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Burst-firing activity of presumed 5-HT neurones of the rat dorsal raphe nucleus: Electrophysiological analysis by antidromic stimulation
Abstract
We recently reported raphe neurones which frequently fired spikes in short bursts. However, the action potentials were broad and the neurones fired in a slow and regular pattern, suggesting they were an unusual type of 5-hydroxytryptamine (5-HT) neurone. In the present study, we investigated whether these putative burst-firing 5-HT neurones project to the forebrain and whether all spikes fired in bursts propagate along the axon. In anaesthetised rats, electrical stimulation of the medial forebrain bundle evoked antidromic spikes in both burst-firing neurones and in single-spiking, classical 5-HT neurones recorded in the dorsal raphe nucleus. Although the antidromic spike latency of the single-spiking and burst-firing neurones showed a clear overlap, burst-firing neurones had a significantly shorter latency than single-spiking neurones. For both burst-firing neurones and classical 5-HT neurones, antidromic spikes made collisions with spontaneously occurring spikes. Furthermore, in all burst-firing neurones tested, first, second and third order spikes in a burst could be made to collide with antidromic spike. Interestingly, in a small number of burst-firing neurones, antidromic stimulation evoked spike doublets, similar to those recorded spontaneously. From these data we conclude that burst-firing neurones in the dorsal raphe nucleus project to the forebrain, and each spike generated by the burst propagates along the axon and could thereby release transmitter (5-HT).
... 2). These neurons sometimes discharge in brief bursts of action potentials, mostly doublets and triplets, with a very short interspike time interval (Hajos and Sharp, 1996). The firing activity in bursting mode is believed to increase the amount of 5-HT release for the same number of spikes delivered at regular intervals (Gartside et al., 2000). ...
... The termination of the NE burst was defined as an interspike interval of 0.16 s or longer (Dawe et al., 2001). Burst firing of DRN 5-HT neurons was defined by brief bursts of action potentials, mostly doublets, with a very short interspike time interval (typically < 10 ms; Hajos and Sharp, 1996). ...
... However, the insights provided by these studies to date are limited. These studies have identified effects on 5-HT transmission with only low temporal resolution, that is, on a timescale that is not commensurate with the dynamic changes in firing rates of 5-HT neurons which range from low frequency tonic firing of 0.5-10 Hz to brief, high frequency burst firing of up to 100-200 Hz (Hajos and Sharp 1996;Hajos et al. 2007). If we are to understand the impact of 5-HTT variation on 5-HT function, it is important to appreciate how 5-HT release is influenced dynamically during different physiological firing frequencies. ...
... Strikingly, both a complete loss and large magnitude gain of 5-HTT levels resulted in insensitivity to stimulation frequency. The latter finding is important in the context of evidence that 5-HT neurons spontaneously fire action potentials over a wide range (0.5-200 Hz) of frequencies (Hajos and Sharp 1996;Allers and Sharp 2003;Kocsis et al. 2006;Hajos et al. 2007). ...
J. Neurochem. (2010) 115, 965–973.
Much evidence suggests that variation in expression of the 5-hydroxytryptamine (5-HT) transporter (5-HTT) is linked to risk of psychiatric illness, but the neurobiological basis of this association is uncertain. In this study, we investigated the impact of variation in 5-HTT expression on subsecond fluctuations in extracellular 5-HT concentrations ([5-HT]o). Stimulus-evoked [5-HT]o was detected using fast-scan cyclic voltammetry at carbon-fibre microelectrodes in the substantia nigra in brain slices from 5-HTT knockout (KO) and 5-HTT over-expressing (OE) mice. Compared with wild-type (WT) controls, evoked [5-HT]o was greater in KO and less in OE mice. In WT controls, evoked [5-HT]o was frequency-sensitive; however, in both KO and OE mice, evoked [5-HT]o showed a striking loss of frequency sensitivity. The latter was observed in WT mice after application of a 5-HTT blocker. These data show that while variation in 5-HTT expression modified the peak magnitude of [5-HT]o evoked by any given stimulus in a gene dose dependent manner, there was a non-linear relationship between 5-HTT expression and frequency sensitivity. Overall, the findings suggest that variation in 5-HTT expression has a marked effect on frequency sensitivity which is a fundamental property of normal 5-HT transmission.
... DRN 5-HT cells were identified by their electrophysiological features: a regular discharging pattern, a slow firing rate and a long-lasting biphasic positive–negative waveform (2 ms). Non-5-HT neurons were identified by their electrophysiological properties, such as the fast firing rate, the irregular pattern of firing and the short-lived spike (<2 ms) (Aghajanian and Lakoski, 1984; Hajos and Sharp, 1996). Moreover, pharmacological criteria such as the inhibitory response to bath application of 5-HT (Sigma) (50–100 mM) or the 5-HT 1A receptor agonist ()-8-hydroxy-2-(di-npropylamino ) tetralin hydrobromide (8-OH-DPAT, Sigma) (10 nM) were used to confirm the identity of 5-HT cells (Aghajanian and Lakoski, 1984; Hajos and Sharp, 1996). ...
... Non-5-HT neurons were identified by their electrophysiological properties, such as the fast firing rate, the irregular pattern of firing and the short-lived spike (<2 ms) (Aghajanian and Lakoski, 1984; Hajos and Sharp, 1996). Moreover, pharmacological criteria such as the inhibitory response to bath application of 5-HT (Sigma) (50–100 mM) or the 5-HT 1A receptor agonist ()-8-hydroxy-2-(di-npropylamino ) tetralin hydrobromide (8-OH-DPAT, Sigma) (10 nM) were used to confirm the identity of 5-HT cells (Aghajanian and Lakoski, 1984; Hajos and Sharp, 1996). As both 5-HT and non-5-HT cells have been recently shown to be inhibited by 5-HT1A receptor activation (Kirby et al., 2003; Marinelli et al., 2004), we only considered, as 5-HT neurons, those cells that fulfilled both electrophysiological and pharmacological criteria. ...
Previous studies have suggested a regulation of 5-hydroxytryptamine (5-HT) neurons by the endocannabinoid system. The aim of our work was to examine the effect of two CB(1) receptor antagonists, SR141716A (rimonabant, Sanofi-Synthélabo Recherche, Montpellier, France) and N-(piperidin-1-yl)-5-(4-iodophenyl)-1-(2,4-dichlorophenyl)-4-methyl-1H-pyrazole-3-carboxamide (AM251, Tocris Cookson, Bristol, UK), on the firing rate of dorsal raphe nucleus (DRN) neurons.
Single-unit extracellular recordings were performed to study the effect of CB(1) receptor antagonists in slices of the DRN from rat brain.
Rimonabant (1 microM) and AM251 (1 microM) decreased the firing rate of about 50% of all the recorded DRN 5-HT cells. The GABA(A)receptor antagonist picrotoxin (20 microM) (Sigma) prevented and also reversed the inhibitory effect of rimonabant (1 microM) and AM251 (1 microM), suggesting that CB(1) receptors regulate 5-HT neurons through the GABAergic system. However, the CB(1)/CB(2) receptor agonist R-(+)-[2,3-dihydro-5-methyl-3-[(morpholinyl)-methyl]pyrrolol[1,2,3-de]-1,4-benzoxazinyl]-(1-naphthalenyl) methanone mesylate salt (10 microM) (WIN55212-2, Sigma, St. Louis, MO, USA) failed to change the firing activity of non-5-HT (presumably GABAergic) neurons in the DRN. The endocannabinoid N-(2-hydroxyethyl)-5Z,8Z,11Z,14Z-eicosatetraenamide (anandamide, Tocris Cookson) (10 microM) also inhibited the firing activity of a number of 5-HT neurons, but this inhibition was not blocked by rimonabant (1 microM) or AM251 (1 microM), and the stable analogue R-(+) N-(2-hydroxy-1methylethyl)-5Z,8Z,11Z,14Z-eicosatetraenamide (methanandamide, Tocris Cookson) (10 microM) did not mimic this effect. The selective CB(1) receptor agonist arachidonoyl-2-chloroethylamide (ACEA) (1 microM) only slightly increased the firing rate of DRN 5-HT cells.
These results suggest a tonic/constitutive regulation of DRN 5-HT neurons by the endocannabinoid system, which may occur through a CB(1) receptor-mediated inhibition of the GABAergic system. The inhibitory effect of anandamide may be mediated through a CB(1) receptor-independent mechanism.
... Like classical 5-HT neurons, these burst firing neurons project to the forebrain via the median forebrain bundle. 12,29 Furthermore, it has been found that burst firing raphe neurons respond to a number of pharmacological challenges (e.g. 5-HT 1A agonists) in a manner typical of classical 5-HT neurons, and they are also sensitive to the 5-HT neurotoxin, 5,7-dihydroxytryptamine. 11,16 Taken together, these data suggest that the burst firing neurons in the midbrain raphe nuclei are a subpopulation of 5-HT neurons. ...
... Moreover, we have previously recorded bursting raphe neurons and shown that all spikes within a short burst collide with antidromic spikes evoked by stimulation of the medial forebrain bundle. 12 These data also support the notion that the short bursts propagate along the 5-HT axon. However, given that action potentials are prone to fail at axon branching points, 21 and that 5-HT neurons have extensive arborization in their terminal fields, 31 it is uncertain whether action potentials within bursts will enter the terminal field. ...
We have previously described a population of 5-hydroxytryptamine neurons which repetitively fires bursts of usually two (but occasionally three or four) action potentials, with a short (<20 ms) interspike interval within a regular low-frequency firing pattern. Here we used a paradigm of electrical stimulation comprising twin pulses (with 7- or 10-ms inter-pulse intervals) to mimic this burst firing pattern, and compared the effects of single- and twin-pulse electrical stimulations in models of pre- and postsynaptic 5-hydroxytryptamine function. Firstly, we measured the effect of direct electrical stimulation (2 Hz for 2 min) of rat brain slices on efflux of preloaded [3H]5-hydroxytryptamine. In this in vitro model, twin-pulse stimulation increased the efflux of tritium by about twice as much as did single-pulse stimulation. This effect was evident in the medial prefrontal cortex (area under the curve: 2. 59+/-0.34 vs 1.28+/-0.22% relative fractional release), as well as in the caudate-putamen (3.93+/-0.65 vs 2.17+/-0.51%) and midbrain raphe nuclei (5.42+/-1.05 vs 2.51+/-0.75%). Secondly, we used in vivo microdialysis to monitor changes in endogenous extracellular 5-hydroxytryptamine in rat medial prefrontal cortex in response to electrical stimulation (3 Hz for 10 min) of the dorsal raphe nucleus. In this model, twin-pulse stimulation of the dorsal raphe nucleus increased 5-hydroxytryptamine by approximately twice as much as did single-pulse stimulation at the same frequency (area under the curve: 50.4+/-9.0 vs 24.2+/-4.4 fmol). Finally, we used in vivo extracellular recording to follow the response of postsynaptic neurons in the rat medial prefrontal cortex to 5-hydroxytryptamine released by dorsal raphe stimulation. Electrical stimulation of the dorsal raphe nucleus (1 Hz) induced a clear-cut poststimulus inhibition in the majority of cortical neurons tested. In these experiments, the duration of poststimulus inhibition following twin-pulse stimulation was markedly longer than that induced by single-pulse stimulation (200+/-21 vs 77+/-18.5 ms). Taken together, the present in vitro and in vivo data suggest that in 5-hydroxytryptamine neurons, short bursts of action potentials will propagate along the axon to the nerve terminal and will enhance both the release of 5-hydroxytryptamine and its postsynaptic effect.
