Differing properties of putative fast-spiking interneurons in the striatum of two rat strains.

Local circuits within the striatum of the basal ganglia include a small number of γ-aminobutyric acid (GABA)-ergic fast-spiking interneurons (FSI). The number of these cells is reduced in disorders of behavioral control, but it is unknown whether this is accompanied by altered electrophysiological properties. The genetically hypertensive (GH) rat strain exhibits impulsiveness and hyperactivity. We investigated if resting-state FSI activity is affected in this strain using extracellular recordings. We also examined the effect of systemic amphetamine (AMPH), a stimulant drug used in the treatment of these particular behavioral deficits. Putative FSI (pFSI) were encountered less often in GH rats compared to the Wistar control strain. pFSI in GH rats also exhibited a higher mean firing rate, higher intraburst firing rate, lower interburst interval, and shorter bursts compared to controls. AMPH increased the mean overall firing rate of Wistar rat pFSI but did not significantly alter the firing properties of this subtype in GH rats. These differences in the resting-state electrophysiological activity of pFSI in GH rats point to them as a cell type of particular interest in understanding striatal functioning across different strains.

Enhanced c-Fos expression in superior colliculus, paraventricular thalamus and septum during learning of cue-reward association.

Reward-mediated associative learning is important for recognizing the significance of environmental cues. Such learning involves convergence of multimodal sensory inputs with circuits involved in affective and memory processes. Dopamine-dependent plasticity in the striatum plays a pivotal role, but the wider circuits engaged in cue-reward association are poorly understood. To identify candidate structures that may be of particular interest for further detailed electrophysiological and functional analysis, we quantified c-Fos expression in a selection of brain structures. c-Fos is a well-known marker of cell activation with additional potential importance for synaptic plasticity. We compared c-Fos expression between animals exposed to 100 pairings of a novel conditioned stimulus with a subsequent reward, and control animals exposed to the same number of cues and rewards, but where the cues and rewards occurred at random with respect to each other. We found significant increases in c-Fos expression in the superior colliculus in the group exposed to cue-reward pairing. This is consistent with previous recordings in conscious animals, showing modulation of phasic visual responses of single collicular neurons depending on their association with reward. Further, the data also suggest the possibility that the thalamic paraventricular nucleus and septal nuclei may be selectively activated during cue-reward association learning. Little is known of the neurophysiological responses in these structures during such tasks, so the present results suggest they would be targets of interest for future single-neuron recording experiments, designed to confirm whether the neurons show learning-specific modulation.

Regulation of hind-limb tone by adenosine A2A receptor in rats.

Adenosine A2A receptor agonists produce a hypokinetic state (catalepsy) that is believed to reflect antagonistic interaction of A2A and dopamine D2 receptors in the basal ganglia. In addition to catalepsy, pharmacological blockade of D2 receptors produces rigidity. However there are conflicting data about the effect of A2A agonists on muscle tone, with some reports indicating an increase, while other data suggest that A2A catalepsy is dominated by muscle hypotonia. We investigated the effect on resistance to imposed movements of systemic cataleptic doses of the selective A2A agonist CGS21680 (5 mg/kg), and compared it with the effect of the D2 antagonist raclopride (5 mg/kg), in rats. Total resistance is made up of elastic and viscous components. The elastic component is velocity independent, and is referred to as "stiffness," whereas viscosity, which dampens responses to imposed movements, is velocity dependent. Using a method for quantifying total joint resistance that enabled separate identification of stiffness and viscosity, we found that during catalepsy evoked by either drug there was a clear increase in joint rigidity. Both CGS21680 and raclopride significantly increased joint stiffness, the velocity independent component of rigidity that is most affected in Parkinsonism. In contrast, the effect of CGS21680 on the velocity-dependent viscosity component was less robust than for raclopride, and did not reach significance, possibly reflecting an interaction with sedative effects via extrastriatal receptors. The effect of CGS21680 and raclopride on joint stiffness is thus consistent with previous findings suggesting functional antagonism of A2A and D2 receptors in the basal ganglia.

Biomechanical and electromyogram characterization of neuroleptic-induced rigidity in the rat.

