Oviposition in the onion fly Delia antiqua (Diptera: Anthomyiidae) is socially facilitated by visual cues.

Ovipositional decisions in herbivorous insects may be affected by social information from conspecifics. Social facilitation of oviposition has been suggested for the onion fly Delia antiqua. In the current study, we found that D. antiqua oviposition was unequal between paired oviposition stations of equal quality and that more eggs were laid on an oviposition station baited with decoy flies than on the control. The increased oviposition toward the decoys continued over time >8 h. When decoys were placed upside down, the number of eggs laid did not differ between the decoy and control sides of oviposition stations, suggesting that social facilitation of oviposition is mediated by visual cues. Based on these findings, mechanisms of social facilitation of oviposition in D. antiqua were discussed.

Phase-dependent activity of neurons in the rostral part of the thalamic reticular nucleus with saccharin intake in a cue-guided lever-manipulation task.

Neurons in the rostral part of the thalamic reticular nucleus (rTRN) receive somatosensory and motor information and regulate neural activities of the thalamic nuclei. Previous studies showed that when activity in visual TRN neurons is suppressed prior to the visual stimuli in a visual detection task, the performance of the task improves. However, little is known about such changes in the rTRN preceding certain events. In the present study, we performed unit recordings in the rTRN in alert rats during a cue-guided lever-manipulation task in which saccharin was provided as a reward. Changes in neural activity during saccharin intake were observed in 56% (51 of 91) of the recorded neurons; the firing rates increased in 21 neurons and decreased in 23 neurons. Seven neurons both increased and decreased their firing rates during saccharin intake. Changes in firing rates during the reward-waiting stage between task termination and saccharin intake were also observed in 73% (37 of 51) of the neurons that responded to saccharin intake. Increased activity during saccharin intake did not correlate with increased activity during lever-manipulation or activity during the reward-waiting stage. However, decreased activity during saccharin intake was correlated with activity during the reward-waiting stage. These results suggest that rTRN neurons have phase-dependent changes in their activity and regulate the thalamic activities. Furthermore, the decreased activity of rTRN neurons before reward may contribute to refine somatosensory and motor information processing in the thalamic nuclei depending on the status of mind such as expectation and attention.

Spike Timing Rigidity Is Maintained in Bursting Neurons under Pentobarbital-Induced Anesthetic Conditions.

Pentobarbital potentiates γ-aminobutyric acid (GABA)-mediated inhibitory synaptic transmission by prolonging the open time of GABAA receptors. However, it is unknown how pentobarbital regulates cortical neuronal activities via local circuits in vivo. To examine this question, we performed extracellular unit recording in rat insular cortex under awake and anesthetic conditions. Not a few studies apply time-rescaling theorem to detect the features of repetitive spike firing. Similar to these methods, we define an average spike interval locally in time using random matrix theory (RMT), which enables us to compare different activity states on a universal scale. Neurons with high spontaneous firing frequency (>5 Hz) and bursting were classified as HFB neurons (n = 10), and those with low spontaneous firing frequency (<10 Hz) and without bursting were classified as non-HFB neurons (n = 48). Pentobarbital injection (30 mg/kg) reduced firing frequency in all HFB neurons and in 78% of non-HFB neurons. RMT analysis demonstrated that pentobarbital increased in the number of neurons with repulsion in both HFB and non-HFB neurons, suggesting that there is a correlation between spikes within a short interspike interval (ISI). Under awake conditions, in 50% of HFB and 40% of non-HFB neurons, the decay phase of normalized histograms of spontaneous firing were fitted to an exponential function, which indicated that the first spike had no correlation with subsequent spikes. In contrast, under pentobarbital-induced anesthesia conditions, the number of non-HFB neurons that were fitted to an exponential function increased to 80%, but almost no change in HFB neurons was observed. These results suggest that under both awake and pentobarbital-induced anesthetized conditions, spike firing in HFB neurons is more robustly regulated by preceding spikes than by non-HFB neurons, which may reflect the GABAA receptor-mediated regulation of cortical activities. Whole-cell patch-clamp recording in the IC slice preparation was performed to compare the regularity of spike timing between pyramidal and fast-spiking (FS) neurons, which presumably correspond to non-HFB and HFB neurons, respectively. Repetitive spike firing of FS neurons exhibited a lower variance of ISI than pyramidal neurons both in control and under application of pentobarbital, supporting the above hypothesis.

