Stimulation of ventral tegmental area and nucleus accumbens reduce receptive fields for hypothalamic biting reflex in cats

Stimulation of the ventral tegmental area (VTA) and nucleus accumbens (NA) suppressed attack behavior elicited by hypothalamic stimulation. Because the nondirected somatic motor and autonomic components of attack were not affected by VTA or NA stimulation, and previous work had demonstrated the importance of sensory guidance in attack, the mechanism for suppression was postulated to be on the sensory component of the attack reaction. We investigated the effects of VTA and NA stimulation on the biting reflex, one of the sensory-controlled components of hypothalamically elicited attack behavior. The receptive field for biting was measured during hypothalamic stimulation with and without concurrent VTA and NA stimulation. At stimulation parameters that inhibited attack, the extent of the receptive field was reduced. Thus, VTA and NA may produce inhibition of attack by acting on the sensory component of the response mechanism. We suggest that reduction of receptive fields is a mechanism by which behavioral inhibition is mediated in the central nervous system.     

Electrophysiological responses of neurones in the nucleus accumbens to hippocampal stimulation and the attenuation of the excitatory responses by the mesolimbic dopaminergic system

Extracellular single unit recordings were obtained from neurones in the nucleus accumbens of urethane anaesthetized rats. Single pulse stimulation (300-800 microA, 0.15 ms, 0.5-1.5 Hz) of the ventral subiculum of the hippocampus strongly excited silent and spontaneously active (3-6 spikes/s) medial accumbens neurones. The majority of neurones excited by hippocampal stimulation were quiescent and identified only by the elicited action potentials. Neurones on the dorso-medial border of the nucleus accumbens and adjacent lateral septum, with a faster spontaneous discharge rate (8-12 spikes/s), were inhibited by hippocampal stimulation. In the ventral border of the accumbens and the olfactory tubercle, hippocampal stimulation also inhibited the fast-firing (greater than 20 spikes/s) neurones. When trains of 10 conditioning pulses (300-800 microA, 0.15 ms, 10 Hz) were delivered to the ventral tegmental area (VTA) 100 ms before each single-pulse stimulation of the hippocampus, the excitatory responses of the silent and spontaneously active accumbens neurones were attenuated. The possibility of this relatively prolonged attenuation effect being dopamine-mediated was supported by several lines of evidence. Dopamine, applied iontophoretically, reduced markedly the excitatory response of accumbens neurones to hippocampal stimulation. Iontophoretically applied dopamine mimicked the attenuating effect produced by VTA conditioning stimulation in the same neurone. The attenuating effects of VTA conditioning stimulation on the activation of accumbens neurones by hippocampal stimulation was reduced by: (1) administration of 6-hydroxydopamine to the VTA 2 days and 7-9 days prior to the recording session, (2) the intraperitoneal injection of haloperidol 1 h before the recording session, and (3) the iontophoretic application of trifluoperazine to accumbens neurones. These observations support the hypothesis that the attenuating effects of the mesolimbic dopamine system on limbic inputs to the nucleus accumbens may have a role in limbic-motor integration.     

Neurotensin neurons in the ventral tegmental area project to the medial nucleus accumbens

Opiate receptors measured in vitro or in vivo with [3H]lofentanil in the rat vagus nerve were found to accumulate on both sides of a ligature, thus indicating a bidirectional axoplasmic transport of these receptors. When rats were treated with capsaicin, the accumulation of opiate receptors was tremendously reduced in the vagus whereas muscarinic receptors in ligated sciatic nerves were unaffected. Since capsaicin is known to affect sensory neurones, mostly those containing substance P, the present results support the idea that the opiate receptors in the vagus are associated with substance P neurones.     

An electrophysiological study of inputs to neurons of the ventral tegmental area from the nucleus accumbens and medial preoptic-anterior hypothalamic areas

Extracellular recordings were obtained from neurons in the ventral tegmental area (VTA) of urethane-anesthetized rats. Neurons were devided into two types based on the latencies of antidromic activation following electrical stimulation of the nucleus accumbens (NAcc), and on the durations of action potentials. Type A neurons had longer latencies for antidromic activation (mean 15.9 msec) and longer durations of action potentials (2.6msec), while type B neurons had shorter latencies (mean 4.5 msec) and shorter duration of action potentials (< 2.6msec).Electrical stimulation of the medial preoptic-anterior hypothalamic areas (mPOA-AHA) and NAcc produced the following effects on the two types of VTA neurons: (i) the majority of both type A and B neurons were suppressed by mPOA-AHA stimula stimulation with onset latencies of less than 10 msec; (ii) 42% of type B neurons were also suppressed by NAcc stimulation, with onset latencies of less than 10 msec; (iii) type A neurons were suppressed (33%) or activated (43%) by NAcc stimulation, the onset latencies usually being longer than 10 msec; (iv) 71% of type A neurons tested had convergent inputs from the mPOA-AHA and NAcc, usually suppressed-suppressed or suppressed-activated, while 45% of type B neurons had convergent inputs from these two areas, usually suppressed-suppressed.     