Rodent models of Parkinson's disease (PD) are usually assessed using measures of akinesia, but other important parkinsonian symptoms such as rigidity are only rarely quantified. This is in part due to technical difficulties in obtaining such measures in small animals. In the present study we developed quantitative methods to provide time-course assessment of the alternations of muscle tone of parkinsonian rats. A portable and miniature biomechanical stretching device was established to manually stretch the hindlimb of awake rats with muscle rigidity induced by dopamine D2-receptor antagonist raclopride (5 mg/kg, i.p.). From the measured angular displacement angle and reactive torque of sinusoidal stretches at five varied frequencies, viscoelastic components of the muscle tone can be derived. In addition, non-invasive multielectrode was applied to record the tonic and phasic components of the gastrocnemius muscle electromyogram (EMG). Our biomechanical measurements showed not only increase in stiffness (P<0.05) but also increase in viscous components (P<0.05) that matched the time course of increased amplitude of EMG activity (P<0.05). There was a significant positive correlation between all of these measures and akinesia, as measured by the conventional bar-test for catalepsy (with a correlation coefficient of 0.87 at stiffness, 0.92 at viscosity and 0.96 at amplitude of EMG). Phasic contraction counts (PCC) of voluntary EMG exhibited a significantly negative correlation with the bar test scores (correlation coefficient=-0.78). These results confirm that akinesia induced by D2-receptor blockade also induces a rigidity that shares many features with human PD. These novel techniques for quantifying biomechanical and electromyographic parameters provide objective assessment methods for investigating the time-course changes of abnormal muscle tone in rat models of PD that will be useful for evaluating novel treatments.

Firing modes of midbrain dopamine cells in the freely moving rat.

There is a large body of data on the firing properties of dopamine cells in anaesthetised rats or rat brain slices. However, the extent to which these data relate to more natural conditions is uncertain, as there is little quantitative information available on the firing properties of these cells in freely moving rats. We examined this by recording from the midbrain dopamine cell fields using chronically implanted microwire electrodes. (1) In most cases, slowly firing cells with broad action potentials were profoundly inhibited by the dopamine agonist apomorphine, consistent with previously accepted criteria. However, a small group of cells was found that were difficult to classify because of ambiguous combinations of properties. (2) Presumed dopamine cells could be divided into low and high bursting (>40% of their spikes in bursts) groups, with the majority having low bursting rates. The distribution of burst incidence was similar to that previously reported with chloral hydrate anaesthesia, but the average intraburst frequency was higher in the conscious animal at rest and was higher again in bursts triggered by salient stimuli. (3) There was no evidence for spike frequency adaptation within bursts on average, consistent with the hypothesis that afterhyperpolarisation currents may be disabled during behaviourally induced bursting. (4) Presumed dopamine cells responded to reward-related stimuli with increased bursting rates and significantly higher intraburst frequencies compared to bursts emitted outside task context, indicating that modulation of afferent activity might not only trigger bursting, but may also regulate burst intensity. (5) In addition to the irregular single spike and bursting modes we found that extremely regular (clock-like) firing, previously only described for dopamine cells in reduced preparations, can also be expressed in the freely moving animal. (6) Cross-correlation analysis of activity recorded from simultaneously recorded neurones revealed coordinated activity in a quarter of dopamine cell pairs consistent with at least "functional" connectivity. On the other hand, most dopamine cell pairs showed no correlation, leaving open the possibility of functional sub-groupings within the dopamine cell fields. Taken together, the data suggest that the basic firing modes described for dopamine cells in reduced or anaesthetised preparations do reflect natural patterns of activity for these neurones, but also that the details of this activity are dependent upon modulation of afferent inputs by behavioural stimuli.

A cellular mechanism of reward-related learning.

