Chronic lithium treatment decreases neuronal activity in the nucleus accumbens and cingulate cortex of the rat

Although the efficacy of lithium as a mood stabilizer is well documented, the mechanism of its therapeutic effect associated with prolonged treatment remains unknown. Identifying discrete brain regions and neural pathways that are functionally altered following long-term lithium treatment is central to elucidating a psychotherapeutic mechanism. We have used a sensitive and quantitative histochemical assay for the determination of cytochrome oxidase (CO) activity, a mitochondrial marker of neuronal activity, to determine the effect of repeated lithium treatment on regional neuronal activity in the rat brain. Oral lithium treatment (21 days) selectively decreased cytochrome oxidase activity in the cingulate cortex and regions of the nucleus accumbens. These decreases were not seen after 5 days of lithium administration, although serum lithium concentrations were similar after both 5 and 21 days of treatment. The analysis of interregional correlations further suggests a role for amygdala pathways in the effects of lithium following 21 days of treatment. The implications of these data for understanding the mechanisms of action of lithium are discussed.

Amygdala activity related to enhanced memory for pleasant and aversive stimuli

Pleasant or aversive events are better remembered than neutral events. Emotional enhancement of episodic memory has been linked to the amygdala in animal and neuropsychological studies. Using positron emission tomography, we show that bilateral amygdala activity during memory encoding is correlated with enhanced episodic recognition memory for both pleasant and aversive visual stimuli relative to neutral stimuli, and that this relationship is specific to emotional stimuli. Furthermore, data suggest that the amygdala enhances episodic memory in part through modulation of hippocampal activity. The human amygdala seems to modulate the strength of conscious memory for events according to emotional importance, regardless of whether the emotion is pleasant or aversive.

Neurotensin induces Fos and Zif268 expression in limbic nuclei of the rat brain

The endogenous tridecapeptide neurotensin exerts a wide range of behavioral, electrophysiological and neurochemical effects when administered directly into the brain. These effects are thought to result from the activation of distinct populations of neurotensin receptors distributed throughout the central nervous system. We have mapped the sites of functional change in the rat brain associated with the central administration of neurotensin using the induction of the nuclear protein products of the immediate early genes c-fos and zif268 as markers of cellular activation. The administration of neurotensin into the lateral ventricle of rats produced an increase in the number of nuclei positive for Fos and Zif268 immunoreactivity in the central and basolateral nuclei of the amygdala and the paraventricular and supraoptic nuclei of the hypothalamus. Neurotensin also produced an increase in serum corticosterone concentration and decrease in body temperature. The intraperitoneal administration of SR48692, a non-peptide neurotensin receptor antagonist, blocked the neurotensin-induced corticosterone secretion and significantly reduced the number of neurotensin-induced Fos-positive and Zif268-positive neurons in the amygdaloid complex. A significant positive correlation was found between the number of Fos-positive nuclei in the central or basolateral nucleus of the amygdala and the serum corticosterone concentration. A significant positive correlation was also found between the number of Zif-positive cells in the paraventricular nucleus of the hypothalamus and change in body temperature following treatment. Our findings indicate that the central role of neurotensin in increasing serum corticosterone involves the induction of Fos in the central and basolateral nuclei of the amygdala. In contrast, the neurotensin-induced hypothermia, which was unaffected by pretreatment with SR48692, involves Zif induction in the paraventricular nucleus of the hypothalamus. These data support further the existence of central neurotensin receptor subtypes which may regulate distinct immediate early genes.

Differential Effects of Conditioned and Unconditioned Stress on the Neurotensin Content of Dopamine Cell Body Groups of the Ventral Mesencephalon