... For burst activity, the start of a burst was indicated by the occurrence of 2 spikes with interspike intervals (ISI) < 0.08 s for NE and DA neurons and <0.01 s for 5-HT neurons. Burst termination was defined as an ISI >0.16 s for NE and DA (Grace and Bunney, 1983) and ISI >0.01 s for 5-HT neurons (Hajós and Sharp, 1996). For mPFC pyramidal neurons, burst determination was based on the following criteria: a series of 2 or more spikes, with ISI <0.045 s for the initiation and >0.045 s for termination of burst (Laviolette et al., 2005). ...
Ketamine acts primarily by blocking the N-methyl-D-aspartate (NMDA) receptor at the phencyclidine site. The rapid antidepressant properties of ketamine were demonstrated in the clinic and several behavioral models of depression in rodents. We hypothesized that the normalization of abnormal activity of monoamine neurons in Wistar Kyoto (WKY) rats contributes to the rapid antidepressant effects of ketamine. A single administration of ketamine (10 mg/kg, i. p) or saline was administered to anesthetized WKY rats before in vivo electrophysiological recordings of dorsal raphe nucleus (DRN) serotonin (5-HT), locus coeruleus (LC) norepinephrine (NE) and ventral tegmental area (VTA) dopamine (DA) neuronal activity. Pyramidal neurons from the medial prefrontal cortex (mPFC) were also recorded before and after a ketamine injection. In the VTA, ketamine elicited a significant increase in the population activity of DA neurons. This enhancement was consistent with findings in other depression-like models in which such a decreased population activity was observed. In the LC, ketamine normalized increased NE neuron burst activity found in WKY rats. In the DRN, ketamine did not significantly reverse 5-HT neuronal activity in WKY rats, which is dampened compared to Wistar rats. Ketamine did not significantly alter the neuronal activity of mPFC pyramidal neurons. These findings demonstrate that ketamine normalized NE neuronal activity and enhanced DA neuronal activity in WKY rats, which may contribute to its rapid antidepressant effect.
... Tonic (basal) neurotransmitter levels arise from clocklike neural firing over minutes to hours to days. Phasic (transient) changes in neurotransmitter levels are rapid (tens of milliseconds to seconds) and are hypothesized to result from synchronized bursts of neural firing in response to evoked or naturally occurring stimuli [29][30][31][32][33]. The ability to monitor transitory neurochemical events, in conjunction with changes in tonic signaling, will enable a more comprehensive understanding of how chemical neurotransmission encodes behaviorally relevant information [34,35]. ...
Many voltammetry methods have been developed to monitor brain extracellular dopamine levels. Fewer approaches have been successful in detecting serotonin in vivo. No voltammetric techniques are currently available to monitor both neurotransmitters simultaneously across timescales, even though they play integrated roles in modulating behavior. We provide proof-of-concept for rapid pulse voltammetry coupled with partial least squares regression (RPV-PLSR), an approach adapted from multi-electrode systems (i.e., electronic tongues) used to identify multiple components in complex environments. We exploited small differences in analyte redox profiles to select pulse steps for RPV waveforms. Using an intentionally designed pulse strategy combined with custom instrumentation and analysis software, we monitored basal and stimulated levels of dopamine and serotonin. In addition to faradaic currents, capacitive currents were important factors in analyte identification arguing against background subtraction. Compared to fast-scan cyclic voltammetry-principal components regression (FSCV-PCR), RPV-PLSR better differentiated and quantified basal and stimulated dopamine and serotonin associated with striatal recording electrode position, optical stimulation frequency, and serotonin reuptake inhibition. The RPV-PLSR approach can be generalized to other electrochemically active neurotransmitters and provides a feedback pipeline for future optimization of multi-analyte, fit-for-purpose waveforms and machine learning approaches to data analysis.
Graphical abstract
... For burst activity, the start of a burst was signified by the occurrence of two spikes with interspike interval (ISI) < 0.08 s for NE and DA neurons, and <0.01 s for 5-HT neurons. The termination of a burst was defined as an ISI < 0.16 s for DA and NE neurons (Grace and Bunney 1983) and ISI > 0.01 s for 5-HT neurons (Hajos and Sharp 1996). ...
Background:
Clinical studies have shown that the rapid antidepressant effect of the glutamate N-Methyl-D-Aspartate receptor antagonist ketamine generally disappears within one week but can be maintained by repeated administration. Preclinical studies showed that a single ketamine injection immediately increases the firing and burst activity of norepinephrine (NE) neurons, but not that of serotonin (5-HT) neurons. It also enhances the population activity of dopamine (DA) neurons. In the present study, we investigated whether such alterations of monoamine neuronal firing are still present one day after a single injection, and whether they can be maintained by repeated injections.
Methods:
Rats received a single ketamine injection or 6 over 2 weeks and the firing activity of dorsal raphe nucleus 5-HT, locus coeruleus NE, and ventral tegmental area DA neurons was assessed.
Results:
One-day following a single injection of ketamine, there was no change in the firing activity of 5-HT, NE, or DA neurons. One day after repeated ketamine administration, however, there was a robust increase of the firing activity of NE neurons, an enhancement of burst and population activities of DA neurons, but still no change in firing parameters of 5-HT neurons. The increased activity of NE neurons was no longer present 3 days after the last injection, whereas that of DA neurons was still present. DA neurons were firing normally 7 days after repeated injections.
Conclusion:
These results imply that the enhanced activity of NE and DA neurons may play a significant role in the maintenance of the antidepressant action of ketamine.
... However, we found that an early adolescence exposure to MPH leads to increased burst activities of DRN serotonin neurons (Figure 3(b)). In a similar way to dopamine neurons (Overton and Clark, 1997), bursting activity of DRN serotonin neurons is known to result in a greater efficiency of serotonin release in serotonin-projecting-region (Gartside et al., 2000;Hajos and Sharp, 1996;Hajos et al., 2007;Hurtig et al., 2007). Some serotonin neurons in the DRN may have adapted their firing mode Figure 6. ...
Background:
Psychostimulants like methylphenidate or D-amphetamine are often prescribed for attention deficit and hyperactivity disorders in children. Whether such drugs can be administered into a developing brain without consequences in adulthood is still an open question.
Methods:
Here, using in vivo extracellular electrophysiology in anesthetised preparations, combined with behavioural assays, we have examined the long-term consequences in adulthood of a chronic methylphenidate oral administration (5 mg/kg/day, 15 days) in early adolescent (post-natal day 28) and late adolescent (post-natal day 42) rats, by evaluating body weight change, sucrose preference (indicator of anhedonia), locomotor sensitivity to D-amphetamine and electrical activities of ventral tegmental area dopamine and dorsal raphe nucleus serotonin neurons.
Results:
Chronic methylphenidate treatment during early or late adolescence did not induce weight deficiencies and anhedonia-like behaviours at adulthood. However, it increased bursting activities of dorsal raphe nucleus serotonin neurons. Furthermore, chronic methylphenidate treatment during early but not during late adolescence enhanced D-amphetamine-induced rearing activity, as well as ventral tegmental area dopamine cell excitability (firing, burst and population activity), associated with a partial desensitisation of dopamine D2 auto-receptors.
Conclusions:
We have demonstrated here that early, but not late, adolescent exposure to oral methylphenidate may induce long-lasting effects on monoamine neurotransmission. The possible clinical implication of these data will be discussed.
... The onset of a burst was signified by the occurrence of 2 spikes with ISI <0.08 seconds for NE and DA and ISI <0.01 seconds for 5-HT. The termination of a burst was defined as an ISI >0.16 seconds for NE and DA and ISI >0.01 seconds for 5-HT (Grace and Bunney, 1983;Hajos and Sharp, 1996;Dawe et al., 2001). ...
Olfactory bulbectomized (OBX) rats generally manifest many of the neurochemical, physiological, and behavioural features of major depressive disorder in humans. Another interesting feature of this model is that it responds to chronic but not acute antidepressant treatments, including selective serotonin (5-HT) reuptake inhibitors (SSRIs). The purpose of the present study was first to characterize the firing activity of dorsal raphe 5-HT neurons in OBX rats and then examine the effects of two antidepressants, namely bupropion and paroxetine. Olfactory bulbectomy was performed by aspirating olfactory bulbs in anesthetized rats. Vehicle and drugs were delivered for 2 and 14 days via subcutaneously implanted minipumps. In vivo electrophysiological recordings were carried out in male anesthetized Sprague-Dawley rats. Following ablation of olfactory bulbs, the firing rate of 5-HT neurons was decreased by 36%, leaving those of norepinephrine and dopamine neurons unchanged. In OBX rats, bupropion (30 mg/kg/day) restored the firing rate of 5-HT neurons to the control level following 2- and 14-day administration and also induced an increase in the tonic activation of 5-HT1A receptors; paroxetine (10 mg/kg/day) did not result in a return to normal of the attenuated firing of 5-HT neurons in OBX rats. In the hippocampus, although at higher dose of WAY 100635 than that required in bupropion-treated animals, paroxetine administration also resulted in an increase in the tonic activation of 5-HT1A receptors. The present results indicate that unlike paroxetine, bupropion administration normalized 5-HT neuronal activity and increased tonic activation of the 5-HT1A receptors in hippocampus.
© The Author 2014. Published by Oxford University Press on behalf of CINP.
... The spikes in a burst had decreasing amplitude but the first was always identical to single spikes. These were extracellular recordings at the cell bodies, but in a later paper [46] it was shown that the spikes in bursts actually create action potentials in the axon that can, therefore, release 5HT in terminal regions. ...
We present a new hypothesis for the efficacy of selective serotonin reuptake inhibitors (SSRIs). We propose that SSRIs bring the response to the phasic firing of raphe nucleus cells back to normal, even though the average extracellular 5HT concentration remains low. We discuss burst firing in the raphe nuclei and use mathematical models to argue that tonic firing and phasic firing may be decoupled and may come from different mechanisms. We use a mathematical model for serotonin synthesis, release, and reuptake in terminals to illustrate the responses in terminal regions to bursts in a normal individual and in an individual with low vesicular serotonin. We then show that acute doses of SSRIs do not bring the response to bursts back to normal, but that chronic doses do return the response to normal. These model results need to be confirmed by new electrophysiological and pharmacological experiments.
... The hallmark characteristics include a firing rate of 1-5 Hz, an action potential with a long duration and large afterhyperpolarization (AHP) and a hyperpolarizing response to 5-HT 1A receptor activation. Additionally, several laboratories have proposed different subtypes of 5-HT neurons (Gartside et al., 2000;Hajos and Sharp, 1996;Kocsis et al., 2006). We have recently used whole cell recording techniques in concert with immunohistochemistry to identify the cellular characteristics of both 5-HT and non-5-HT neurons in rat vmDR and MR (Beck et al., 2004). ...