Positive reinforcement helps to control the acquisition of learned behaviours. Here we report a cellular mechanism in the brain that may underlie the behavioural effects of positive reinforcement. We used intracranial self-stimulation (ICSS) as a model of reinforcement learning, in which each rat learns to press a lever that applies reinforcing electrical stimulation to its own substantia nigra. The outputs from neurons of the substantia nigra terminate on neurons in the striatum in close proximity to inputs from the cerebral cortex on the same striatal neurons. We measured the effect of substantia nigra stimulation on these inputs from the cortex to striatal neurons and also on how quickly the rats learned to press the lever. We found that stimulation of the substantia nigra (with the optimal parameters for lever-pressing behaviour) induced potentiation of synapses between the cortex and the striatum, which required activation of dopamine receptors. The degree of potentiation within ten minutes of the ICSS trains was correlated with the time taken by the rats to learn ICSS behaviour. We propose that stimulation of the substantia nigra when the lever is pressed induces a similar potentiation of cortical inputs to the striatum, positively reinforcing the learning of the behaviour by the rats.

Parameter precuing and motor preparation.

A movement task was used to investigate the effects of precued variables on reaction time. The task involved rapid rotation of a hand-held manipulandum to target locations and required either pronation or supination of the forearm through short or long extent. The effects on reaction time of precues signalling target direction, extent, or a combination of direction and extent, were measured. The longest reaction times occurred when no information about direction or extent was provided in the precue (all parameters uncertain). Complete prior specification of target position produced the shortest reaction times. Specification of direction when extent was uncertain produced a significantly larger reduction in reaction time than specification of extent when direction was uncertain. Prior specification of extent also produced a small but significant reduction in reaction time relative to the condition in which direction and extent were specified in a mutually conditional manner. The results are discussed in relation to parameter precuing and motor programming, in which the direction is programmed by the pre-selection of neurons representing the muscles to be used in the task while programming of extent is represented by their level of activity during task performance.

Foreperiod length, but not memory, affects human reaction time in a precued, delayed response.

The effect of foreperiod length on reaction time in memorized (MM) and nonmemorized (NM), precued, delayed responses was investigated. Six subjects participated in one long and one short foreperiod schedule testing session. An aiming task, using elbow supination/pronation, in response to a visual stimulus was employed. In the MM condition, target spatial information was available for a fraction of the foreperiod duration. In the NM condition, target information was available continuously until the subject attained the target position. Subjects responded with a significantly longer latency in the long foreperiod schedule. Within each foreperiod schedule, the shortest foreperiod resulted in significantly longer reaction time. However, the absolute value of foreperiod did not have a major effect on reaction time latency. Memorization and nonmemorization conditions did not affect reaction time.

Muscle activity during forelimb reaching movements in rats.

The absolute timing, and correlation in time of activity in a number of shoulder, elbow and wrist muscles in the rat was analysed in relation to onset and termination of the extension phase of a skilled forelimb reaching movement. Movement onsets were analysed separately in the component upward, forward and medial directions. On average, movements in the upward and medial directions occurred together, prior to forward movement. Latissimus dorsi activity was the earliest muscle event, occurring approximately 150 ms prior to movement, whilst onset of teres major activity, possibly related to paw elevation, had the highest temporal correlation with movement onset. Triceps activity was strongly time locked to the end of the reach, and may have provided final extensor thrust to complete the reaching movement. Although it is possible to speculate on possible roles of particular EMG bursts, multiple (often anatomically antagonistic) muscles were active at all stages of the reach, and no unique muscle relationships to initiation of individual movement components could be identified. It is concluded that reaching movements are produced by temporal variation in distributed activity among all available muscles.

Luteinizing hormone release in the anesthetized cat following stimulation in the diagonal band of Broca, dorsal septum and fornix.

The release of luteinizing hormone (LH) in response to electrical stimulation of septal nuclei (the diagonal band of Broca, DBB, and dorsal septal nucleus) and the subcallosal fornix has been studied in gonadectomized female cats. The cats were anesthetized with Althesin. Electrodes were placed on the medial and lateral aspects of the subcallosal fornix and paired bipolar stimulating electrodes were aimed at the DBB or dorsal septal nucleus. The effect of electrical stimulation of these regions on the secretion of LH was studied by radioimmunoassay of LH in serial blood samples taken before, during and after stimulation. Stimulation in the DBB or in the dorsal septal nucleus resulted in a peak of LH release during stimulation followed by further spontaneous peaks. All peaks showed an exponential decline. The frequency of spontaneous peaks following stimulation could reach the level found in unanesthetized cats. Stimulation of the subcallosal fornix produced a significant depression in the amplitude of LH release. The effects of DBB, dorsal septal and fornix stimulation are all exerted, we suggest, by projections to LHRH containing neurons in the preoptic region.