Response of nucleus accumbens neurons to amygdala stimulation and its modification by dopamine

Extracellular single unit recordings were obtained from the nucleus accumbens of urethane anesthetized rats. It was found that electrical stimulation of the basal lateral and basal medial nuclei of the amygdala produced strong excitatory responses in neurons of the nucleus accumbens, in particular the medial region. Latencies of activation were relatively short with a mean of 10.7 ms.Dopamine applied iontophoretically had a marked attenuating effect on the excitatory response of nucleus accumbens neurons to amygdala stimulation. The spontaneous activity of all neurons recorded from the nucleus accumbens was also suppressed by dopamine, but the excitatory response was more sensitive to dopamine inhibition than the spontaneous activity.Neurons in the nucleus accumbens showed a variety of responses to single-pulse electrical stimulation of the ventral tegmental area (VTA). Some units in the nucleus accumbens received convergent inputs from both the amygdala and the VTA. Stimulation of the VTA also attenuated the response of nucleus accumbens neurons to excitatory inputs from the amygdala. A train of 10 pulses (0.15 ms, 200–600 αA) at 10 Hz delivered to the VTA at 100 ms before stimulation of the amygdala caused attenuation of the original excitatory response. The attenuating effect could be observed irrespective of whether individual single-pulse stimulation of the VTA elicited a response in that particular accumbens neuron or not. 6-Hydroxydopamine injected into the VTA 2 days prior to the recording experiment, or haloperidol injected intraperitoneally 1 h before the recording session, abolished this attenuating effect. However, responses to single-pulse stimulations of the VTA were not abolished. The results suggest that the attenuation of the excitatory response to amygdala stimulation was due to the release of dopamine from mesolimbic dopaminergic neurons. Responses to single-pulse stimulations of the VTA were probably due to activation of non-dopaminergic neurons projecting from the same area.It is suggested as a working hypothesis that this inhibitory effect of dopamine may be an important function of the mesolimbic dopamine pathway in modulating the extent to which limbic structures can exert an influence on the motor system through the accumbens.     

CCK—8及损毁MFB对腹侧被盖区和伏核多巴胺,CCK—8含量的影响

应用荧光分光光度法和放射免疫法,在以６－羟基多巴胺（６－ＯＨＤＡ）单侧损毁内侧前脑束（ＭＦＢ）制备的偏侧帕金森病（ＰＤ）大鼠模型身上,测定了腹侧被盖区（ＶＴＡ）和伏核（Ａｃｂ）中多巴胺（ＤＡ）和八胺胆囊收缩素（ＣＣＫ－８）的含量,并测定了ＴＶＡ和Ａｃｂ区微量注射ＣＣＫ－８对正常大鼠ＤＡ含量的影响。结果如下：ＰＤ大鼠模型损毁侧ＶＴＡ和Ａｃｂ的ＤＡ和ＣＣＫ－８的含量与健康及对照组相比均减少（Ｐ〈０．０     

Behavioral and neurochemical effect of daily injection with neurotensin into the ventral tegmental area

Many lines of evidence indicate an excitatory role by neurotensin (NT) on mesolimbic dopamine neurons in the ventral tegmental area (VTA). In support of this postulate, NT microinjection into the VTA of rats produces a dopamine-dependent increase in spontaneous motor activity that is associated with an increase in dopamine metabolism in the nucleus accumbens. In this study it was found that after daily intra-VTA injection with NT, both the motor hyperactivity and increase in dopamine metabolism were significantly enhanced. Further, the increased motor response to NT was present after 7 days without daily administration. While the augmented motor response could be produced with the carboxy-terminal fragment NT8-13, the NH2-terminal fragment, NT1-8, was ineffective. The enhancement of motor activity was only produced by NT injection into the A10 dopamine region and not adjacent nuclei. These results suggest that daily administration with NT into the VTA will potentiate the responsiveness of mesolimbic dopamine neurons to subsequent injection with NT.     