Opioid subtype- and cell-type-dependent regulation of inhibitory synaptic transmission in the rat insular cortex.

The insular cortex (IC) plays a principal role in the regulation of pain processing. Although opioidergic agonists depress cortical excitatory synaptic transmission, little is known about opioidergic roles in inhibitory synaptic transmission. In the IC, the opioid receptors differentially regulate the excitatory propagation: agonists of the mu (MOR), delta (DOR), and kappa (KOR) exhibit suppressive, facilitative, and little effects, respectively. Thus, we aimed to examine the effects of opioid receptor agonists on unitary inhibitory postsynaptic currents (uIPSCs) in the IC. Pyramidal and GABAergic neurons in the rat IC were recorded by a multiple whole-cell patch-clamp technique. [D-Ala2,N-Me-Phe4,Gly5-ol]-Enkephalin acetate salt (DAMGO), an MOR agonist, reduced uIPSC amplitude by 74% in fast-spiking GABAergic interneuron (FS)→FS connections without a significant effect on FS→pyramidal cell (Pyr) connections. These effects of DAMGO were also observed in non-FS→FS and non-FS→Pyr connections: DAMGO reduced the uIPSC amplitude in non-FS→FS but not in non-FS→Pyr connections. DAMGO-induced depression of uIPSCs was blocked by the MOR antagonist, D-Phe-Cys-Tyr-D-Trp-Arg-Thr-Pen-Thr-NH2. The DOR agonist, [D-Pen2,5]-Enkephalin hydrate (DPDPE), reduced uIPSC amplitude by 39% in FS→FS and by 49% in FS→Pyr connections, which was antagonized by the DOR antagonist, naltrindole. However, DPDPE had little effect on non-FS→FS/Pyr connections. (±)-trans-U-50488 methanesulfonate salt (U50488), a KOR agonist, had little effect on uIPSC in FS→FS/Pyr connections. These results suggest that MOR-induced uIPSC depression in FS→FS and non-FS→FS, but not FS→Pyr and non-FS→Pyr connections, results in the depression of excitatory propagation in the IC, which may be an underlying mechanism of the powerful analgesic effects of MOR agonists.

Cytoarchitecture-Dependent Decrease in Propagation Velocity of Cortical Spreading Depression in the Rat Insular Cortex Revealed by Optical Imaging.

Cortical spreading depression (SD) is a self-propagating wave of depolarization accompanied by a substantial disturbance of the ionic distribution between the intra- and extracellular compartments. Glial cells, including astrocytes, play critical roles in maintenance of the extracellular environment, including ionic distribution. Therefore, SD propagation in the cerebral cortex may depend on the density of astrocytes. The present study aimed to examine the profile of SD propagation in the insular cortex (IC), which is located between the neocortex and paleocortex and is where the density of astrocytes gradually changes. The velocity of SD propagation in the neocortex, including the somatosensory, motor, and granular insular cortices (5.7 mm/min), was higher than that (2.8 mm/min) in the paleocortex (agranular insular and piriform cortices). Around thick vessels, including the middle cerebral artery, SD propagation was frequently delayed and sometimes disappeared. Immunohistological analysis of glial fibrillary acidic protein (GFAP) demonstrated the sparse distribution of astrocytes in the somatosensory cortex and the IC dorsal to the rhinal fissure, whereas the ventral IC showed a higher density of astrocytes. These results suggest that cortical cytoarchitectonic features, which possibly involve the distribution of astrocytes, are crucial for regulating the velocity of SD propagation in the cerebral cortex.

Spatiotemporal profiles of dental pulp nociception in rat cerebral cortex: an optical imaging study.

Somatosensation is topographically organized in the primary (S1) and secondary somatosensory cortex (S2), which contributes to identify the region receiving sensory inputs. However, it is still unknown how somatosensory inputs from the oral region, especially nociceptive inputs from the teeth, are processed in the somatosensory cortex. We performed in vivo optical imaging and identified the precise cortical regions responding to electrical stimulation of the maxillary and mandibular dental pulp in rats. Electrical stimulation of the mandibular incisor pulp evoked neural excitation in two areas: the most rostroventral part of S1, and the ventral part of S2 caudal to the middle cerebral artery. Maxillary incisor pulp stimulation initially evoked responses only in the ventral part of S2, although later maximum responses were also observed in S1 similar to mandibular incisor stimulation responses. The maxillary and mandibular molar pulp-responding regions were located in the most ventral S2, a part of which was histologically classified as the insular oral region (IOR). In terms of the initial responses, maxillary incisor and molar stimulation induced excitation in the S2/IOR rostral to the mandibular dental pulp-responding region. Contrary to the spatially segregated initial responses, the maximum excitatory areas responding to both incisors and molars in the mandible and maxilla overlapped in S1 and the S2/IOR. Multielectrode extracellular recording supported the characteristic localization of S2/IOR neurons responding to mandibular and maxillary molar pulp stimulation. The discrete and overlapped spatial profiles of initial and maximum responses, respectively, may characterize nociceptive information processing of dental pain in the cortex.

