltage-clamp studies were carried out to clarify the mechanism for spontaneous firing activity in neurons of the suprachiasmatic nucleus (SCN) of rat hypothalamic brain slices in vitro. SCN neurons displayed spontaneously firing action potentials that were preceded by a depolarizing pre-potential and followed by a short spike after-hyperpolarization (AHP). Injection of inward current with a duration longer than 50 ms resulted in a depolarizing voltage "sag" on hyperpolarizing electrotonic potentials. The inward rectification was depressed by bath application of caesium (1 mM) but not by barium (500 microM). SCN neurons also showed a rebound depolarization associated with spike discharge (anodal break) in response to relaxation of hyper polarizing current injection. The rebound depolarization was reduced by nominally zero calcium. Cadmium (500 microM), cobalt (1 mM) or caesium (1 mM) but not nicardipine also depressed the rebound depolarization. Under voltage-clamp conditions, hyperpolarizing steps to membrane potentials negative to approximately -60 mV caused an inward rectifier current, probably H current (IH), which showed no inactivation with time. Bath application of caesium (1-2 mM) suppressed IH. Caesium (2 mM) depressed the slope of the depolarizing spike pre-potential, resulting in a prolongation of the interspike interval of tonic firing neurons. We conclude that both the inward rectifier current, IH, and the low-threshold calcium current contribute to the spike prepotential of spontaneous action potentials in firing neurons of the rat SCN.

Regulation of melatonin-sensitivity and firing-rate rhythms of hamster suprachiasmatic nucleus neurons: constant light effects

Rhythms of spontaneous firing rate and of responsiveness to pressure ejection of melatonin were recorded from neurons in the Syrian hamster suprachiasmatic nuclei (SCN) in a slice preparation. In animals taken from light-dark cycles (LD 14:10), SCN cells had high firing rates during the projected day and lower rates during the projected night. The proportion of melatonin-suppressed cells (35% overall) was also high during the day and fell during the night, while melatonin activated approximately 23% of cells at all phases. To assess the source of the melatonin-responsiveness rhythm, hamsters were exposed for approximately 48 h to constant illumination (LL) to suppress melatonin secretion. LL exposure before slice preparation altered both firing-rate and melatonin-responsiveness rhythms. Firing rates failed to show a morning peak and remained at low levels, with no indication of daily rhythmicity. Melatonin responsiveness also failed to show the usual rhythm and even tended to rise at night. Overall melatonin responsiveness rose after LL exposure so that 50% of cells were suppressed and 21% activated. LL exposure also increased the proportions of cells which showed regular baseline firing rates. Control studies indicated that pressure artifacts did not account for either suppression or activation by melatonin, while the composition of the saline vehicle appeared to be responsible for the activations recorded. The results indicate that brief LL exposure alters SCN sensitivity to melatonin and SCN rhythmicity in Syrian hamsters, perhaps as a result of the loss of the daily melatonin secretion rhythm. Physiological melatonin patterns may have important effects on the rodent circadian pacemaker.

Spontaneous and stimulated firing in cultured rat suprachiasmatic neurons

Neurons from the suprachiasmatic nucleus (SCN) of the hypothalamus, the site of a circadian pacemaker in mammals, were isolated from embryonic rat. After mechanical dissociation neurons were brought into culture for 1-2 weeks, using a chemically defined medium. Recordings were made from 74 bipolar neurons using two different configurations of the patch-clamp technique. During cell attached patch recordings, 45% of neurons fired spontaneously. The mean firing rate was 0.7 +/- 0.6 Hz and the firing pattern was irregular. In whole cell recordings 73% of the investigated neurons showed spontaneous activity with an irregular firing pattern. The mean spontaneous firing rate with an intracellular Cl- concentration of 145 mM was 1.0 +/- 0.6 Hz. The resting membrane potential of the bipolar neurons was estimated to be -62 +/- 24 mV. An intracellular Cl- concentration of 145 mM depolarised the membrane potential. It also increased the probability of spontaneous firing. A depolarising current stimulus produced an action potential with a threshold voltage of -46 +/- 9 mV. Suprathreshold stimuli resulted in repetitive firing with a mean frequency of 12 +/- 4 Hz. The minimum interspike interval was 52 +/- 14 ms. All action potentials either occurring spontaneously or elicited by current stimuli were abolished by the Na(+)-channel blocker TTX. These results indicate that our cultured neurons have some electrophysiological properties in common with SCN neurons in brain slices and in vivo.