Methylphenidate dose–response behavioral and neurophysiological study of the ventral tegmental area and nucleus accumbens in adolescent rats

The psychostimulant methylphenidate (MPD) is the most common medication used in treating ADHD in children. Studies have shown an increasing prevalence among adolescents without ADHD to take MPD as a cognitive booster and recreational drug, even though it is a Schedule II drug and has a high potential for abuse. The objective of this study is to explore if there is an association between the animals’ behavioral and neurophysiological responses to acute and/or chronic methylphenidate exposure within the ventral tegmental area and the nucleus accumbens, and to compare how these two brain structures fire in response to methylphenidate. Freely moving adolescent rats implanted with semimicroelectrodes within the VTA and NAc were divided into three MPD dosing groups: 0.6, 2.5, and 10 mg/kg i.p., as well as a saline control group. The animals were divided into two groups based on their behavioral responses to chronic MPD, behavioral sensitization and tolerance, and the neuronal responses of the two groups were compared for each MPD dosing. Significant differences in the proportion of neuronal units in the VTA and NAc responding to MPD were observed at the 0.6 and 10.0 mg/kg MPD dosing groups. Moreover, the same doses of 0.6, 2.5, and 10.0 mg/kg MPD elicited behavioral sensitization in some animals and behavioral tolerance in others. This specific study shows that the VTA and NAc neurons respond differently to the same doses of MPD. MPD has different neuronal and behavioral effects depending on the individual, the dosage of MPD, and the brain structure studied.     

Hypocretin /orexin preferentially activates caudomedial ventral tegmental area dopamine neurons

The hypocretin/orexin (HCRT) neuropeptide system modulates behavioral state and state-dependent processes via actions on multiple neuromodulatory transmitter systems. Recent studies indicate that HCRT selectively increases dopamine (DA) neurotransmission within the prefrontal cortex (PFC) and the shell subregion of the nucleus accumbens (NAs), but not the core subregion of the nucleus accumbens (NAc). The circuitry underlying the differential actions of HCRT across distinct DA systems is unclear. The current study examined whether HCRT preferentially activates PFC- and NAs-projecting relative to NAc-projecting DA neurons within the VTA. One week after infusion of the retrograde tracer fluorogold (FG) into the medial PFC, NAc or NAs, animals received a ventricular infusion of HCRT-1. Subsequent analyses conducted across the rostral-caudal extent of the VTA determined the degree to which: (i) Fos-immunoreactivity (ir) was observed within tyrosine hydroxylase (TH)-ir neurons; (ii) TH-ir was observed within FG-ir neurons; and (iii) Fos-ir was observed within FG-ir neurons. HCRT significantly increased Fos-ir in VTA DA (TH-ir) neurons, primarily in a restricted population of small-to-medium-sized DA neurons located within the caudomedial VTA. Furthermore, within this region of the VTA, PFC- and NAs-projecting TH-ir neurons were more likely to contain Fos-ir than were NAc-projecting TH-ir neurons. These results provide novel evidence that HCRT selectively activates PFC- and NAs-projecting DA neurons within the VTA, and suggest a potential role for HCRT in PFC- and NAs-dependent cognitive and/or affective processes. Moreover, these and other observations suggest that the dysregulation of HCRT-DA interactions could contribute to cognitive/affective dysfunction associated with a variety of behavioral disorders.     

Expression of D1 receptor mRNA in projections from the forebrain to the ventral tegmental area

In situ hybridization was combined with Fluoro-Gold retrograde labeling to determine if cells projecting from the forebrain to the ventral tegmental area (VTA) express D₁ receptor mRNA. Cell counts were made in the prefrontal cortex, shell of the nucleus accumbens, and ventral pallidum to estimate the percentage of neurons projecting to the VTA that express D₁ receptor mRNA. Retrogradely labeled cells were observed in the infralimbic and prelimbic regions of the prefrontal cortex, and up to 37% of the retrogradely labeled cells expressed D₁ receptor mRNA. Double-labeled cells constituted up to 89% of retrogradely labeled neurons in the rostral shell and up to 68% in the caudal shell of the nucleus accumbens. The number of retrogradely labeled cells in the ventral pallidum that were double-labeled ranged from 13% in the rostral to less than 10% in the caudal portions. These data provide anatomical support for a role of D₁ receptors in the reciprocal innervation between the forebrain and VTA. Synapse 25:205–214, 1997. © 1997 Wiley-Liss, Inc.     