Simultaneous activation of the α1A-, α1B- and α1D-adrenoceptor subtypes in the nucleus accumbens reduces accumbal dopamine efflux in freely moving rats.

Intra-accumbal infusion of the α1-adrenergic agonist methoxamine, which has comparable affinity for α1A-, α1B- and α1D-adrenoceptor subtypes, fails to alter noradrenaline efflux but reduces dopamine efflux in the nucleus accumbens of rats. In-vivo microdialysis experiments were carried out to analyse the putative contribution of α1A-, α1B- and α1D-adrenoceptor subtypes to the methoxamine-induced decrease in accumbal dopamine efflux in freely moving rats. The drugs used were dissolved in the infusion medium and administered locally through a dialysis membrane. Intra-accumbal infusions of the α1A-adrenoceptor antagonist 5-methylurapidil (6 pmol), the α1B-adrenoceptor antagonist cyclazosin (0.6 and 6 pmol) and the α1D-adrenoceptor antagonist BMY 7378 (0.6 pmol) did not alter accumbal efflux of noradrenaline or dopamine: pretreatment with each of these α1-adrenoceptor subtype-selective antagonists counteracted the methoxamine (24 pmol)-induced decrease in accumbal dopamine efflux. Doses indicated are the total amount of drug administered over a 60-min infusion period. These results clearly suggest that the α1A-, α1B- and α1D-adrenoceptor subtypes in the nucleus accumbens mediate the α1-adrenergic agonist methoxamine-induced decrease in accumbal dopamine efflux. The present study also provides in-vivo neurochemical evidence indicating that concomitant, but not separate, activation of the α1A-, α1B- and α1D-adrenoceptors in the nucleus accumbens is required for α1-adrenergic inhibition of accumbal dopaminergic activity.

Investigating complex basal ganglia circuitry in the regulation of motor behaviour, with particular focus on orofacial movement.

Current concepts of basal ganglia function have evolved from the essentially motoric, to include a range of extramotoric functions that involve not only dopaminergic but also cholinergic, γ-aminobutyric acid (GABA)ergic and glutamatergic mechanisms. We consider these mechanisms and their efferent systems, including spiralling, feed-forward striato-nigro-striatal circuitry, involving the dorsal and ventral striatum and the nucleus accumbens (NAc) core and shell. These processes are illustrated using three behavioural models: turning-pivoting, orofacial movements in rats and orofacial movements in genetically modified mice. Turning-pivoting indicates that dopamine-dependent behaviour elicited from the NAc shell is funnelled through the NAc-nigro-striato-nigro-pedunculopontine pathway, whereas acetylcholine-dependent behaviour elicited from the NAc shell is funnelled through the NAc-ventral pallidum-mediodorsal thalamus pathway. Cooperative/synergistic interactions between striatal D1-like and D2-like dopamine receptors regulate individual topographies of orofacial movements that are funnelled through striatal projection pathways and involve interactions with GABAergic and glutamatergic receptor subtypes. This application of concerted behavioural, neurochemical and neurophysiological techniques implicates a network that is yet broader and interacts with other neurotransmitters and neuropeptides within subcortical, cortical and brainstem regions to 'sculpt' aspects of behaviour into its topographical collective.

Accumbal α-adrenoceptors, but not ß-adrenoceptors, regulate behaviour that is mediated by reserpine-sensitive storage vesicles.