The median (MR) and dorsal raphe (DR) nuclei contain the majority of the 5-hydroxytryptamine (5-HT, serotonin) neurons that project to limbic forebrain regions, are important in regulating homeostatic functions and are implicated in the etiology and treatment of mood disorders and schizophrenia. The primary synaptic inputs within and to the raphe are glutamatergic and GABAergic. The DR is divided into three subfields, i.e., ventromedial (vmDR), lateral wings (lwDR) and dorsomedial (dmDR). Our previous work shows that cell characteristics of 5-HT neurons and the magnitude of the 5-HT(1A) and 5-HT(1B) receptor-mediated responses in the vmDR and MR are not the same. We extend these observations to examine the electrophysiological properties across all four raphe subfields in both 5-HT and non-5-HT neurons. The neurochemical topography of glutamatergic and GABAergic cell bodies and nerve terminals were identified using immunohistochemistry and the morphology of the 5-HT neurons was measured. Although 5-HT neurons possessed similar physiological properties, important differences existed between subfields. Non-5-HT neurons were indistinguishable from 5-HT neurons. GABA neurons were distributed throughout the raphe, usually in areas devoid of 5-HT neurons. Although GABAergic synaptic innervation was dense throughout the raphe (immunohistochemical analysis of the GABA transporters GAT1 and GAT3), their distributions differed. Glutamate neurons, as defined by vGlut3 anti-bodies, were intermixed and co-localized with 5-HT neurons within all raphe subfields. Finally, the dendritic arbor of the 5-HT neurons was distinct between subfields. Previous studies regard 5-HT neurons as a homogenous population. Our data support a model of the raphe as an area composed of functionally distinct subpopulations of 5-HT and non-5-HT neurons, in part delineated by subfield. Understanding the interaction of the cell properties of the neurons in concert with their morphology, local distribution of GABA and glutamate neurons and their synaptic input, reveals a more complicated and heterogeneous raphe. These results provide an important foundation for understanding how specific subfields modulate behavior and for defining which aspects of the circuitry are altered during the etiology of psychological disorders.
... As the recordings were extracellular, it was not possible to neurochemically identify the recorded cells by subsequent immunohistochemical labelling. However, previous studies have reported that serotonergic cells in this region tend to have a regular firing pattern at a slow frequency, 0.1–3 Hz (Vandermaelen and Aghajanian, 1983; Hajos and Sharp, 1996). For this reason, we measured the coefficient of variation (standard deviation/mean ) of the interspike interval measured 400 s just before the application of ghrelin, to describe the firing pattern. ...
The orexigenic and pro-obesity hormone ghrelin targets key hypothalamic and mesolimbic circuits involved in energy balance, appetite and reward. Given that such circuits are closely integrated with those regulating mood and cognition, we sought to determine whether chronic (>2 weeks) CNS exposure to ghrelin alters anxiety- and depression-like behaviour in rats as well as some physiological correlates. Rats bearing chronically implanted i.c.v. catheters were treated with ghrelin (10 μg/d) or vehicle for 4 weeks. Tests used to assess anxiety- and depression-like behaviour were undertaken during weeks 3-4 of the infusion. These revealed an increase in anxiety- and depression-like behaviour in the ghrelin-treated rats relative to controls. At the end of the 4-week infusion, brains were removed and the amygdala dissected for subsequent qPCR analysis that revealed changes in expression of a number of genes representing key systems implicated in these behavioural changes. Finally, given the key role of the dorsal raphe serotonin system in emotional reactivity, we examined the electrophysiological response of dorsal raphe neurons after a ghrelin challenge, and found mainly inhibitory responses in this region. We demonstrate that the central ghrelin signalling system is involved in emotional reactivity in rats, eliciting pro-anxiety and pro-depression effects and have begun to explore novel target systems for ghrelin that may be of importance for these effects.
... Burst activity of 5-HT neurons mostly occurs in doublets. Furthermore, 5-HT burst firing was analyzed using the following parameter: the onset of a burst, defined as the occurrence of two spikes with an interspike interval of 0.01 s or shorter (Hajós and Sharp, 1996). ...
Pramipexole (PPX) is a D(2)/D(3) receptor agonist that has been shown to be effective in the treatment of depression. Serotonin (5-HT), norepinephrine (NE) and dopamine (DA) systems are known to be involved in the pathophysiology and treatment of depression. Due to reciprocal interactions between these neuronal systems, drugs selectively targeting one system-specific receptor can indirectly modify the firing activity of neurons that contribute to firing patterns in systems that operate via different neurotransmitters. It was thus hypothesized that PPX would alter the firing rate of DA, NE and 5-HT neurons. To test this hypothesis, electrophysiological experiments were carried out in anesthetized rats. Subcutaneously implanted osmotic minipumps delivered PPX at a dose of 1 mg/kg per day for 2 or 14 days. After a 2-day treatment with PPX the spontaneous neuronal firing of DA neurons was decreased by 40%, NE neuronal firing by 33% and the firing rate of 5-HT neurons remained unaltered. After 14 days of PPX treatment, the firing rate of DA had recovered as well as that of NE, whereas the firing rate of 5-HT neurons was increased by 38%. It was also observed that sustained PPX administration produced desensitization of D(2)/D(3) and 5-HT(1A) cell body autoreceptors, as well as a decrease in sensitivity of alpha(2)-adrenergic cell body autoreceptors. These adaptive changes are implicated in long-term firing rate adaptations of DA, NE and 5-HT neurons after prolonged PPX administration. In conclusion, the therapeutic action of PPX in depression might be attributed to increased DA and 5-HT neurotransmission.
... Antidromic activations were verified by collision tests in which spontaneous spikes are made to collide with and extinguish antidromic spikes. Spontaneous spikes were converted to TTL pulses to trigger the stimulation with appropriate delays between spontaneous spike and stimulus (Fuller and Schlag, 1976;Hajós and Sharp, 1996). The effect of raphe stimulation was determined by construction of peristimulus-time histograms (PSTH, bin size: 10 ms). ...
The ventral part of the medial prefrontal cortex (mPFC) plays an important role in mood and cognition. This study examined the effect of the 5-HT in this region by measuring the electrophysiological response of ventral mPFC neurones to electrical stimulation of the dorsal and median raphe nuclei (DRN and MRN), which are the source of the 5-HT input. DRN or MRN stimulation evoked a consistent, short-latency, post-stimulus inhibition in the majority of ventral mPFC neurones tested (DRN: 44/73 neurones; MRN: 24/31 neurones). Some neurones responded to DRN or MRN stimulation with antidromic spikes indicating that they were mPFC-raphe projection neurones. Both DRN- and MRN-evoked inhibitions were attenuated by systemic administration of the 5-HT1A antagonist WAY 100635 (0.1 mg/kg i.v.). DRN-evoked inhibition was also attenuated by iontophoretic application of WAY 100635 and by systemic administration of the 5-HT1A antagonist, NAD-299 (4 mg/kg i.v.) but not the 5-HT2 antagonist ketanserin (4 mg/kg, i.v.). These data suggest that DRN and MRN 5-HT neurones inhibit neurones in the ventral mPFC via activation of 5-HT1A receptors. Some of these mPFC neurones may be part of a 5-HT1A receptor-controlled postsynaptic feedback loop to the DRN and MRN.
... In contrast to spontaneous firing, the recovery of firing after hyperpolarizing current pulses was dramatically slowed by the A-current (Fig. 3A). This suggests that the A-current may significantly affect the firing responses to pulsatile hyperpolarizing inputs, which in the case of orexin neurons could potentially originate from burst-firing noradrenergic and serotonergic cells (Tung et al., 1989; Hajos & Sharp, 1996; Li et al., 2002; Yamanaka et al., 2003b). Our measurements also revealed a positive correlation between the A-type conductance density and the gain (slope) of the relationship between the firing frequency and hyperpolarizing current in orexin cells (Fig. 3C). ...
The activity of hypothalamic neurons that release the neuropeptides orexin-A and orexin-B is essential for normal wakefulness. Orexin neurons fire spontaneously and are hyperpolarized and inhibited by physiological neuromodulators, but the intrinsic determinants of their electrical activity are poorly understood. We show that mouse orexin neurons coexpress orexin-A and orexin-B, and possess a low-voltage-activated A-type K(+) current (A-current) likely to be composed of Kv4.3 subunits. The A-current enhances the inhibitory influence of hyperpolarizing currents via two mechanisms: by delaying the resumption of spiking after hyperpolarization and by increasing the slope of the relation between the firing frequency and injected current. These results identify an important determinant of the firing dynamics of orexin neurons, and support the idea that the A-current can control neuronal gain.
Les études épidémiologiques estiment que le risque de dépression majeure (DM) est plus élevé chez les patients diabétiques comparé à la population générale. Des études plus spécifiques mettent en lumière des corrélations entre la dégradation de certains paramètres métaboliques et les symptômes anxio-dépressifs chez l'humain. C'est notamment le cas pour l'insulino-résistance périphérique qui est positivement corrélée à la sévérité de la DM. En revanche, les conséquences de l'insulino-résistance centrale sur les troubles dépressifs n'ont jamais été étudiés de manière approfondie non seulement en clinique mais également chez l'animal de laboratoire. Compte tenu de la présence du récepteur à l'insuline dans le cerveau, une des hypothèses serait que cette hormone module directement (ou indirectement) l'activité des systèmes monoaminergiques et notamment celle des neurones sérotoninergiques (5-HT) majoritairement regroupé dans le noyau dorsal du raphé (NDR). En effet, si l'influence de l'insuline sur le système dopaminergique et le comportement alimentaire a déjà été montré, très peu d'études se sont intéressées à son impact sur le système 5-HT pourtant clé dans la physiopathologie de la DM. Au cours de ce travail de thèse nous avons pu montrer que le récepteur à l'insuline est présent sur les neurones 5-HT du NDR. Grâce à des techniques d'électrophysiologie ex- et in-vivo et de microdialyse intracérébrale réalisées sur modèle murin, nous avons caractérisé l'effet excitateur de l'insuline sur l'activité électrique des neurones 5-HT. Ces résultats nous ont amené à tester les effets comportementaux de l'insuline et à montrer les effets anxiolytiques de son injection intra-raphé et intra-nasale chez la souris saine. Dans un second temps, afin de se placer dans un contexte pathologique et de mieux comprendre l'impact de la perturbation de la signalisation de l'insuline sur l'humeur, nous avons étudié l'activité du système 5-HT et les comportements de type anxio-dépressifs dans des modèles murins de diabète de type 1 et 2 (DT1/DT2). Dans ces deux modèles, que ce soit dans un contexte d'insulinopénie (DT1) ou d'insulino-résistance (DT2), les souris présentent un phénotype anxieux et certains traits de la DM associés à un diminution de l'activité du système sérotoninergique du NDR. Enfin, nous avons tenté d'identifier l'implication de l'apeline, une adipokine connue pour ses propriétés insulino-sensibilisatrice sur les anomalies comportementales induites par un DT2. Nos résultats montrent que les souris présentant une invalidation génétique de l'apeline, sont plus susceptibles à développer une insulino-résistance en réponse à un régime alimentaire diabétogène et des troubles comportementaux. De manière intéressante le traitement par la metformine, un antidiabétique aux propriétés insulino-sensibilisatrice, ne permet pas l'amélioration des paramètres métaboliques de ces souris mutantes mais améliore leur état anxieux. Ainsi ce travail de thèse a permis de souligner l'existence d'interactions anatomiques et fonctionnelles entre le système insulinergique et sérotoninergique central ainsi que leur importance dans l'anxiété, un trouble psychiatrique souvent annonciateur d'un épisode dépressif. [...]
Background
Cariprazine, the novel dopamine (DA) D 3 -preferring D 3 /D 2 and serotonin (5-HT) 1A receptor partial agonist, has activity as an adjunctive therapy in major depressive disorder (MDD).