Oxytocin receptors are expressed on dopamine and glutamate neurons in the mouse ventral tegmental area that project to nucleus accumbens and other mesolimbic targets

The mesolimbic dopamine (DA) circuitry determines which behaviors are positively reinforcing and therefore should be encoded in the memory to become a part of the behavioral repertoire. Natural reinforcers, like food and sex, activate this pathway, thereby increasing the likelihood of further consummatory, social, and sexual behaviors. Oxytocin (OT) has been implicated in mediating natural reward and OT‐synthesizing neurons project to the ventral tegmental area (VTA) and nucleus accumbens (NAc); however, direct neuroanatomical evidence of OT regulation of DA neurons within the VTA is sparse. To phenotype OT‐receptor (OTR) expressing neurons originating within the VTA, we delivered Cre‐inducible adeno‐associated virus that drives the expression of fluorescent marker into the VTA of male mice that had Cre‐recombinase driven by OTR gene expression. OTR‐expressing VTA neurons project to NAc, prefrontal cortex, the extended amygdala, and other forebrain regions but less than 10% of these OTR‐expressing neurons were identified as DA neurons (defined by tyrosine hydroxylase colocalization). Instead, almost 50% of OTR‐expressing cells in the VTA were glutamate (GLU) neurons, as indicated by expression of mRNA for the vesicular GLU transporter (vGluT). About one‐third of OTR‐expressing VTA neurons did not colocalize with either DA or GLU phenotypic markers. Thus, OTR expression by VTA neurons implicates that OT regulation of reward circuitry is more complex than a direct action on DA neurotransmission. J. Comp. Neurol. 525:1094–1108, 2017. © 2016 Wiley Periodicals, Inc.     

Non-NMDA excitatory amino acid receptors in the ventral tegmental area mediate systemic dizocilpine (MK-801) induced hyperlocomotion and dopamine release in the nucleus accumbens

This study investigated the putative role of non-NMDA excitatory amino acid (EAA) receptors in the ventral tegmental area (VTA) for the increase in dopamine (DA) release in the nucleus accumbens (NAC) and behavioral stimulation induced by systemically administered dizocilpine (MK-801). Microdialysis was utilized in freely moving rats implanted with probes in the VTA and NAC. Dialysates from the NAC were analyzed with high-performance liquid chromatography for DA and its metabolites. The VTA was perfused with the AMPA and kainate receptor antagonist CNQX (0.3 or 1 mM) or vehicle. Forty min after onset of CNQX or vehicle perfusion of the VTA, MK-801 (0.1 mg/kg) was injected subcutaneously. Subsequently, typical MK-801 induced behaviors were also assessed in the same animals by direct observation. MK-801 induced hyperlocomotion was associated with a 50% increase of DA levels in NAC dialysates. Both the MK-801 evoked hyperlocomotion and DA release in the NAC was antagonized by CNQX perfusion of the VTA in a concentration-dependent manner. None of the other rated MK-801 evoked behaviors, e.g. head weaving or sniffing, were affected by CNQX perfusion of the VTA. By itself the CNQX or vehicle perfusion of the VTA alone did not affect DA levels in NAC or any of the rated behaviors. These results indicate that MK-801 induced hyperlocomotion and DA release in the NAC are largely elicited within the VTA via activation of non-NMDA EAA receptors, tentatively caused by increased EAA release. Thus, the locomotor stimulation induced by psychotomimetic NMDA receptor antagonists may not only reflect impaired NMDA receptor function, but also enhanced AMPA and/or kainate receptor activation in brain, e.g., in the VTA. In view of their capacity to largely antagonize the behavioral stimulation induced by psychotomimetic drugs, such as MK-801, AMPA, and/or kainate receptor antagonists may possess antipsychotic efficacy. J. Neurosci. Res. 51:583–592, 1998. © 1998 Wiley-Liss, Inc.     

Extracellular dopamine in the rat ventral tegmental area and nucleus accumbens following ventral tegmental infusion of cocaine

Rats were implanted with dual dialysis probes, one in the ventral tegmental area, and another one ipsilateral in the nucleus accumbens. Infusion of cocaine (10, 100, 1000 mM) into the ventral tegmental area gradually increased extracellular dopamine to 164, 329 and 991% of baseline in the ventral tegmental area, but reduced dopamine to 76, 47 and 38% of baseline in the nucleus acumbens. These results are consistent with cocaine-induced feedback regulation of dopamine cell activity involving somatodendritec impulse-regulating dopamine D₂ autoreceptors.     