Responses in the diagonal band of Broca, adjacent septal nuclei and the islands of Calleja of cats to stimulation of the subcallosal fornix, medial basal hypothalamus and medial forebrain bundle.

The projection of neurons in the septal nuclei and the insula magna of the islands of Callaja (IC) was explored together with their response to stimulation of the fornix. The septal nuclei all contained neurons projecting in the medial forebrain bundle (MFB). Only the diagonal band of Broca (DBB) and the lateral septal nucleus (LS) contained many neurons projecting toward the medial basal hypothalamus (MBH). The spatial distribution of neurons excited by stimulation of the fornix in the DBB was almost identical with the distribution of neurons projecting toward the MBH and there was considerable overlap (10/28 cells). In the medial septal nucleus the spatial distribution of neurons excited by stimulation of the fornix and neurons projecting in the MFB was similar and there was considerable overlap (6/21 cells). The connectivity of the IC resembled that of the MS but there was little overlap between the neurons excited by fornix stimulation and those projecting in the MFB (1/27 cells). In the LS there were almost equal numbers of neurons projecting in the MFB and toward the MBH but there was very little input from the fornix. Neurons were significantly more often excited by stimulation of the lateral fornix, carrying axons from the subiculum, than they were by medial stimulation exciting axons from Ammon's horn. Axons projecting toward the MBH or in the MFB had conduction velocities less than 1 m/s.

Stimulation of the LH release by naloxone in anaesthetized cats after ovariectomy.

The effect of intravenous injections or infusions of the opioid receptor antagonist naloxone on the secretion of luteinizing hormone (LH) was studied in 18 spayed cats anaesthetized with Althesin. Effective injections significantly increased the LH concentration of plasma samples (taken every 10-15 min and measured by radio-immunoassay) to a peak 20-30 min after injection. The concentration thereafter declined exponentially (ke = 0.42), and, in 4/8 trials rose again significantly and declined again without further injection. The threshold dose was between 0.4 and 0.5 mg/kg. There did not appear to be a dose dependence of the effect above threshold. Infusion of naloxone at levels up to 5 mg/kg/h was effective in producing a pulsatile release of LH and repeated injections of threshold doses (0.5 mg/kg) could produce a maintained plateau and pulsatile release at frequencies comparable to pulse frequencies in vivo.

Distribution and projection of single units in the cat preoptic region responding to stimulation of the medial amygdala.

Neuronal responses were recorded extracellularly in the preoptic region of 11 male castrate cats following stimulation in the 'medial' group of amygdalar nuclei (medial, basomedial, basolateral). The latency of responses varied with the site of stimulation and could be explained if connections to the preoptic region were made through both the stria terminalis and the ventral amygdalofugal pathway. Projection of 13% of orthodromically excited preoptic units to the medial basal hypothalamus was established by collision tests following stimulation in these regions. The amygdalar excitation was probably exerted through the amygdalofugal pathway. In 5/6 cats the amygdalar stimulation was successfully used to raise plasma LH levels. In one cat no preoptic units projecting to the medial basal hypothalamus were found and in the cat which failed to increase plasma LH in response to amygdala stimulation, 5 such units were found. We conclude the pathway from the amygdala through the preoptic region to the hypothalamus may not be the way in which amygdalar stimulation affects LH release in the cat. Projection of 10% of orthodromically excited preoptic units in the medial forebrain bundle was established by collision tests in 3 cats. These identified units were driven from amygdalar sites thought to project to the preoptic region by ventral amygdalofugal pathways.

Responses of cat preoptic neurons to stimulation of the medial frontal cortex and the medial basal hypothalamus.