Aims
This study aims to investigate the effects of chronic cariprazine administration in combination with the selective serotonin reuptake inhibitor escitalopram on the activity of monoaminergic systems.
Methods
Rats received cariprazine alone and in adjunct to escitalopram for 2 and 14 days and the firing activity of dorsal raphe nucleus 5-HT, locus coeruleus norepinephrine (NE) and ventral tegmental area DA neurons was assessed. 5-HT and NE neurotransmission in hippocampus pyramidal neurons was evaluated by assessing tonic activation of their 5-HT 1A , and α 1 - and α 2 -adrenergic receptors, using their selective antagonists.
Results
Two and 14-day cariprazine regimens increased the firing rate of NE, but not 5-HT and DA neurons. Addition of cariprazine to escitalopram reversed the inhibitory effect of escitalopram on NE but not 5-HT and DA neurons. In the hippocampus, there was an increase in neurotransmission at 5-HT 1A receptors in cariprazine-treated rats, but no change in overall NE transmission by either regimen.
Conclusion
Cariprazine increased NE neuronal firing and reversed the escitalopram-induced inhibition of these neurons. Despite a lack of effect on 5-HT neuronal firing activity, there was an increase in tonic activation of hippocampus 5-HT 1A receptors by cariprazine alone but not with the combination. These effects provide a possible rationale for the clinical efficacy of cariprazine as an adjunctive strategy in patients with MDD.
Electrophysiological methods are commonly used in neuroscience and pharmacology to reveal the mechanisms of drug action. In vivo analysis of the mechanisms of drug action is a particularly important method in neuropharmacology. Here, we show the juxtacellular recording method to characterize the electrophysiological and neurochemical properties of neurons. Using juxtacellular recording, researchers can record the membrane potential from single neurons, and examine action potential parameters, such as the width and coefficient variance of inter-spike intervals. Additionally, recorded neurons can be labeled using neurobiotin, and neurochemical properties can be revealed by a combination of immunohistochemical staining and in situ hybridization. We introduce an experiment testing the effects of a phosphodiesterase 4 (PDE4) inhibitor on the fronto-striatal circuit using juxtacellular recording. The cerebral cortex-nucleus accumbens (NAcc)-external segment of globus pallidus (GPe)-subthalamic nucleus (STN)-substantia nigra pars reticulata (SNr) pathway is the neurobiological basis of many neuropsychiatric disorders. Several components of this pathway are particularly important for the regulation of motor action and cognitive function: 1) STN-SNr pathway (hyperdirect pathway), 2) NAcc-SNr pathway (direct pathway), and 3) GPe-STN-SNr pathway (indirect pathway). Researchers can record tri-phasic responses reflecting these pathways using electro-stimulation in cerebral cortex. A PDE4 inhibitor, roflumilast, affected the 2) direct pathway as well as the 3) indirect pathway, but not the 1) hyperdirect pathway. The current findings suggest that PDE4 inhibition could be considered as a possible treatment for cognitive deficits related to fronto-striatal disorders such as attention deficit/hyperactivity disorder, and Parkinson's disease.
Despite its importance in regulating emotion and mental well-being, the complex structure and function of the serotonergic system present formidable challenges toward understanding its mechanisms. In this paper, we review studies investigating the interactions between serotonergic and related brain systems and their behavior at multiple scales, with a focus on biologically based computational modeling. We first discuss serotonergic intracellular signaling and neuronal excitability, followed by neuronal circuit and systems levels. At each level of organization, we will discuss the experimental work accompanied by related computational modeling work. We then suggest that a multiscale modeling approach that integrates the various levels of neurobiological organization could potentially transform the way we understand the complex functions associated with serotonin.
We use mathematical modeling to study how the electrophysiology and the pharmacology of the brain affect each other and brain function. Necessarily, this involves understanding volume transmission by which neurons in a brain nucleus project to distant nuclei and change the local biochemistry there. Examples include the serotonergic projection from the dorsal raphe nucleus to the striatum and the dopaminergic projection from the substantial nigra pars compacta to the striatum. The serotonin concentration in the striatum affects dopamine release in the striatum through receptors on the dopamine terminals. The concept of volume transmission is discussed and other examples of volume transmission are given. We describe how we construct our mathematical models based on known physiology and biochemistry. We describe model results that show how autoreceptors buffer the serotonin system against genetic polymorphisms and we explain why the brain serotonin concentration depends on diet but the dopamine concentration does not. We discuss the traditional hypotheses about the mechanism of action of selective sserotonin reuptake inhibitors (SSRIs), and introduce a new hypothesis about the mechanisms of SSRIs. We explain why the serotonin system has a large effect on the efficacy of levodopa treatment for Parkinson’s disease and why dyskinesias occur as the disease progresses. Finally, we study various aspects of the homeostasis of dopamine in the striatum. Volume transmission raises many new, interesting questions for the mathematical neuroscience community.
Carisbamate and lamotrigine are anticonvulsants which act on neuronal voltage-gated sodium channels. Carisbamate has been shown to have antidepressant-like effects in animal models of depression, and lamotrigine is a mood stabilizer with a therapeutic effect in depressive episodes of patients with bipolar disorder. This study examined the effects of carisbamate and lamotrigine on monoaminergic transmission in rodents which could contribute to their antidepressant action. In vivo electrophysiological recordings were carried out in rats, after 2 and 14 days administration of vehicle, carisbamate (60 mg/kg/day) or lamotrigine (25 mg/kg/day). Overall firing activity of the dorsal raphe nucleus (DRN) serotonin (5-HT), locus coeruleus (LC) norepinephrine (NE) and ventral tegmental area (VTA) dopamine (DA) neurons were decreased with carisbamate. Lamotrigine also decreased 5-HT neuronal firing and this effect was dampened by lesion of the prefrontal cortex. Despite these decreases in firing activity after their prolonged administration, both anticonvulsants exhibited significant increase in tonic activation of hippocampus 5-HT1A receptors as shown by a disinhibition of the firing activity of pyramidal neurons in response to the selective antagonist WAY-100635. This reveals an increase in 5-HT level that may be attributed to a desensitization of the terminal 5-HT1B autoreceptors. This study demonstrates that sustained carisbamate and lamotrigine administration decreases 5-HT firing in the DRN but nevertheless enhances 5-HT transmission in the forebrain. This serotonergic effect may be associated with an antiglutamatergic action, and may contribute to the antidepressant-like effect of carisbamate in the forced swim test (FST) and the antidepressant properties of lamotrigine.
Background: Selectively-bred alcohol-preferring (P) rats have fewer serotonin (5-HT) neurons in the dorsal raphe nucleus (DRN) than do alcohol-nonpreferring (NP) rats. The present study was designed to test the hypothesis that the remaining 5-HT neurons in P rats compensated for their reduced number by increasing neuronal activity.
Methods: Spontaneous activity was recorded from single-spiking and bursting 5-HT neurons in the DRN of unanesthetized paralyzed, alcohol-naive P, NP, and Wistar rats. Firing frequencies, the percentages of action potentials in bursts, and the percentages of bursting neurons were evaluated.
Results: There were no significant differences among the three groups of rats in any of the parameters measured. Power analyses were performed on preliminary data to determine the sample sizes necessary for detection of significant differences. The mean firing frequencies of single-spiking 5-HT neurons averaged 1.8 (37 neurons), 1.7 (17 neurons), and 1.8 (41 neurons) spikes per second in P, NP, and Wistar rats, respectively. For bursting 5-HT neurons, the percentages of action potentials in bursts for P, NP, and Wistar rats were 55.0% (24 neurons), 49.7% (18 neurons), and 55.1% (21 neurons). The mean percentages of bursting 5-HT neurons encountered per electrode penetration were 44% for P rats (n= 28), 44% for NP rats (n= 14), and 34% for Wistar rats (n= 26).
Conclusions: The results indicate that the sample of 5-HT neurons recorded in the DRN of P rats had not compensated for a reduced number by altering neuronal activity.
The morphology and electrophysiological properties of serotonergic and non-serotonergic projection neurons in the dorsal raphe nucleus (DRN) of the rat were examined in frontal brain slices. Biocytin was injected intracellularly into the intracellularly recorded neurons. Then the morphology of the recorded neurons was observed after histochemical visualization of biocytin. The recorded neurons extending their main axons outside the DRN were considered as projection neurons. Subsequently, serotonergic nature of the neurons was examined by serotonin (5-HT) immunohistochemistry. The general form of the dendritic trees is radiant and poorly branching in both 5-HT- and non-5-HT neurons. However, the dendrites of the 5-HT neurons were spiny, whereas those of the non-5-HT neurons were aspiny. The main axons of both 5-HT- and non-5-HT neurons were observed to send richly branching axon collaterals to the DRN, ventrolateral part of the periaqueductal gray and the midbrain tegmentum. In response to weak, long depolarizing current pulses, the 5-HT neurons displayed a slow and regular firing activity. The non-5-HT neurons fired at higher frequencies even when stronger current was injected. Some other differences in electrophysiological properties were also observed between the 5-HT-immunoreactive spiny projection neurons and the 5-HT-immunonegative aspiny projection neurons.
Asenapine is a psychopharmacologic agent being developed for schizophrenia and bipolar disorder. This study electrophysiologically characterized the in vivo effects of asenapine at dorsal raphe nucleus (DRN) and hippocampus serotonin-1A (5-HT(1A)), ventral tegmental area D(2), locus coeruleus 5-HT(2A,) and alpha(2)-adrenergic receptors in anesthetized rats. Asenapine displayed potent antagonistic activity at alpha(2)-adrenoceptors (ED(50), 85+/-2 microg/kg), 5-HT(2A) (ED(50), 75+/-2 microg/kg) and D(2) receptors (ED(50), 40+/-2 microg/kg) as evidenced by its reversal of clonidine-, DOI-, and apomorphine-induced inhibition of norepinephrine and dopamine neurons. In contrast, asenapine acted as a partial agonist at 5-HT(1A) receptors in DRN and hippocampus, as indicated by blockade of its inhibitory effect on neuronal firing by the 5-HT(1A) antagonist WAY 100635 and the partial inhibition of the suppressant action of 5-HT when co-applied by microiontophoresis. These results confirm that asenapine displays potent antagonistic activity at 5-HT(2A), D(2), alpha(2)-adrenergic receptors and provide evidence to support its 5-HT(1A) partial agonistic activity.
The substantia nigra pars reticulata (SNr) forms a principal output from the basal ganglia. It also receives significant histamine (HA) input from the tuberomammillary nucleus whose functions in SNr remain poorly understood. One identified role is the regulation of serotonin (5-HT) neurotransmission via the HA-H(3) receptor. Here we have explored regulation by another HA receptor expressed in SNr, the H(2)-receptor (H(2)R), by monitoring electrically evoked 5-HT release with fast-scan cyclic voltammetry at carbon-fiber microelectrodes in SNr in rat brain slices. Selective H(2)R antagonists (inverse agonists) ranitidine and tiotidine enhanced 5-HT release while the agonist amthamine suppressed release. The 'neutral' competitive antagonist burimamide alone was without effect but prevented ranitidine actions indicating that inverse agonist effects result from constitutive H(2)R activity independent of HA tone. H(2)R control of 5-HT release was most apparent (from inverse agonist effects) at lower frequencies of depolarization (< or = 20 Hz), and prevailed in the presence of antagonists of GABA, glutamate or H(3)-HA receptors. These data reveal that H(2)Rs in SNr are constitutively active and inhibit 5-HT release through H(2)Rs on 5-HT axons. These data may have therapeutic implications for Parkinson's disease, when SNr HA levels increase, and for neuropsychiatric disorders in which 5-HT is pivotal.