The effects of continuous light exposure on Syrian hamster suprachiasmatic (SCN) neuronal discharge activity in vitro

The circadian variation in neuronal discharge activity recorded in vitro from the Syrian hamster suprachiasmatic nucleus (SCN), identified as a circadian clock, was used as an index of SCN circadian function. SCN neurones (n = 89) following in vitro commissural section of the paired SCN showed a similar peak in spontaneous discharge activity during the projected light phase (between CT 06.00 and 08.00 h) as the commissural intact LD 12:12 preparations (n = 230 neurones). Long-term exposure to continuous lighting (LL) may induce either arrhythmicity or splitting of locomotor behaviour. Circadian variation in SCN discharge activity was absent in hamsters (44 cells, 6 animals) showing LL-induced arrhythmicity. In 4 hamsters exhibiting split free-running behaviour two peaks in SCN discharge activity (n = 32 cells) were observed. Fifteen LL free-running animals showed no evidence of splitting or arrhythmicity and subsequent SCN recordings revealed only a single peak in SCN discharge activity. These LL-induced changes in overt circadian behaviour appeared paralleled by changes in neuronal discharge activity of the SCN circadian clock and support the view that the paired SCN act as a mutually coupled circadian oscillator.

Dual effect of glycine on isolated rat suprachiasmatic neurons

Pharmacological properties of strychnine-sensitive and -insensitive glycine receptors have been investigated in rat suprachiasmatic nucleus (SCN) neurons. Because the SCN neurons were too small for stable intracellular recordings by the glass-microelectrode technique, a conventional whole cell mode patch-clamp technique was employed on the acutely dissociated SCN neurons. Dissociated SCN neurons were morphologically heterogeneous and could be distinguished into several types. All cells responded to glycine in a concentration-dependent manner. The glycine-induced current was primarily Cl- sensitive and competitively blocked by strychnine. The SCN neurons also responded to excitatory amino acids: glutamate, quisqualate, kainate, and N-methyl-D-aspartate (NMDA). Responses to glutamate and aspartate, which are endogenous neurotransmitter candidates, were enhanced by adding glycine. Glycine especially augmented the maximum response to NMDA in a full concentration range. 6-Cyano-7-nitroquinoxaline-2,3-dione (CNQX) did not suppress the strychnine-sensitive glycine response but did suppress the strychnine-insensitive NMDA response in a competitive manner for glycine. The results suggest that glycine influences neural activity in the SCN as a classical inhibitory neurotransmitter and an excitatory neuromodulator.

Factors affecting slow regular firing in the suprachiasmatic nucleus in vitro

In isolated slices of hypothalamus, suprachiasmatic nucleus (SCN) neurons were recorded intracellularly. Blockade of Ca++ channels increased spike duration, eliminating an early component of the afterhyperpolarization (AHP) that followed evoked spikes. The duration and reversal potential of AHPs were, however, unaffected, suggesting that only an early, fast component of the AHP was Ca(++)-dependent. Unlike other central neurons that exhibit pacemaker activity, therefore, SCN neurons do not display a pronounced, long-lasting Ca(++)-dependent AHP. Extracellular Ba++ and intracellular Cs+ both revealed slow depolarizing potentials evoked either by depolarizing current injection, or by repolarization following large hyperpolarizations. They had different effects on the shape of spikes and the AHPs that followed them, however. Cs+, which blocks almost all K+ channels, dramatically reduced resting potential, greatly increased spike duration (to tens of milliseconds), and blocked AHPs completely. In contrast, Ba++ had little effect on resting potential and produced only a small increase in spike duration, depressing an early Ca(++)-dependent component and a later Ca(++)-independent component of the AHP. The relatively weak pacemaker activity of SCN neurons appears to involve voltage-dependent activation of at least one slowly inactivating inward current, which brings the cells to firing threshold and maintains tonic firing; both Ca(++)-dependent and Ca(++)-independent K+ channels, which repolarize cells after spikes and maintain interspike intervals; and Ca++ channels, which contribute to activation of Ca(++)-activated K+ currents and may also contribute to slow depolarizing potentials. In the absence of powerful synaptic inputs, SCN neurons express a pacemaker activity that is sufficient to maintain an impressively regular firing pattern. Slow, repetitive activation of optic input, however, increases local circuit activity to such an extent that the normal pacemaker potentials are overridden and firing patterns are altered. Since SCN neurons are very small and have large input resistances, they are particularly susceptible to synaptic input.

Activity of suprachiasmatic and hypothalamic neurons during sleep and wakefulness in the rat

Single unit activity was recorded from the suprachiasmatic nucleus (SCN) and preoptic/anterior hypothalamus (POAH) of unrestrained Wistar rats during sleep and wakefulness. Regularly firing cells, which are abundant in in vitro SCN preparations and have been considered the basis of a central neuronal oscillator, were conspicuously absent in this preparation and in other in vivo studies. Most of the 55 cells recorded in the SCN and POAH were characterized by spontaneous firing rates below 12 Hz and with heterogeneous patterns of changes in frequency with arousal states. In vivo neurophysiological studies of the SCN in which the anesthetic agent urethane is used should consider the effect of different levels of arousal, as indicated by the cortical EEG, in evaluating the relationship between sensory stimulation and single unit activity.