It has previously been demonstrated that mesolimbic α-adrenoceptors, but not ß-adrenoceptors, control the release of dopamine that is derived from reserpine-sensitive storage vesicles. The aim of the present study was to investigate whether these storage vesicles also regulate α-adrenoceptor-mediated or ß-adrenoceptor-mediated changes in behaviour. Accordingly, rats were pretreated with reserpine before the α-adrenoceptor antagonist phentolamine or the ß-adrenoceptor agonist isoproterenol was locally applied to the nucleus accumbens. Both phentolamine and isoproterenol increased the duration of walking, rearing and grooming and decreased the duration of sitting. Reserpine counteracted the behavioural response elicited by phentolamine but not by isoproterenol. The results of the present study demonstrate that mesolimbic α-adrenoceptors, but not ß-adrenoceptors, regulate behaviour that is mediated by reserpine-sensitive storage pools. It is hypothesized that the observed α-adrenoceptor-mediated increase in locomotor activity is due to the α-adrenoceptor-mediated increase in the release of accumbal intravesicular dopamine. Our finding that α-adrenoceptors inhibit, whereas ß-adrenoceptors stimulate, locomotor activity may help explain why noradrenaline or environmental stressors have previously been found to have opposing effects on the regulation of behaviour.

Fast-spiking cell to pyramidal cell connections are the most sensitive to propofol-induced facilitation of GABAergic currents in rat insular cortex.

BACKGROUND: Propofol facilitates γ-aminobutyric acid-mediated inhibitory synaptic transmission. In the cerebral cortex, γ-aminobutyric acidergic interneurons target both excitatory pyramidal cells (Pyr) and fast-spiking (FS) and non-FS interneurons. Therefore, the propofol-induced facilitation of inhibitory transmission results in a change in the balance of excitatory and inhibitory inputs to Pyr. However, it is still unknown how propofol modulates γ-aminobutyric acidergic synaptic transmission in each combination of Pyr and interneurons. METHODS: The authors examined whether propofol differentially regulates inhibitory postsynaptic currents (IPSCs) depending on the presynaptic and postsynaptic cell subtypes using multiple whole cell patch clamp recording from γ-aminobutyric acidergic interneurons and Pyr in rat insular cortex. RESULTS: Propofol (10 µM) consistently prolonged decay kinetics of unitary IPSCs (uIPSCs) in all types of inhibitory connections without changing paired-pulse ratio of the second to first uIPSC amplitude or failure rate. The FS→Pyr connections exhibited greater enhancement of uIPSC charge transfer (2.2 ± 0.5 pC, n = 36) compared with that of FS→FS/non-FS connections (0.9 ± 0.2 pC, n = 37), whereas the enhancement of charge transfer in non-FS→Pyr (0.3 ± 0.1 pC, n = 15) and non-FS→FS/non-FS connections (0.2 ± 0.1 pC, n = 36) was smaller to those in FS→Pyr/FS/non-FS. Electrical synapses between FS pairs were not affected by propofol. CONCLUSIONS: The principal inhibitory connections (FS→Pyr) are the most sensitive to propofol-induced facilitation of uIPSCs, which is likely mediated by postsynaptic mechanisms. This preferential uIPSC enhancement in FS→Pyr connections may result in suppressed neural activities of projection neurons, which in turn reduces excitatory outputs from cortical local circuits.

Reciprocal regulation of inhibitory synaptic transmission by nicotinic and muscarinic receptors in rat nucleus accumbens shell.

Medium spiny neurones (MSNs) in the nucleus accumbens (NAc) are the principal neurones whose activities are regulated by GABAergic inputs from MSNs and fast-spiking interneurones (FSNs). Cholinergic interneurones play important roles in the regulation of activity in MSNs; however, how acetylcholine modulates inhibitory synaptic transmission from MSNs/FSNs to MSNs remains unknown. We performed paired whole-cell patch-clamp recordings from MSNs and FSNs in rat NAc shell slice preparations and examined cholinergic effects on unitary inhibitory postsynaptic currents (uIPSCs). Carbachol (1 µM) suppressed uIPSC amplitude by 58.3 ± 8.0% in MSN→MSN connections, accompanied by increases in paired-pulse ratio and failure rate, suggesting that acetylcholine reduces the probability of GABA release from the synaptic terminals of MSNs. Carbachol-induced uIPSC suppression was antagonised by 100 µM atropine, and was mimicked by pilocarpine (1 µM) and acetylcholine (1 µM) but not nicotine (1 µM). Application of AM251 slightly reduced carbachol-induced uIPSC suppression (30.8 ± 8.9%), suggesting an involvement of endocannabinoid signalling in muscarinic suppression of uIPSCs. In contrast, FSN→MSN connections showed that pilocarpine had little effect on the uIPSC amplitude, whereas both nicotine and acetylcholine facilitated uIPSC amplitude, with decreases in failure rate and paired-pulse ratio, suggesting that nicotine-induced uIPSC facilitation is mediated by presynaptic mechanisms. Miniature IPSC recordings support these hypotheses of presynaptic cholinergic mechanisms. These results suggest a differential role for muscarinic and nicotinic receptors in GABA release, which depends on presynaptic neuronal subtypes in the NAc shell.