Clinical studies indicate that addition of bupropion to selective serotonin (5-HT) reuptake inhibitors (SSRIs) provides incremental benefit over SSRI monotherapy in depression. This study was designed to investigate the effects of co-administration of bupropion with escitalopram on the firing rate of 5-HT and norepinephrine (NE) neurons in anesthetized rats. Escitalopram (10 mg/kg/day x 2 days), given via subcutaneously (s.c.) implanted minipumps, decreased the firing of 5-HT and NE neurons by 70% and 55%, respectively. The firing of 5-HT neurons, unlike that of NE neurons, recovered after the 14-day escitalopram regimen. Bupropion, injected once daily (30 mg/kg/day, s.c. x 2 days), did not increase 5-HT firing but decreased that of NE by 55%. After 14 days of repeated bupropion administration, 5-HT firing was increased by 50%, and NE firing was back to baseline. Co-administration of escitalopram and bupropion doubled 5-HT firing after 2 and 14 days, whereas NE neurons were inhibited by 60% after 2 days, but partially recovered after 14 days. The responsiveness of 5-HT(1A) autoreceptors was significantly attenuated in the combination-treated rats after 2 days, indicating an early desensitization. These results provide support for contributions from 5-HT and NE mechanisms for enhanced effectiveness of combination of SSRI and bupropion treatment.
Bupropion is widely used in the treatment of depression. There are, however, limited data on its long-term effects on monoaminergic neurons and therefore the mechanism of its delayed onset of action is at present not well understood. The present study was conducted to examine the effects of prolonged bupropion administration on the firing activity of dorsal raphe nucleus (DRN), locus coeruleus (LC), and ventral tegmental area (VTA) neurons. Spontaneously firing neurons were recorded extracellularly in rats anesthetized with chloral hydrate. Bupropion (30 mg/kg/day) was administered using subcutaneously implanted minipumps. In the DRN, the firing rate of serotonin (5-HT) neurons was significantly increased after 2, 7 and 14 days of administration. The suppressant effect of LSD was significantly diminished after the two-day regimen, indicating a desensitization of 5-HT1A autoreceptors. In the LC, the firing rate of norepinephrine (NE) neurons was significantly attenuated after a 2-day regimen, but recovered progressively over 14 days of administration. The suppressant effect of clonidine on NE neuronal firing was significantly attenuated in rats treated with bupropion for 14 days, indicating a desensitization of alpha2-adrenoceptors. In the VTA, neither 2 nor 14 days of bupropion administration altered the firing and burst activity of dopamine neurons. These results indicate that bupropion, unlike 5-HT reuptake inhibitors, promptly increased 5-HT neuronal activity, due to early desensitization of the 5-HT1A autoreceptor. The gradual recovery of neuronal firing of NE neurons, due to the desensitization of alpha2-adrenoceptors, in the presence of the sustained increase in 5-HT neuronal firing, may explain in part the delayed onset of action of bupropion in major depression.
Here we report the existence of burst-firing neurones in the rat dorsal raphe as detected in vivo using intracellular electrophysiological techniques. These neurones discharged single action potentials and doublets or triplets of action potentials in a slow and regular pattern. The apparent input resistance, action potential width and firing threshold of these burst-firing raphe neurones were indistinguishable from classical 5-HT neurones. Spike doublets were evoked by depolarising DC currents, but only in burst-firing neurones. These findings provide further evidence to support the hypothesis that 5-HT neurones (or a sub-set of them) are capable of burst-firing activity.
In this study we utilized electrophysiological and pathway tracing methods to investigate the projections from the medial prefrontal cortex to the midbrain raphe nuclei of the rat. Initial pathway tracing experiments using retrograde (horseradish peroxidase conjugates with wheatgerm agglutinin or choleratoxin B subunit) and anterograde (Phaseolus vulgaris-leucoagglutinin) markers demonstrated a direct, bilateral projection to the dorsal raphe nucleus and median raphe nucleus from the medial prefrontal cortex, and the origin of this projection was localized predominantly in the ventral medial prefrontal cortex (infralimbic/dorsal penduncular cortices). Using chloral hydrate-anaesthetized rats, extracellular recordings were made mostly from 5-hydroxytryptamine neurons in the dorsal raphe nucleus, but non-5-hydroxytryptamine dorsal raphe neurons were also studied, as was a small number of 5-hydroxytryptamine neurons in the median raphe nucleus. In an initial study, electrical stimulation of the ventral medial prefrontal cortex caused a post-stimulus inhibition in the majority (49/56) of dorsal raphe 5-hydroxytryptamine neurons tested (mean duration of inhibition, 200+/-17 ms); in some cases (8/56) the inhibition was preceded by short-latency (26 +/-3 ms) orthodromic activation, and a small number of cells was antidromically activated (6/56). Both single spiking and burst-firing 5-hydroxytryptamine neurons in the dorsal raphe nucleus responded in the same way, and median raphe 5-hydroxytryptamine neurons were also inhibited (5/5). In contrast, few (2/12) of the non-5-hydroxytryptamine dorsal raphe neurons tested were inhibited by ventral medial prefrontal cortex stimulation. The effects of stimulation of the dorsal and ventral medial prefrontal cortex were compared on the same raphe 5-hydroxytryptamine neurons (n=17): ventral medial prefrontal cortex stimulation inhibited 16/17 of these neurons while only 8/17 were inhibited by dorsal medial prefrontal cortex stimulation. Finally, the inhibitory effect of ventral medial prefrontal cortex stimulation on 5-hydroxytryptamine cell-firing was not altered by 5-hydroxytryptamine depletion with p-chlorophenylalanine or by systemic administration of the selective 5-hydroxytryptamine1A receptor antagonist WAY 100635. The latter findings indicate that the inhibition is not due to release of raphe 5-hydroxytryptamine which could theoretically arise from anti- or orthodromically activated 5-hydroxytryptamine neurons. Our results show that stimulation of the ventral medial prefrontal cortex causes a marked post-stimulus inhibition in the vast majority of midbrain raphe 5-hydroxytryptamine neurons tested. It seems likely that the projection from ventral medial prefrontal cortex to the midbrain raphe nuclei mediates the responses of 5-hydroxytryptamine neurons to cortical stimulation. These data are relevant to recent discoveries of functional and structural abnormalities in the medial prefrontal cortex of patients with major depressive illness.
Selectively-bred alcohol-preferring (P) rats have fewer serotonin (5-HT) neurons in the dorsal raphe nucleus (DRN) than do alcohol-nonpreferring (NP) rats. The present study was designed to test the hypothesis that the remaining 5-HT neurons in P rats compensated for their reduced number by increasing neuronal activity.
Spontaneous activity was recorded from single-spiking and bursting 5-HT neurons in the DRN of unanesthetized paralyzed, alcohol-naive P, NP, and Wistar rats. Firing frequencies, the percentages of action potentials in bursts, and the percentages of bursting neurons were evaluated.
There were no significant differences among the three groups of rats in any of the parameters measured. Power analyses were performed on preliminary data to determine the sample sizes necessary for detection of significant differences. The mean firing frequencies of single-spiking 5-HT neurons averaged 1.8 (37 neurons), 1.7 (17 neurons), and 1.8 (41 neurons) spikes per second in P, NP, and Wistar rats, respectively. For bursting 5-HT neurons, the percentages of action potentials in bursts for P, NP, and Wistar rats were 55.0% (24 neurons), 49.7% (18 neurons), and 55.1% (21 neurons). The mean percentages of bursting 5-HT neurons encountered per electrode penetration were 44% for P rats (n = 28), 44% for NP rats (n = 14), and 34% for Wistar rats (n = 26).
The results indicate that the sample of 5-HT neurons recorded in the DRN of P rats had not compensated for a reduced number by altering neuronal activity.
Recent electrophysiological studies demonstrate that the ventral medial prefrontal cortex has a powerful inhibitory influence on 5-hydroxytryptamine (5-HT) neurones in the dorsal raphe nucleus. Here we utilised a combination of anatomical and electrophysiological methods to characterise the cellular substrate underlying this effect.Anterograde tracing (Phaseolus vulgaris leucoagglutinin) using electron microscopy demonstrated a pathway from the ventral medial prefrontal cortex that makes neuronal contacts throughout the dorsal raphe nucleus. These contacts were predominantly asymmetrical synapses adjoining GABA immunoreactive dendrites and spines. In vivo extracellular recordings were made in the dorsal raphe nucleus of the anaesthetised rat from a subpopulation of non-5-HT neurones. These neurones were fast-firing, irregular and with short spike width, properties strongly reminiscent of immunochemically identified GABA interneurones in other brain regions. Recordings of classical 5-HT neurones were also included. Electrical stimulation of the ventral medial prefrontal cortex elicited a rapid onset (16 ms latency), orthodromic excitation of the non-5-HT neurones (13/25 neurones). This stimulation also caused a pronounced inhibition of most 5-HT neurones tested, with a longer latency (30 ms), and this was partially blocked by locally applied bicuculline. These data provide the first evidence that the ventral medial prefrontal cortex influences the activity of large numbers of raphe 5-HT neurones by targeting a local network of GABA neurones. This circuitry predicts that physiological and pathological changes in the ventral medial prefrontal cortex will impact on significant parts of the forebrain 5-HT system.
Substance P receptor [neurokinin 1 (NK1] antagonists (SPAs) represent a novel mechanistic approach to antidepressant therapy with comparable clinical efficacy to selective serotonin reuptake inhibitors (SSRIs). Because SSRIs are thought to exert their therapeutic effects by enhancing central serotonergic function, we have examined whether SPAs regulate neuronal activity in the dorsal raphe nucleus (DRN), the main source of serotonergic projections to the forebrain. Using in vivo electrophysiological techniques in the guinea pig, we found that administration of the highly selective NK1 receptor antagonist 1-(5-[[(2R,3S)-2-([(1R)-1-[3,5-bis(trifluoromethyl)phenyl]ethyl]oxy)-3-(4-phenyl)morpholin-4-yl]methyl]-2H-1,2,3-triazol-4-yl)-N,N-dimethylmethanamine (L-760735) caused an increase in DRN neuronal firing rate. However, unlike chronic treatment with fluoxetine, there was no detectable 5-HT1A autoreceptor desensitization. In vitro electrophysiological investigation showed that these effects were not mediated by a direct action in the DRN, an observation supported by immunocytochemical analysis that identified the lateral habenula (LHb) as a more likely site of action. Subsequently, we found that local application of L-760735 into the LHb increased firing in the DRN, which, together with our data showing that L-760735 increased metabolic activity in the cingulate cortex, amygdala, LHb, and DRN, indicates that the effects of L-760735 may be mediated by disinhibition of forebrain structures acting via a habenulo raphe projection. These findings support other evidence for an antidepressant profile of SPAs and suggest that regulation of DRN neuronal activity may contribute to their antidepressant mechanism of action but in a manner that is distinct from monoamine reuptake inhibitors.