The findings of this study extend the observations of Deutch et al. who suggested that NT in the ventral mesencephalon may be involved in the environmentally elicited activation of selectively responsive populations of mesotelencephalic dopamine neurons. The unconditioned response of NT-LI to electric footshock was observed only at an intensity of 500 microA and only in the lateral subdivision of the VTA. The selective effect of footshock stress on the NT content of a specific cell body group of the ventral mesencephalon suggests that NT mechanisms in the lateral VTA may, in part, underlie the stress-induced activation of dopamine neurons that originate in the lateral VTA. However, it should be noted that populations of dopamine neurons are activated by footshock intensities less than 500 microA, while NT concentrations of mesencephalic dopamine cell body groups are not altered by these shock intensities. The disparity weakens the possibility of a role for NT in the stress-induced activation of brain dopamine neurons unless NT mechanisms may be involved in transducing the effects of higher intensity stressors versus low intensity stressors. However, it should be noted that changes in the concentration of NT-LI represent an endpoint of unknown sensitivity and functional significance and best serve as an initial approximation of the effects of a manipulation on NT-containing neurons. It is plausible that NT mechanisms in the ventral mesencephalon may act in concert with other neuropeptides such as substance P and Met-enkephalin to transduce the effects of stressors on alterations in the activity of mesotelencephalic dopamine neurons that originate in the ventral mesencephalon. An examination of the effects of footshock stress on the content of prepro-NT mRNA in the dopamine cell body groups of the ventral mesencephalon would be of interest in assessing whether stress enhances NT gene expression or alters the characteristics of release of this neuropeptide in the ventral mesencephalon. Lacking NT receptor antagonists, it would also be of interest to determine the effects of the passive immunoneutralization of NT in the ventral mesencephalon on footshock-induced increases in the biochemically estimated activity of mesotelencephalic dopamine neurons to better understand the involvement of NT as a transducer of the effects of stress on dopamine neuronal activity. The distinct topography of conditioned versus unconditioned stress on the concentration of NT-LI in the dopamine cell body groups of the ventral mesencephalon suggests that NT may be involved in the differential activation of distinct dopamine neuronal populations by these different stressors.(ABSTRACT TRUNCATED AT 400 WORDS)

Selective activation of mesoamygdaloid dopamine neurons by conditioned stress: attenuation by diazepam

Populations of dopamine (DA) neurons in the rat brain are selectively activated by stress, and the response is attenuated by the administration of anxiolytics. Given the role of the component nuclei of the amygdaloid complex in conditioned associations, stress responses and the anxiolytic effects of benzodiazepines, we hypothesized that particular mesoamygdaloid DA projections might be especially sensitive to the effects of conditioned stress and to diazepam (DZ). We mapped the effect of a conditioned stressor on the concentration of the DA metabolite homovanillic acid (HVA) in distinct amygdaloid nuclei and other brain nuclei and areas and the effect of DZ (1 or 3 mg/kg) on the conditioned response in drug-experienced subjects. The conditioned stress paradigm resulted in significant elevations in classical indices of stress, including serum corticosterone and plasma epinephrine. Conditioned stress-induced increases in the estimated activity of DA neurons were specific for DA neurons projecting to the central, basolateral and lateral amygdaloid nuclei, and for DA projections to the dorsal septal nucleus. Conditioned stress-induced increases in the HVA concentration of responsive amygdaloid nuclei were antagonized by low, anxiolytic doses of DZ. These results indicate a role for a subset of mesoamygdaloid DA projections in transducing the impact of perceived stressors on the output of the amygdaloid complex. A role for particular amygdaloid DA projections in the formation of conditioned fear or anticipatory anxiety and its modulation by anxiolytics is also suggested.

The biochemistry and pharmacology of mesoamygdaloid dopamine neurons

Populations of DA neurons innervating the component nuclei of the amygdaloid complex differ in their inferred density of innervation, estimated rate of impulse activity, and adaptive response to the prolonged administration of antipsychotic drugs. Mesoamygdaloid DA neurons have in common the absence of tonically inhibitory, nerve terminal autoreceptors regulating DA synthesis, the nonassociation with a DA-stimulated adenylate cyclase, and the regulation of DA synthesis by receptor-mediated neuronal feedback mechanisms and end-product inhibition. The output of the amygdaloid complex appears to be organized into distinct functions subserved by component nuclei. The present findings suggest a differing role for DA afferents in modulating the functional output of discrete nuclei. The significance of this focal influence will be speculative pending a more complete understanding of the physiology of DA neurotransmission in the amygdaloid complex. Populations of DA neurons innervating discrete amygdaloid nuclei exhibit a composite of mechanisms of regulation and signal transduction and pharmacology that differ from that of other mesotelencephalic DA systems. These comparisons highlight the fact that the nucleus accumbens and olfactory tubercle do not represent or reflect DA neurotransmission in the limbic system. The study of the physiology, pharmacology, and pathology of mesolimbic DA neurons can and should extend beyond the nucleus accumbens and olfactory tubercle to the amygdala and other brain structures central to the organization of the limbic system. It is our opinion that the term "mesolimbic" DA system has purely anatomical connotations and that a more specific terminology (e.g., meso-central amygdaloid nuclear) would express the functional organization of this system more accurately.