Interactions between amygdala central nucleus and the ventral tegmental area in the acquisition of conditioned cue-directed behavior in rats

Rats orient to and approach localizable visual cues paired with food delivery. Previous studies from this laboratory show that the acquisition and expression of these learned cue-directed responses depend on integrity of a system including the central nucleus of the amygdala (CeA), the substantia nigra pars compacta (SNc) and the dorsolateral striatum (DLS). Other investigators have suggested that cue-directed behaviors may also depend on interaction between CeA and the ventral striatum, perhaps via CeA projections to the ventral tegmental area (VTA). In Experiment 1, we examined the effects of unilateral lesions of CeA and/or VTA on rats' acquisition of conditioned responses to visual cues paired with food. Contrary to the results of previous studies that examined interactions of CeA with either SNc or DLS, rats with contralateral disconnection lesions of CeA and VTA were unimpaired in their acquisition of cue-directed responses. By contrast, rats with lesions of both structures in the same hemisphere failed to learn cue-directed responses, but were normal in their acquisition of conditioned responses directed to the food cup. In Experiment 2, we attempted to characterize the influence of VTA on CeA by examining FOS induction in CeA by a visual cue for food in rats with unilateral lesions of VTA. The results suggested an excitatory influence of VTA on CeA in the presence of food cues. Implications of these results for brain circuits involved in learned orienting and incentive motivation are discussed.     

Dopaminergic neurons in the rat ventral tegmental area. III. Effects of -and -amphetamine

By use of various histochemical techniques, it was shown that both DA and non-DA cells in the VTA project to the NAc. Of these VTA-NAc output cells, the great majority were DA-containing cells. A small number of non-DA cells were encountered most frequently in the lateral part of the VTA. Correspondingly, two distinct groups of neurons, types I and II, could be identified by antidromic stimulation of the NAc. Several lines of evidence suggest that type I cells are DA-containing neurons. The evidence may be summarized as follows:

1. (1) type I cells had a slow-bursting or regular firing pattern, slow discharge rate and wide spike duration which appears to be identical to the characteristics of DA neurons originally described by Bunney et al.¹⁶;

2. (2) the great majority of these cells could be activated antidromically by stimulation of the NAc;

3. (3) the conduction velocity and absolute refractory period of type I cells are consistent with unmyelinated fine DA fibers;

4. (4) injection of 6-OHDA, but not 5,7-DHT directly in the MFB blocked antidromic responses of these cells;

5. (5) they were extremely sensitive to intravenously administered DA agonist apomorphine (ID₅₀ = 7 μg/kg); and

6. (6) direct fluorescence histochemical examination of serial sections from brains of animals in which type I cells have been identified by antidromic stimulation of the NAc showed that type I cells are most likely catecholamine-containi ng neurons. By contrast, type II cells possessed an entirely different spectrum of physiological characteristics; in addition, they showed no consistent response to apomorphine and their antidromic responses to stimulation of the NAc were not affected by 6-OHDA. It is concluded that (1) VTA output neurons consist of both DA and nonDA neurons, and (2) identified types I and II neurons in the VTA by antidromic stimulation of the NAc are DA and non-DA cells, respectively.

Projection neurons of the nucleus accumbens: an intracellular labeling study

Projection neurons of nucleus accumbens (NAC) of the rat were identified by either antidromic activation from stimulation of midbrain ventral tegmental area-substantia nigra (VTA-SN) regions, or by tracing axons of intracellularly labeled NAC neurons into the ventral pallidum. The morphology of these NAC projection neurons were determined to be medium spiny neurons similar to those identified in the caudate-putamen.     

Electrophysiological identification of mesencephalic ventromedial tegmental (VMT) neurons projecting to the frontal cortex, septum and nucleus accumbens

The electrophysiological properties of neurons located in the mesencephalic ventromedial tegmentum (VMT) and the organization of the efferents of these neurons to the frontal cortex, the septum, the nucleus accumbens and the head of the striatum were studied in ketamine-anesthetized rats. The projections of the VMT cells were determined through use of the antidromic activation method. Our results show that VMT projections to different target areas originate mainly from different VMT neurons. However, in some cases single VMT neurons were found to send axon collaterals to two different areas. Three branching patterns were observed: septum-cortex, septum--nucleus accumbens and septum--striatum. The occasional observation of temporally distinct antodromic responses from a single area was considered to result from activation of different branches of the arborizing axon. The distribution of antidromic response latencies for VMT projections to each structure is discussed in relation to the question of dopaminergic versus non-dopaminergic mesolimbic and mesocortical systems.