Functional neuroimaging of aversive taste-related areas in the alert rat revealed by positron emission tomography.

Among noninvasive functional brain imaging techniques, (18) F-fluorodeoxyglucose (FDG)-positron emission tomography (PET) has a comparative advantage in detecting active brain regions in freely locomoting animals. We developed an [(18) F]FDG-PET protocol that visualizes active brain regions that respond preferentially to citrate-induced multiple behaviors in freely locomoting rats. In addition, c-Fos immunohistochemistry, an activity-dependent mapping, was performed to examine whether the areas detected by PET correspond to regions with c-Fos-immunopositive neurons. Citrate (0.1 M) was intraorally applied to detect activated brain regions responding to gustation and the rejection behaviors including gaping and tongue protrusion, which would potently activate the limbic system. PET images during citrate stimulation were subtracted from those obtained during free locomotion or during application of distilled water. Citrate increased FDG signals in multiple gustation-related regions: the nucleus accumbens (core and shell), the ventromedial nucleus of the thalamus, the basolateral and central nuclei of the amygdala, the hypothalamus, and the insular cortex. In addition, the ventrolateral striatum and the cingulate and entorhinal cortices, which have received less attention in the field of gustatory studies, also showed an increase in FDG signals. As expected, c-Fos-immunopositive cells were also found in these regions, suggesting that increased FDG signals induced by intraoral citrate injection are likely to reflect neural activity in these regions. Our [(18) F]FDG-PET protocol reveals the contributions of multiple brain regions responding to aversive taste in freely locomoting rats, and this approach may aid in the identification of unknown neural networks especially relating to the limbic information processing.

Synergistic, but not separate, stimulation of accumbal ß1- and ß2-adrenoceptors alters the accumbal dopamine efflux in freely moving rats.

The effects of intra-accumbal infusion of selective agonists for the ß-adrenoceptor subtypes on the noradrenaline and dopamine efflux in the nucleus accumbens of freely moving rats were investigated, using in vivo microdialysis. Neither ß1-(dobutamine: 0.06 and 0.12 pmol) nor ß2-adrenoceptor agonist (salbutamol: 0.36 and 3.6 pmol) altered the basal noradrenaline and dopamine efflux in the nucleus accumbens. Co-administration of 0.06 pmol of dobutamine with salbutamol (3.6 pmol) did not affect the noradrenaline levels, but it increased the dopamine efflux to approximately 120%. Co-administration of 0.12 pmol of dobutamine with salbutamol (0.36 or 3.6pmol) also increased DA efflux to approximately 120% without affecting noradrenaline levels. The non-selective ß-adrenoceptor antagonist l-propranolol (1200 pmol) that did not alter the basal noradrenaline and dopamine levels, suppressed the dopamine efflux, induced by co-administration of dobutamine (0.12 pmol) and salbutamol (3.6 pmol). The doses mentioned are the total amount of drug over the 60-min infusion period. The present results support our previously reported conclusion that stimulation of accumbal ß-adrenoceptors which are suggested to be postsynaptically located on accumbal dopaminergic terminals, can enhance the dopamine efflux in the nucleus accumbens. The present study also provides in vivo neurochemical evidence that concomitant, but not separate, activation of accumbal ß1- and ß2-adrenoceptors synergistically increases the accumbal dopamine efflux.

Apomorphine-induced modulation of neural activities in the ventrolateral striatum of rats.