Differential effects of antipsychotic drugs on the neurotensin concentration of discrete rat brain nuclei

The present study mapped the topographic distribution of, and the effect of neuropharmacologically distinct antipsychotic drugs on, the concentration of neurotensin (NT) in the rat brain at the level of discrete nuclei or areas. The chronic administration of either haloperidol or clozapine increased the concentration of NT-like immunoreactivity (NT-LI) in the nucleus accumbens and decreased it in the medial prefrontal and cingulate cortex and in the interstitial (bed) nucleus of the stria terminalis. In contrast, the prolonged administration of haloperidol, but not clozapine, increased the concentration of NT-LI in the anterior caudate nucleus and posterior caudate-putamen. The concentration of NT-LI in the great majority of the rat brain nuclei examined was unaffected by the chronic administration of either antipsychotic drug. This pattern of pharmacological response distinguishes NT from all other neuropeptides which have been shown to be influenced by prolonged antipsychotic drug administration. These findings suggest that the functional information imparted to NT-containing cells by neuronal dopamine (DA) release, as inferred from the consequences of receptor blockade, varies remarkably between different populations of DA neurons and further implicate NT as a neuroanatomically-selective neurochemical substrate of the adaptive responses mediating the therapeutic and motoric side effects of antipsychotic drugs.

Absence of synthesis-modulating nerve terminal autoreceptors on mesoamygdaloid and other mesolimbic dopamine neuronal populations

The present study sought to map the distribution of dopamine (DA) synthesis-modulating autoreceptors on DA nerve terminals innervating the amygdala and other limbic structures of the rat brain at a level of anatomic resolution (i.e., discrete component nuclei) commensurate with the functional organization of such structures. The biochemically estimated response of mesoamygdaloid and other limbic DA neuronal populations to conditions of minimal (gammabutyrolactone administration or surgical axotomy) and maximal (low-dose apomorphine administration) activation of nerve terminal DA autoreceptors was examined and compared to the response of mesostriatal and mesocortical DA neurons. In contrast to the caudate nucleus, nucleus accumbens, and olfactory tubercle, neither gammabutyrolactone (GBL) nor axotomy increased biochemically estimated DA synthesis (DOPA accumulation) in any of the amygdaloid nuclei, the anterior amygdaloid area, septal nuclei, or subdivisions of the interstitial (bed) nucleus of the stria terminalis. These results indicate that, similar to the medial prefrontal cortex and median eminence, DA synthesis in mesoamygdaloid and other subcortical limbic DA neuronal populations is not under the regulatory influence of tonically active, nerve terminal-localized autoreceptors. Both GBL and axotomy increased DOPA accumulation in the anterior cingulate cortex, but not in allocortical projection fields. In contrast to the differential distribution of DA synthesis-modulating terminal autoreceptors, the end-product inhibition of tyrosine hydroxylase activity appears to be a ubiquitously expressed regulatory property of DA neurons. The decrease in DA metabolism produced by the administration of a low, presumably auto-receptor-selective, dose of apomorphine exhibited a DA neuronal population distribution distinctly unlike that of the aforementioned effects of GBL or axotomy on DOPA accumulation. These results reinforce the DA neuronal population-selective distribution of synthesis-modulating autoreceptors and indicate that nerve terminal-localized autoreceptors are operative in regulating DA synthesis in only a minority of DA-innervated brain structures. Further, the demonstration of such autoreceptors is dependent upon the preparation, pharmacological tools, and functional endpoints chosen for study.