In the present study, changes of the neuronal activity of 5-hydroxytrypamine (5-HT) neurons of dorsal raphe nucleus(DRN) in a rat model of Parkinson's disease (PD) were investigated with glass microelectrode recording. The results showed that the discharge rates of 5-HT neurons in control and PD rats were (1.61+/-0.56) Hz and (2.61+/-1.97) Hz, respectively. The discharge rate of PD rats was significantly increased when compared to that of the control rats. In control rats, 79% of 5-HT neurons discharged regularly and 21% in bursts. In PD rats, however, 36% of 5-HT neurons discharged regularly, 16% irregularly and 47% in bursts. The percentage of 5-HT neurons discharging in bursts was obviously higher than that of the control rats (P<0.05). The data suggest that the discharge rate and bursting pattern of 5-HT neurons in DRN are increased in a rat model of Parkinson's disease.
New data show that 5-hydroxytryptamine (5-HT) neurons of the dorsal raphe nucleus (DRN) are subject to feedback control from 5-HT2 receptors, but the circuitry involved is uncertain. This study investigated whether 5-HT2 receptor agonism activates DRN gamma-aminobutyric acid (GABA) neurons, which are known to inhibit neighbouring 5-HT neurons. Systemic administration of the 5-HT2 receptor agonist, DOI, caused a striking increase in Fos-immunoreactivity in the DRN. This effect was abolished by the 5-HT2 antagonists ritanserin and MDL 100907, but not SB 206553, indicating the involvement of 5-HT2A receptors. Importantly, DOI-induced Fos-immunoreactivity in the DRN was extensively colocalized in GAD67-immunoreactive neurons. These findings suggest that activated local GABA neurons may play an important role in 5-HT2 receptor-mediated feedback control of DRN 5-HT neurons.
Early life adversity is associated with an increased incidence of psychiatric illness in adulthood. Although the mechanisms underlying this association are unclear, one possible substrate is brain 5-hydroxytryptamine neurotransmission, which is reportedly abnormal in several psychiatric disorders. This study examined the effect of a rat model of early life adversity, early maternal separation, on 5-hydroxytryptamine neurotransmission in adulthood. In vitro electrophysiological experiments revealed that, in early maternal separation rats compared with controls, the sensitivity of α1-adrenoceptors on 5-hydroxytryptamine neurons in the dorsal raphe nucleus was significantly reduced, whilst the sensitivity of 5-hydroxytryptamine1A receptors showed a nonsignificant trend to reduction. In in vivo microdialysis experiments, the 5-hydroxytryptamine1A receptor agonist-induced suppression of 5-hydroxytryptamine release in the frontal cortex was reduced in early maternal separation animals, suggesting desensitization of 5-hydroxytryptamine1A autoreceptors. There was no increase in basal 5-hydroxytryptamine in the frontal cortex as measured by microdialysis and a nonsignificant trend towards increased basal firing activity of classical (non-bursting) 5-hydroxytryptamine neurons in the dorsal raphe nucleus measured by in vivo electrophysiology. Finally, early maternal separation failed to alter expression of messenger ribonucleic acids coding for 5-hydroxytryptamine1A or α1B receptors in the dorsal raphe nucleus as measured by in situ hybridization histochemistry, suggesting that functional changes in receptor sensitivity observed are not due to changes in receptor gene transcription. The findings demonstrate that early life adversity programs changes in sensitivity of the two principal regulators of 5-hydroxytryptamine neuronal activity. Similar effects in humans may contribute to the increased incidence of psychiatric illness in individuals exposed to early life adversity.
Recent electrophysiological studies have discovered evidence of heterogeneity of 5-hydroxytryptamine (5-HT) neurons in the mesencephalic raphe nuclei. Of particular interest is a subpopulation of putative 5-HT neurons that display many of the electrophysiological properties of presumed 5-HT-containing neurons (regular and slow firing of single spikes with a broad waveform) but fire spikes in short, stereotyped bursts. In the present study we investigated the chemical identity of these neurons in rats utilizing in vivo juxtacellular labelling methods. Of ten dorsal raphe nucleus (DRN) neurons firing short stereotyped bursts within an otherwise regular firing pattern, all exhibited immunoreactivity for either 5-HT (n = 6) or the 5-HT synthesizing enzyme, tryptophan hydroxylase (TRH; n = 2) or both (n = 2). Supporting pharmacological experiments demonstrated that the burst firing DRN neurons demonstrated equal sensitivity to 5-HT(1A) agonism and alpha(1)-adrenoceptor antagonism to single spiking DRN neurons that we have previously identified as 5-HT-containing. Collectively these data provide direct evidence that DRN neurons that exhibit stereotyped burst firing activity are 5-HT containing. The presence of multiple types of electrophysiologically distinct midbrain 5-HT neurons is discussed.
Evidence from electrophysiological studies has suggested an inhibitory interaction between GABAergic neurons in substantia nigra pars reticulata and dopaminergic neurons in pars compacta. However, that this inhibitory interaction is due to a projection from pars reticulata to pars compacta has never been demonstrated directly, nor has the GABAergic neuron that mediates the interaction been identified either electrophysiologically or anatomically. To more closely examine interactions between substantia nigra pars reticulata GABA neurons and dopaminergic neurons, single unit extracellular recordings were obtained from antidromically identified nigrostriatal neurons and their response to antidromic activation of nigral GABAergic projection neurons observed. Stimulation of superior colliculus or thalamus produced a short latency inhibition of dopaminergic neurons. This inhibition was blocked by local application of bicuculline but not 2- hydroxysaclofen. Bicuculline caused most dopaminergic neurons to fire in a bursty mode, whereas saclofen caused most dopaminergic neurons to fire in a pacemaker-like mode. The thalamic-evoked inhibition was not affected by kainate lesions of the globus pallidus, but these lesions produced effects on firing pattern identical to those produced by saclofen. These data demonstrate a short latency inhibition of nigral dopaminergic neurons mediated by GABAA receptors that arises from the axon collaterals of pars reticulata projection neurons. We propose a model in which the firing pattern of nigral dopaminergic neurons in vivo is modulated differentially by disinhibition of GABAA inputs arising from pars reticulata projection neuron axon collaterals and disinhibition of pallidonigral GABAergic inputs mediated by GABAB receptors.
Three types of neurons, distinguished on the basis of their spontaneous firing rates and patterns, extracellularly recorded waveforms and responses to neostriatal stimulation, were observed in the dorsal raphe nucleus in urethane-anesthetized rats. Type 1 neurons (presumed to be serotonergic) fired spontaneously from 0.1 to 3 spikes/s in a regular pattern, with initial positive-going bi- or triphasic action potentials. Type 1 cells exhibited long-latency antidromic responses to neostriatal stimulation (mean +/- S.E.M. 24.9 +/- 0.3 ms) that sometimes occurred at discrete multiple latencies, and supernormal periods persisting up to 100 ms following spontaneous spikes. Type 2 cells fired spontaneously in an irregular, somewhat bursty pattern from 0 to 2 spikes/s with initial negative-going biphasic spikes, and were antidromically activated from neostriatal stimulation at shorter latencies than Type 1 cells (21.8 +/- 0.9 ms). Type 3 cells were characterized by initial positive-going biphasic waveforms and displayed a higher discharge rate (5-30 spikes/s) than Type 1 or Type 2 cells. Type 3 cells could not be antidromically activated from neostriatal stimulation. The relatively long conduction time to neostriatum of the Type 1 presumed serotonergic neuron is discussed with respect to previous interpretations of the synaptic action of serotonin in the neostriatum. In conjunction with these antidromic activation studies, the neurophysiological consequences of serotonergic terminal autoreceptor activation were examined by measuring changes in the excitability of serotonergic terminal fields in the neostriatum following administration of the serotonin autoreceptor agonist, 5-methoxy-N,N-dimethyltryptamine (5-MeODMT). The excitability of serotonergic terminal fields was decreased by intravenous injection of 40 micrograms/kg 5-MeODMT, and by infusion of 10-50 microM 5-MeODMT directly into the neostriatum. These results are interpreted from the perspective of mechanisms underlying autoreceptor-mediated regulation of serotonin release.
Intracellular recordings were obtained from directly identified rat nigral dopamine cells in vivo. This identification was based on an increase in glyoxylic acid-induced catecholamine fluorescence in the impaled dopamine neurons. One of three compounds was injected intracellularly into each cell to produce the heightened fluorescence: (1) L-DOPA, to increase the intracellular dopamine content by precursor loading; (2) tetrahydrobiopterin, a cofactor for tyrosine hydroxylase, to increase intracellular dopamine concentration through activation of the rate-limiting enzyme for dopamine synthesis and (3) colchicine, to arrest intraneuronal transport and thus allow the build-up of dopamine synthesizing enzymes and dopamine in the soma. In addition, dopamine cells were antidromically activated from the caudate nucleus and collision with a directly elicited action potential was demonstrated. Identified dopamine neurons were shown to possess an input resistance of 31.2 +/- 7.4 M omega (means +/- SD) and a time constant of 12.1 +/- 3.2 ms. The action potentials were of long duration (2.75 +/- 0.5 ms) with a marked break between the initial segment and the somatodendritic spike components. The initial segment was the only component commonly elicited during antidromic activation. Spontaneously occurring action potentials were usually preceded by a slow, pacemaker-like depolarization. Burst firing by summation of depolarizing afterpotentials was observed to occur spontaneously, but could not be triggered by short depolarizing current pulses. Intravenously administered apomorphine demonstrated the same inhibitory effect on cell firing that was previously reported to occur when recording extracellularly from identified dopaminergic neurons. The determination of the electrophysiological characteristics of a population of cells directly identified as containing a specific neurotransmitter (in this case, dopamine) may allow one to construct better models of a system's functioning. Thus, the high input resistance and long time constant of dopamine-containing cells, combined with their burst/pause firing mode, may be important functionally with respect to a possible modulatory effect of dopamine in postsynaptic target areas.
The purpose of this study was to ascertain the identity of presumed noradrenergic or serotonergic neurons recorded by single cell techniques in the mammalian brain. A double labeling method was developed in which intracellular injections of a red fluorescing dye (ethidium bromide) could be co-localized with the formaldehyde-induced green fluorescence of norepinephrine or yellow fluorescence of serotonin. By this method, neurons of the rat locus coeruleus that display a characteristic activation-inhibition response to noxious stimuli were confirmed to be noradrenergic; the slow, rhythmically firing neurons of the dorsal raphe nucleus were confirmed to be serotonergic.
Evidence from electrophysiological studies has suggested an inhibitory interaction between GABAergic neurons in substantia nigra pars reticulata and dopaminergic neurons in pars compacta. However, that this inhibitory interaction is due to a projection from pars reticulata to pars compacta has never been demonstrated directly, nor has the GABAergic neuron that mediates the interaction been identified either electrophysiologically or anatomically. To more closely examine interactions between substantia nigra pars reticulata GABA neurons and dopaminergic neurons, single unit extracellular recordings were obtained from antidromically identified nigrostriatal neurons and their response to antidromic activation of nigral GABAergic projection neurons observed. Stimulation of superior colliculus or thalamus produced a short latency inhibition of dopaminergic neurons. This inhibition was blocked by local application of bicuculline but not 2-hydroxysaclofen. Bicuculline caused most dopaminergic neurons to fire in a bursty mode, whereas saclofen caused most dopaminergic neurons to fire in a pacemaker-like mode. The thalamic-evoked inhibition was not affected by kainate lesions of the globus pallidus, but these lesions produced effects on firing pattern identical to those produced by saclofen. These data demonstrate a short latency inhibition of nigral dopaminergic neurons mediated by GABAA receptors that arises from the axon collaterals of pars reticulata projection neurons. We propose a model in which the firing pattern of nigral dopaminergic neurons in vivo is modulated differentially by disinhibition of GABAA inputs arising from pars reticulata projection neuron axon collaterals and disinhibition of pallidonigral GABAergic inputs mediated by GABAB receptors.