The dopaminergic system in the ventrolateral portion of the striatum (Svl), part of the basal ganglia, regulates orofacial movements; bilateral co-stimulation of both dopamine D1 -like and D2 -like receptors elicits repetitive jaw movements in rats. However, how the activities of Svl neurons are modulated by the activation of dopaminergic receptors remains unknown. We systematically injected apomorphine, a non-selective dopamine receptor agonist that induced jaw movements under urethane anesthesia, and performed multi-channel unit recording from Svl neurons. The Svl neurons were classified into two subgroups: (1) the phasically active (PA) neurons represented by mainly the medium spiny neurons and the GABAergic interneurons in part, and (2) the tonically active (TA) neurons composed of mainly the cholinergic interneurons. Apomorphine modulated PA neuron firing frequency with wide variability; 33.3% of the PA neurons were facilitated, while 38.3% were suppressed. In the majority of TA neurons, the firing frequency was reduced by apomorphine (71.1%). The cross-correlations between PA and PA, PA and TA, and TA and TA neurons were analyzed, and pairs of PA neurons and pairs of PA and TA neurons, showed negligible apomorphine-induced effect on the number of synchronized spikes. In contrast, pairs between TA neurons showed a consistent decrease in the number of synchronized spikes. The apomorphine-induced suppression of TA neuron activities with decreased synchronized outputs is likely to reduce the amount of locally released acetylcholine, which may contribute to the induction of apomorphine-induced jaw movements in rats.

Anatomical and electrophysiological mechanisms for asymmetrical excitatory propagation in the rat insular cortex: in vivo optical imaging and whole-cell patch-clamp studies.

The insular cortex (IC) integrates limbic information from the amygdala and hypothalamic nucleus to multimodal sensory inputs, including visceral, gustatory, and somatosensory information. However, the functional framework of excitation in the IC is still unknown. We performed optical imaging and single pyramidal neuronal staining using a whole-cell patch-clamp technique in urethane-anesthetized rats to elucidate the precise anatomical and physiological features of IC pyramidal neurons, which regulate cortical information processing via their horizontal connections. Optical imaging revealed that electrical stimulation of the granular (GI) or dysgranular (DI) IC elicited characteristic excitatory propagations along the rostrocaudal axis parallel to the rhinal fissure, with a preference toward the rostral direction. Spatial patterns of the dendrites and axons of layer II/III pyramidal cells in the DI/GI support these functional features of excitation; for example, rostrocaudal axonal arbors tend to extend with a rostral directional preference. The mean length of the axons from the soma to the farthest site rostrally was ∼50% longer than that of the caudal length. Pyramidal cells in the DI/GI exhibited spontaneous membrane oscillation in the UP and DOWN states. Similarly to the evoked signals obtained by optical imaging, repetitive electrical stimulation of the caudal IC ∼1 mm away from the recorded cells (five pulses at 50 Hz) induced the summation of evoked excitatory postsynaptic potentials during the DOWN state and profound inhibitory postsynaptic potentials during the UP state. Clarification of the excitation feature with its cellular basis provides new clues about the functional mechanisms of the asymmetric propagation of neural activities in the IC.

Nucleus accumbens and dopamine-mediated turning behavior of the rat: role of accumbal non-dopaminergic receptors.

Accumbal dopamine plays an important role in physiological responses and diseases such as schizophrenia, Parkinson's disease, and depression. Since the nucleus accumbens contains different neurotransmitters, it is important to know how they interact with dopaminergic function: this is because modifying accumbal dopamine has far-reaching consequences for the treatment of diseases in which accumbal dopamine is involved. This review provides a summary of these interactions, and our current knowledge about them are as follows: A) AMPA receptors are required for dopamine-dependent behavior and vice versa; NMDA receptors modulate the activity at the level of AMPA and/or dopamine D1 receptors. B) GABA(A), but not GABA(B), receptors inhibit dopamine-dependent behavior. C) Nicotinic receptors are required for dopamine-dependent behavior, whereas muscarinic receptors inhibit dopamine-dependent behavior. D) α-Adrenoceptors inhibit dopamine-dependent behavior in contrast to ß-adrenoceptors, which potentiate this behavior. E) µ- and δ2-opioid receptors elicit behavior that requires an intact dopaminergic function and δ2-opioid receptors modulate dopamine-dependent behavior. F) Orexin 2 receptors play an important, modifying role in dopamine-dependent behavior. G) Somatostatin receptors potentiate dopamine-dependent behavior. It is suggested that modulation of the above-mentioned non-dopaminergic receptors provide new tools to control physiological functions as well as diseases mediated by accumbal dopamine.

Constitutive and conditional mutant mouse models for understanding dopaminergic regulation of orofacial movements: emerging insights and challenges.