Responses of single preoptic neurons to electrical stimulation of the medial frontal cortex, the mediobasal hypothalamus (MBH) and the medial forebrain bundle (MFB) were recorded in anaesthetised cats. Single pulse stimulation of the medial frontal cortex orthodromically drove 96 otherwise quiescent preoptic neurons, which were found more frequently in the dorsal preoptic region, inhibited 53% of the spontaneously active preoptic neurons and excited 16%. Testing of cortically influenced preoptic neurons with MBH or MFB stimulation resulted in antidromic invasion of 6% (MBH) and 9% (MFB). Convergence of orthodromic inputs from medial frontal cortex and MBH was detected in 78% of spontaneously active preoptic neurons, and three-way convergence including input from MFB was noted in 17% of neurons tested with all stimulators. Some cortex-response neurons were found to also respond to vaginal or anal probing, paw squeezing and haemorrhage. The role of this input to the preoptic region from medial frontal cortex remains to be elucidated, but may include neuroendocrine, behavioural and homeostatic functions.

Luteinizing hormone release in the anaesthetised cat following electrical stimulation of limbic structures.

The release of luteinizing hormone (LH) in response to electrical stimulation of limbic centres, namely the medial preoptic region (MPO) medial basal hypothalamus (MBH) and the medial amygdala (AME) has been studied in the anaesthetised gonadectomized cat. Chronically gonadectomized cats were anaesthetised with pentobarbitone or Althesin and paired bipolar stimulating electrodes were aimed at the MPO, AME or MBH. The effect of electrical stimulation of these regions on the secretion of LH was studied by radio-immunoassay of LH in serial blood samples taken before, during and after stimulation. No change in plasma LH in response to electrical stimulation was ever recorded during pentobarbitone anaesthesia. During Althesin anaesthesia stimulation in the MPO more often than not resulted in a peak of LH release during stimulation. A peak release of LH during stimulation was also recorded when electrodes were placed in the arcuate-median eminence region of the MBH. The time-course of these peaks in LH secretion was similar to the time-course of the plasma LH responses recorded following a single intravenous injection of gonadotrophin-releasing hormone (GnRH). In contrast, electrodes placed in AME had no effect on plasma LH during electrical stimulation, but immediately after stopping it, a small LH peak was recorded. The time-course of these responses suggests a pulse release of GnRH, the rapid response to MPO and MBH stimulation possibly being the result of a direct action on GnRH neurons while the delayed AME response may be produced by AME projections to the GnRH release system. These responses could be likened to the surge of LH which in the cat occurs post-coitus.

Does the precommissural fornix excite neurons in the cat dorsal septum which project to the medial preoptic region?

The possibility that effects of fornix stimulation on units in the medial preoptic region (MPO) may be via an interposed neuron in the dorsal septum was investigated using electrophysiological techniques. We found a reciprocal monosynaptic linkage between the MPO and the dorsal, medial and fimbrial septal nuclei. When recording in the MPO, stimulation of the dorsal septum affected 59% of spontaneously active units. Of all MPO units synaptically excited by stimulation of the dorsal septum 33% also had an input from the fornix. When recording in the dorsal septum during stimulation of the MPO and fornix, units synaptically driven by, or antidromically invaded following MPO stimulation, were found in caudal regions of the DS and units excited by stimulation of the fornix were located in more rostral regions. Units excited by stimulation of the fornix were never antidromically invaded following stimulation in the MPO, so there was no direct pathway for fornix excitation in the dorsal septum to reach the MPO.

Electrophysiological evidence for a projection from medial prefrontal and anterior limbic cortex toward the medial preoptic area in the cat.

Neurons in cat medial prefrontal cortex, anterior limbic cortex and possibly the indusium griseum were identified by antidromic invasion as having axonal projections towards the medial preoptic region, using both macro- and microstimulation techniques. These projecting axons were found to be of slow conduction velocity (0.2-4.8 m/s) and to in some cases also send branches towards the anteromedial thalamus, mediodorsal thalamus, ventromedial tegmentum, basolateral amygdala or medial forebrain bundle. Threshold-depth curves for axons excited by microstimulation in the medial preoptic region were very steep, with proportionality constants of 0.3-7.1 micron/microA. Calculations based on the threshold-depth curves confirmed that microstimulation was most probably only activating axons within the MPO, and current spread to lateral fibers of passage following macrostimulation in the MPO was not detected in the branching studies.