Previous electrophysiological studies have shown that spontaneously active mesencephalic 5-hydroxytryptaminergic neurons of anaesthetized or freely moving animals fire solitary spikes in a slow, regular pattern. In the present study, using extracellular single unit recordings from dorsal and median raphe neurons of the anaesthetized rat, an additional electrophysiological property of a sub-population of presumed 5-hydroxytryptaminergic neurons was observed. These neurons, during their otherwise regular firing pattern, repeatedly fired two (or occasionally three or even four) spikes where only one was expected. Spikes in this burst-like repetitive firing mode (spikes in doublets or triplets) occurred in a short time interval (range: 2.4-11.5 ms), and with a diminishing spike amplitude. Cross-correlation analysis of spikes in doublets revealed a very high interdependency between them. The proportion of spikes in doublets to solitary spikes showed great variation between different neurons, ranging from 5 to 95% of the total spikes displayed. However, for each neuron the proportion of spikes in doublets to solitary spikes, and the time interval between the spikes in doublets, remained constant during control recordings. All these features are characteristic of single neurons firing in a repetitive firing pattern rather than simultaneous recordings of two separate 5-hydroxytryptaminergic neurons. Repetitive firing neurons were recorded with a similar frequency in both chloral hydrate and Saffan anaesthetized rats, and were detected using both glass and metal electrodes. Furthermore, neurons with a repetitive firing pattern were inhibited by intravenous administration of a selective 5-hydroxytryptamine1A receptor agonist and a 5-hydroxytryptamine reuptake inhibitor, thus displaying responses typical of 5-hydroxytryptaminergic neurons. Repetitive firing neurons occurred in both the dorsal and median raphe nuclei, although they were much more frequent in the dorsal raphe nucleus (91 of 332 neurons). The occurrence of repetitive firing neurons in the midbrain raphe nuclei is a newly described phenomenon which may indicate unique properties of a sub-population of 5-hydroxytryptaminergic neurons. In functional terms, it could modify both axonal and dendritic 5-hydroxytryptamine release, and provide an additional option for neuronal information signalling.
Intracellular recordings were obtained from directly identified rat nigral dopamine cells in vivo. This identification was based on an increase in glyoxylic acid-induced catecholamine fluorescence in the impaled dopamine neurons. One of three compounds was injected intracellularly into each cell to produce the heightened fluorescence: (1) L-DOPA, to increase the intracellular dopamine content by precursor loading; (2) tetrahydrobiopterin, a cofactor for tyrosine hydroxylase, to increase intracellular dopamine concentration through activation of the rate-limiting enzyme for dopamine synthesis and (3) colchicine, to arrest intraneuronal transport and thus allow the build-up of dopamine synthesizing enzymes and dopamine in the soma. In addition, dopamine cells were antidromically activated from the caudate nucleus and collision with a directly elicited action potential was demonstrated. Identified dopamine neurons were shown to possess an input resistance of 31.2 +/- 7.4 M omega (means +/- SD) and a time constant of 12.1 +/- 3.2 ms. The action potentials were of long duration (2.75 +/- 0.5 ms) with a marked break between the initial segment and the somatodendritic spike components. The initial segment was the only component commonly elicited during antidromic activation. Spontaneously occurring action potentials were usually preceded by a slow, pacemaker-like depolarization. Burst firing by summation of depolarizing afterpotentials was observed to occur spontaneously, but could not be triggered by short depolarizing current pulses. Intravenously administered apomorphine demonstrated the same inhibitory effect on cell firing that was previously reported to occur when recording extracellularly from identified dopaminergic neurons. The determination of the electrophysiological characteristics of a population of cells directly identified as containing a specific neurotransmitter (in this case, dopamine) may allow one to construct better models of a system's functioning. Thus, the high input resistance and long time constant of dopamine-containing cells, combined with their burst/pause firing mode, may be important functionally with respect to a possible modulatory effect of dopamine in postsynaptic target areas.
The existence of a dopamine (DA) projection from nucleus raphe dorsalis (RD) to neostriatum was demonstrated in the rat by combined tyrosine hydroxylase (TH) immunohistochemistry and radioautography after retrograde axonal transport of [3H]noradrenaline ([3H]NA). Intrastriatal injections of [3H]NA were carried out in normal rats or after ipsilateral destruction of the nigrostriatal DA system by injection of 6-hydroxydopamine (6-OHDA) into the substantia nigra. Some 1,000 TH-positive nerve cell bodies were counted within the confines of RD as defined by its content in serotonin (5-HT) neurons. These DA neurons occupied the upper third of the RD and the, were part of its small cell population. In all cases, a small proportion of the TH-immunoreaative nerve cell bodies in RD were retrogradely radiolabeled. Radiolabeled but immunonegative cells were exceedingly rare. The double-labeled neurons were generally more numerous after elimination of the nigrostriatial DA innervation than in normal rats. They mostly lay within the ventral portion of the medial subdivision of RD and always predominated on the [3H]NA- injected side. Some were also present in nucleus linearis caudalis. It was concluded that (1) [3H]NA had been taken up and retrogradely transported exclusively by catecholamine neurons; (2) part of the DA cell group in RD projects to the neostriatum; and that (3) most if not all non-5-HT neurons projecting from RD to neostriatum are likely to be dopaminergic.
The effects of the selective 5-HT1A receptor agonist (R)-8-hydroxy-2(di-n-propylamino)tetralin [(R)-8-OH-DPAT] and the novel 5-HT1A antagonist (S)-5-fluoro-8-hydroxy-2-(dipropylamino)-tetralin [(S)-UH-301] were studied with regard to the firing pattern of single mesencephalic dopamine (DA) neurons with extracellular recording techniques in chloral hydrate anesthetized male rats. Neuronal activity was studied with respect to firing rate, burst firing and regularity of firing. In the ventral tegmental area (VTA) low doses of (R)-8-OH-DPAT (2–32 g/kg i.v.) caused an increase in all three parameters. The effect on firing rate of DA neurons was more pronounced in the parabrachial pigmentosus nucleus than in the paranigral nucleus, the two major subdivisions of VTA. In the substantia nigra zona compacta (SN-ZC), (R)-8-OH-DPAT (2–256 g/kg i.v.) had no effect on firing rate and regularity of firing and only slightly increased burst firing. High doses of (R)-8-OH-DPAT (512–1024 g/kg i.v.) decreased the activity of DA cells in both areas, an effect that was prevented by pretreatment with the selective DA D2 receptor antagonist raclopride. (S)-UH-301 (100–800 g/kg i.v.) decreased both firing rate and burst firing without affecting regularity of DA neurons in the VTA. In the SN-ZC, (S)-UH-301 decreased the firing rate but failed to affect burst firing and regularity of firing. These effects of (S)-UH-301 were blocked by raclopride pretreatment. Local application by pneumatic ejection of 8-OH-DPAT excited the DA cells in both the VTA and the SN-ZC, whereas (S)-UH-301 inhibited these cells when given locally. These results show that 5-HT1A receptor related compounds differentially affect the electrophysiological activity of central DA neurons. The DA receptor agonistic properties of these compound appear to contribute to the inhibitory effects of high doses of (R)-8-OH-DPAT and (S)-UH-301 on DA neuronal activity. Given the potential use of 5-HT1A receptor selective compounds in the treatment of anxiety and depression their effects on central DA systems involved in mood regulation and reward related processes are of considerable importance.
The localization and distribution of serotonin (5-hydroxytryptamine, 5-HT) has been studied with the indirect immunofluorescence technique using a highly specific and well-characterized antibody to 5-HT. In neuron systems 5-HT was found to be primarily present with a distribution similar to that observed in basic mappings carried out with the formaldehyde-induced fluorescence method. In addition to the nine areas originally described, several other areas in the mesencephalon and rhombencephalon appeared to contain widely distributed 5-HT-positive perikarya. In the median eminence 5-HT fluorescent mast cells could be visualized. No 5-HT-positive nerve cell bodies could be observed either in the telencephalon or diencephalon.
Extracellular unit recordings were made from pontine reticular neurons in the cat and cells of the motor cortex in monkeys. In all cases, the characteristics of responses to electrical stimulation were studied using the tests of invariance of latency, high frequency following, and collision for determining the orthodromic or antidromic nature of the responses. The results of these tests show that their conclusions are not always consistent. A systematic error was found between the experimental and predicted values of the collision interval. It is argued that this error is due to differences in the application of measured parameters in calculating the collision interval. The collision test can be considerably improved by repeating the test with stimuli of progressively greater strengths.
Fast cyclic voltammetry (FCV) at carbon fibre microelectrodes was used to monitor the time course of changes in extracellular concentration of endogenous 5-hydroxytryptamine ([5-HT]ex), in slices of rat brain containing either dorsal raphe nucleus (DRN) or suprachiasmatic nucleus (SCN). Five- or 20-pulse electrical stimulation trains were applied at frequencies between 5 and 500 Hz. [5-HT]ex was frequency and train length dependent, with maximum overflow in both sites at 100 Hz. Methiothepin (0.1 microM) caused a significant increase in [5-HT]ex when 5 pulses were applied at 5 Hz or when 20 pulses were applied at 10 or 20 Hz, but not at higher frequencies. When a single pseudo single pulse stimulation was used (5-pulse train at 100 Hz), methiothepin (0.1 microM) did not enhance [5-HT]ex in either the DRN or SCN; when 4 such pseudo single pulses were applied at 1 Hz methiothepin (0.1 microM) enhanced [5-HT]ex. A minimum period of stimulation of between 400 ms and 1 s was required for autoreceptor activation to occur in both regions. We conclude that [5-HT]ex can show a wide dynamic range of response to electrical stimulation, and that in both DRN and SCN it is subject to pulse-to-pulse regulation by presynaptic autoreceptors.
Midbrain dopamine neurons of the zona compacta substantia nigra (SN) and ventral tegmental area (VTA), giving rise to the nigrostriatal and mesolimbocortical midbrain dopamine pathways, respectively, typically display a spontaneous activity consisting of single spikes and bursts. Previously, intracerebroventricular administration of the excitatory amino acid (EAA) antagonist kynurenate has been shown to inhibit burst firing and induce a regular, pacemaker-like firing of ventral tegmental area midbrain dopamine neurons. In the present experiments, zona compacta substantia nigra and ventral tegmental area midbrain dopamine neurons were recorded in the chloral hydrate anaesthetized male rat. Kynurenate was administered locally, either by micro-iontophoresis or by pneumatic (micropressure) ejection. Both forms of local kynurenate application produced an immediate inhibition of burst firing and a slightly increased regularity of firing in both zona compacta substantia nigra and ventral tegmental area midbrain dopamine neurons. The present results indicate that excitatory amino acid nerves tonically modulate midbrain dopamine neuronal burst firing directly on the midbrain dopamine cell bodies, further stressing the importance of excitatory amino acid innervation in the physiological function of midbrain dopamine neurons, particularly in the dynamic aspects involved in the behavioural modulation and pharmacological responses of these psychopharmacologically important neurons.