Among numerous mechanisms implicated in the regulation of orofacial movements, dopamine-containing neurons have received the most extensive study. Here we review the effects of a) constitutive knockout of D(1-5) dopamine receptors and b) conditional mutations with progressive ablation of D(1) receptor-expressing cells, on the topography of spontaneous and D(1)-like agonist-induced orofacial movements. In constitutive knockouts, D(1) and D(2) exert primary roles in regulating horizontal and vertical jaw movements, respectively, in opposite directions; in contrast, both D(1) and D(2) receptors regulate tongue protrusions and incisor chattering, in the same direction. D(3) and D(5) receptors play more subtle roles in regulating orofacial movements, while D(4) receptors do not play any material role. Progressive loss of forebrain D(1) receptor-expressing cells in CamKIIa/Cre D(1)Tox mutants is associated primarily with decreases in head and vibrissae movements, while progressive loss of striatal D(1) receptor-expressing cells in DARPP-32/Cre D(1)Tox mutants is associated primarily with reductions in jaw movements and tongue protrusions but increases in head and vibrissae movements. Further application of constitutive and particularly conditional mutants may clarify further not only dopaminergic regulation of orofacial movements but also the pathophysiology of orofacial dysfunction in Huntington's disease and Parkinson's disease.

Histaminergic effects on the frequency of repetitive spike firing in rat insular cortex.

The insular cortex (IC) processes multimodal sensory information including gustatory, visceral, nociceptive, and thermal sensation, and is considered to play a role in the regulation of homeostasis. The IC receives dense histaminergic projection from the tuberomamillary nucleus in the hypothalamus, and recent studies have demonstrated that the blockage of histaminergic receptors impairs physiological functions in the IC. However, little is known about the effects of histamine on the electrophysiological properties of the IC. To explore the effects of histamine on the subthreshold responses and action potential properties in the IC, intracellular recording with a sharp glass electrode was obtained from IC pyramidal cells in cortical slice preparations. Application of histamine (30 µM) increased the frequency of repetitive spike firing in response to a long depolarizing current pulse injection; accompanied by an increase in input resistance. The frequency of repetitive spike firing was estimated by the slope of the frequency-current (f/I) curve. Histamine caused an increase from 23.3±2.3 Hz/nA to 40.3±4.3 Hz/nA. The histamine-induced facilitation of repetitive spike firing was blocked by pre-application of 50 µM cimetidine, an H(2) receptor antagonist, but not 30 µM pyrilamine, an H(1) receptor antagonist. R-α-methylhistamine (10 µM), an H(3) autoreceptor agonist, had little effect on the slope of the f/I curve. These results suggest that the histamine-induced facilitation of firing frequency is mediated via H(2) and not H(1) receptors. In addition, H(3) receptors have a minor role in the intrinsic membrane and firing properties of IC pyramidal cells.

The α1-, but not α2-, adrenoceptor in the nucleus accumbens plays an inhibitory role upon the accumbal noradrenaline and dopamine efflux of freely moving rats.

In vivo microdialysis was used to analyse the role of the α(1)- and α(2)-adrenoceptor subtypes in the regulation of noradrenaline and dopamine efflux in the nucleus accumbens of freely moving rats. Intra-accumbal infusion of α(1)-adrenoceptor agonist methoxamine (24pmol) failed to alter the noradrenaline efflux, but decreased the dopamine efflux. The intra-accumbal infusion of α(1)-adrenoceptor antagonist prazosin (6, 600 and 6000pmol) produced a dose-related increase and decrease of the noradrenaline and dopamine efflux, respectively. An ineffective dose of prazosin (6pmol) counteracted the methoxamine (24pmol)-induced decrease of dopamine efflux. The prazosin (6000pmol)-induced increase of noradrenaline efflux, but not the decrease of dopamine efflux, was suppressed by the co-administration of an ineffective dose of methoxamine (0.024pmol). Neither the α(2)-adrenoceptor agonist clonidine (300pmol) and UK 14,304 (300pmol) nor the α(2)-adrenoceptor antagonist RX 821002 (0.6, 3, 600 and 6000pmol) significantly affected the accumbal noradrenaline and dopamine efflux. The doses mentioned are the total amount of drug over the 60-min infusion period. The present results show that (1) accumbal α(1)-adrenoceptors which are presynaptically located on noradrenergic nerve terminals inhibit the accumbal noradrenaline efflux, increasing thereby the accumbal dopamine efflux, (2) accumbal α(1)-adrenoceptors which are postsynaptically located on dopaminergic nerve terminals inhibit the accumbal dopamine efflux, and (3) accumbal α(2)-adrenoceptors play no major role in the regulation of accumbal efflux of noradrenaline and dopamine.