The existence of a dopamine (DA) projection from nucleus raphe dorsalis (RD) to neostriatum was demonstrated in the rat by combined tyrosine hydroxylase (TH) immunohistochemistry and radioautography after retrograde axonal transport of [3H]noradrenaline ([3H]NA). Intrastriatal injections of [3H]NA were carried out in normal rats or after ipsilateral destruction of the nigrostriatal DA system by injection of 6-hydroxydopamine (6-OHDA) into the substantia nigra. Some 1,000 TH-positive nerve cell bodies were counted within the confines of RD as defined by its content in serotonin (5-HT) neurons. These DA neurons occupied the upper third of the RD and they were part of its small cell population. In all cases, a small proportion of the TH-immunoreactive nerve cell bodies in RD were retrogradely radiolabeled. Radiolabeled but immunonegative cells were exceedingly rare. The double-labeled neurons were generally more numerous after elimination of the nigrostriatal DA innervation than in normal rats. They mostly lay within the ventral portion of the medial subdivision of RD and always predominated on the [3H]NA- injected side. Some were also present in nucleus linearis caudalis. It was concluded that [3H]NA had been taken up and retrogradely transported exclusively by catecholamine neurons; part of the DA cell group in RD projects to the neostriatum; and that most if not all non-5-HT neurons projecting from RD to neostriatum are likely to be dopaminergic.
The objective of the present study was to characterize the morphology of serotoninergic axons in cerebral cortex of the rat and to determine whether dissimilar axon terminals arise from the dorsal vs. the median raphe nuclei. The anterograde tracer PHA-L was administered by iontophoresis into the dorsal (DR) and median (MR) raphe nuclei, and the morphologic features of the respective axonal projections from raphe to forebrain were analyzed. We have observed consistent structural differences between the axons from these two nuclei. Anterogradely labeled axons which arise from cells in the MR are characterized by large, spherical varicosities (type M axons) and by variations in axonal diameter. In contrast, DR fibers are very fine and typically have small, pleomorphic varicosities that are granular or fusiform in shape (type D axons). Similar features of serotonin (5-HT) axon morphology are also evident in 5-HT immunocytochemical preparations. In addition to structural differences, there is a differential topographic distribution of MR vs. DR fibers, with MR axons concentrated in particular areas of limbic cortex such as dentate gyrus, posterior cingulate, and entorhinal areas as well as in parietal cortex. Immunofluorescence with dual labels shows that over two-thirds of the raphe-cortical axons are serotoninergic. The dissimilarities in axon morphology indicate that individual raphe nuclei may form different patterns of synaptic organization. Based on the evidence that the dorsal and median raphe nuclei give rise to morphologically different axon terminals, we conclude that 5-HT axons in cortex may be subdivided into two distinct projections. This proposal is in accord with other, recent data showing that the two axon types have different pharmacologic properties and are likely to be functionally different.
The class of rapidly firing neurons in the dorsal raphe of the rat was examined using extracellular recording and intracellular injection of horseradish peroxidase. Rapidly firing neurons (termed F-cells in this report) continue to fire at high spontaneous rates during intracellular recording. This and their brief (ca. 1 ms) and symmetrical action potentials distinguish them from the slowly firing, presumably serotonergic neurons in dorsal raphe. Intracellular labeling with horseradish peroxidase reveals that F-cells have small (10-15 microns) spherical, multipolar or piriform somata. Somatic spines are sparse or entirely absent. The general form of the dendritic tree is radiant and poorly branching. However, the dendrites of F-cells take two forms, with both forms being present on the same neuron so that besides having a complement of poorly branching dendrites, each F-cell has at least one dendrite with a slightly tufted branching pattern: a short primary dendrite gives rise to 3 or 4 secondary branches. The axons of F-cells project from the nucleus. They align themselves along the trajectories of known dorsal raphe efferent pathways, coursing laterally and ventrorostrally beyond the bounds of the nucleus. Morphometric measurements of retrogradely labeled dorsal raphe projection neurons provide additional evidence that small projection neurons exist.
Extracellular single unit recordings were made in the median raphe nucleus from rats anaesthetized with urethane. Spontaneous firing as well as orthodromic and antidromic responses to stimulation of the fornix and the medial septum were studied. One hundred and twelve units (out of a total of 355) with a regular spontaneous firing rate of 0.2-3 spikes/s were classified as serotonin-containing neurons. Fifty nine of them were antidromically invaded from either the fornix or the medial septum (conduction velocity, 0.8 m/s) and 7 additional neurones from both the fornix and the medial septum. Antidromic action potentials were followed by a period of decreased probability of firing, that was already present below threshold for antidromic invasion, were proportional to the stimulation intensity and had a latency similar to orthodromic inhibition. No preferential topographical distribution within the median raphe nucleus was observed for the serotonin neurones, even those invaded antidromically. Twenty six neurones with a clear-cut anatomical location around the borders of the median raphe nucleus showed a spontaneous rhythmic activity (4-20 spikes/s) characterized by the presence of extremely prolonged silent periods (up to 5 min). Only one of these neurones was invaded antidromically from the medial septum and none from the fornix. Of the remaining non-serotonin neurones, 28 showed a very low firing rate consisting of single action potentials every 10-60 s while 189 had a spontaneous activity of 6-30 spikes/s. Regardless of their firing rate they were all antidromically invaded from the fornix and/or the medial septum and had a conduction velocity of 5 m/s. These experiments demonstrate the electrophysiological heterogeneity of the neuronal population of the median raphe nucleus, the presence of strong projections of both putative serotonin and non-serotonin neurones to the medial septum and, via the fornix, to the hippocampus, and the existence of axonal branching in both types of neurones.
Impulses in rat locus coeruleus neurons exhibit pronounced conduction latency decreases, followed by even larger latency increases (of over 20 msec in some cases) during a single train of antidromic activation. The magnitude of latency fluctuation varies as a function of basal antidromic latency, frequency of stimulation, and number of stimuli in a train. These and additional data indicate that this variability in latency is a consequence of altered impulse conduction velocity along the axons, perhaps reflecting reduced ion concentration gradients resulting from impulse propagation. These latency changes may allow thin unmyelinated axons to influence target cells most effectively with short bursts of activity, and suggest that myelination and large axon diameter provide for high fidelity as well as for high velocity of impulse flow in nervous tissue.
Variations in the antidromic latency of substantia nigra compacta neurones were commonly observed following striatal stimulation. These results provide electrophysiological evidence for a branched unmyelinated nigrostriatal pathway and demonstrate that the antidromic criterion of constant latency is not valid for this type of pathway.
Acute systemic injection of selective serotonin reuptake inhibitors (SSRIs) decreases 5-HT neuronal firing in the dorsal raphe nucleus (DRN). Recent data, however, question whether these drugs also inhibit the firing of 5-HT neurones in the median raphe nucleus (MRN). Using in vivo extracellular electrophysiological recording techniques in the chloral hydrate anaesthetised rat, we have tested the effect of acute administration of the SSRI, paroxetine, on 5-HT neuronal activity in the MRN and DRN. Presumed 5-HT neurones in the MRN displayed the same electrophysiological characteristics as those in the DRN, the only detectable difference being that MRN neurones showed a significantly (p < 0.001) slower mean (+/- SEM(n)) spontaneous firing rate (MRN, 5.6 +/- 0.9 (14) spikes/10 s; DRN, 13.5 +/- 1.6 (24) spikes/10 s). Paroxetine caused a dose-related (0.1-0.8 mg/kg i.v.) inhibition of all MRN neurons tested (n = 8), producing a complete cessation of cell-firing at the highest doses. DRN neurones (n = 9) responded in a similar fashion. Furthermore, paroxetine inhibited MRN and DRN neurones with almost identical potency (MRN ED50 259 +/- 57 micrograms/kg i.v.: DRN ED50 243 +/- 49 micrograms/kg i.v.). In the majority of cells tested, the effect of paroxetine was reversed by the 5-HT1A receptor antagonists spiperone or (+)WAY100135, implicating the involvement of the 5-HT1A autoreceptor. The selective 5-HT1A receptor agonist 8-OH-DPAT also inhibited the firing of MRN (n = 5) and DRN (n = 12) neurones and with equal potency (MRN ED50, 1.32 +/- 0.40 microgram/kg i.v.: DRN ED50, 1.19 +/- 0.23 microgram/kg i.v.).(ABSTRACT TRUNCATED AT 250 WORDS)
Central dopaminergic neurons exhibit two kinds of discharge activity: single spikes and bursts of two to six action potentials. Since these neurons can switch from one discharge pattern to the other whereas the mean discharge rate remains little affected, bursts may be more potent in triggering the release of their neurotransmitter, dopamine. Electrical stimulations mimicking the bursting pattern were actually twice as potent as regularly spaced stimulations to enhance the dopamine extracellular concentration. This suggested that dopamine release might be facilitated by increasing the impulse flow frequency. The high extracellular overflow evoked by a burst might also be due to accumulation of the released dopamine whereas, at lower frequencies, dopamine might be readily eliminated between every action potential. In the present study the dopamine overflow evoked by electrical stimulation of the dopaminergic pathway was measured in vivo by carbon fibre electrodes combined with continuous amperometry. We observed a small facilitation of the release per pulse during stimulations mimicking a burst but only in mesolimbic areas. The high extra-cellular dopamine level evoked by a burst was mainly due to accumulation of the released dopamine.
Serotonergic neurons are thought to play a role in depression and obsessive compulsive disorder. However, their functional transmitter repertoire is incompletely known. To investigate this repertoire, intracellular recordings were obtained from 132 cytochemically identified rat mesopontine serotonergic neurons that had re-established synapses in microcultures. Approximately 60% of the neurons evoked excitatory glutamatergic potentials in themselves or in target neurons. Glutamatergic transmission was frequently observed in microcultures containing a solitary serotonergic neuron. Evidence for co-release of serotonin and glutamate from single raphe neurons was also obtained. However, evidence for gamma-aminobutyric acid release by serotonergic neurons was observed in only two cases. These findings indicate that many cultured serotonergic neurons form glutamatergic synapses and may explain several observations in slices and in vivo.
Recently, we described neurones in the rat dorsal raphe nucleus (DRN) with electrophysiological characteristics typical of 5-hydroxytryptamine (5-HT) neurones except that the neurones fired brief bursts. Here we report the effect of 5-HT lesions on the incidence of these burst-firing neurones. In vivo extracellular recordings revealed that in rats pretreated with the selective 5-HT neurotoxin, 5,7-dihydroxytryptamine, the occurrence of typical 5-HT neurones was significantly decreased (80%) compared to controls. In these 5-HT lesioned animals, the number of the burst-firing DRN neurones was also significantly reduced (91%). Neurones previously characterised as not containing 5-HT, were not altered by the lesion. These data are further evidence to support our hypothesis that burst-firing neurones in the DRN contain 5-HT.
Raphe nuclei and serotonin containing systems The Rat Nert'ous System
- T Irk
T(irk, I., Raphe nuclei and serotonin containing systems. In G. Paxinos (Ed.), The Rat Nert'ous System, Academic Press, Sydney, 1985, pp. 43 78.
Raphe nuclei and serotonin containing systems
- Törk
Structure and function of the brain serotonin system
- Jacobs