The organization of instrumental food-procuring movements in rats]

The roles of the lateral hypothalamus, basolateral nucleus of the amygdalar complex, the second field of the frontal cortex, and ventromedial thalamic nucleus in organization of the fast ballistic food-procuring movements were studied in albino rats. Sequences of uni- and bilateral destruction of the brain structures were assessed by photorecording. Movement-related neuronal activity in these structures was recorded in freely moving animals. A specific involvement of each of the above listed structures in organization of food-procuring movements was shown. The lateral hypothalamus seems to participate in initiation of the motor program and its efficient realization, the basolateral amygdala appears to produce activatory, training, and stabilizing effects. The second field of the motor cortex leads in movement acquisition (i.e., in memorizing) and decision making about triggering the program. The idea about the relay role of the thalamic motor nucleus is supplemented by understanding of its more complex integrative function.     

Influence of the medial raphe nucleus damage on discharge activity of the central and bazolateral nuclei of the amygdala

It has been revealed pronounced differences between neuronal discharge activity of central and basolateral nuclei of amygdala. After midbrain raphe medial nucleus damage discharge activity of amygdalar nuclei markedly changes, mainly by reciprocal manner. It is suggest that serotonergic afferentations from nucleus raphe to show various influence upon discharge activity of central and lateral nuclei of amygdala.     

Food conditioned reflexes in dogs during activation and blockade of the cholinoreactive system of the amygdala

By means of chemical stimulation of subcortical structures it has been found that the cholinoreactive system of the basolateral part of amygdala is involved in realization of secretory component of alimentary conditioned reactions and takes no direct part in accomplishment of the instrumental component. Activation of the cholinoreactive system of the amygdalar basolateral part has an inhibitory effect and the blockade has an activating effect on the realization of the secretory component of alimentary conditioned reactions. A change in characteristics is observed of the differentiation inhibition and of the correlation of conditioned salivation in response to various stimuli presented in a stereotype order.     

Neuronal reactions in field 2 of the frontal cortex, related to organization and performance of food-procuring movements in rats

Movement-related electrical reactions of neuronal units localized in field 2 of the frontal cortex were studied in albino rats performing fast food-procuring movements under conditions of unrestrained behavior. According to the temporal characteristics of the changes in the neuronal spike activity, three types of reactions were classified: (i) activation that forestalled the movement initiation for 1.0–1.5 sec; (ii) activation or inhibition forestalling this beginning for 0.20–0.26 sec; and (iii) activation in the course of a performed movement. Considerations about the involvement of the neurons of various cortical layers in the mechanisms of programing, switching on, and current control of the efficiency of performance of food-procuring movements are proposed, and the role of the frontal cortex in these processes is discussed.     

Neurons of the human basal ganglia (striatum and basolateral amygdala) expressing the enzyme NADPH-d

In human striatum and basolateral amygdala NADPH-d+ neurons were revealed (after Vincent et al., 1983); and in striatum strio-cortical neurons were also revealed using DiI marker (after Dahtstrom and Belichenko, 1995). The NADPH-d+ neurons were numerous in both formations. Staining of NADPH-d+ neurons with their processes, and our previous study of striatal and amygdalar human neurons by Golgi method made it possible to identify the species of neurons with their assessment as sparsely or densely branched. The main efferent neurons of striatum and basolateral amygdala (densely branched medium spiny and bushy spiny, respectively) and their densely branched interneurons were not marked. Efferent NADPH-d+ neurons included the most numerous ones in both formations. A projection of reticular striatal neurons to cortex was also shown. The NADPH-d+ interneurons belonged to sparsely branched forms. In striatum they included slender-dendritic and long-dendritic bipolars (numerous), ordinary bipolars, twisted and large poor-dendritic cells; in amygdala--the same bipolars and radial cells. Thus, the NADPH-d positive cells in the formations under study were represented by more "ancient" or less structurally complex cell forms.     

Role of the amygdalar complex in programing of fast food-procuring movements in rats

Effects of uni- and bilateral electrolytic destruction of the basolateral nuclei of the amygdalar complex on the main parameters of fast food-procuring movements of albino rats were studied in the course of rearrangement of the motor programs; modifications of the parameters were observed both throughout the entire experiment and within each experimental day. The accuracy of the movements was significantly modified, which was manifested in an increase in the number of trials necessary for successful food capturing. An increase in the duration and a decrease in the frequency of the movements were also observed. The studied parameters underwent no complete recovery even on the tenth experimental day. Thus, the basolateral nuclei of the amygdalar complex occupy an important position in the system responsible for rearrangement of motivated automatized movements; when these nuclei are Injured, their function cannot be completely compensated by other brain structures.     

Increased anxiety-like behavior and enhanced synaptic efficacy in the amygdala of GluR5 knockout mice

GABAergic transmission in the amygdala modulates the expression of anxiety. Understanding the interplay between GABAergic transmission and excitatory circuits in the amygdala is, therefore, critical for understanding the neurobiological basis of anxiety. Here, we used a multi-disciplinary approach to demonstrate that GluR5-containing kainate receptors regulate local inhibitory circuits, modulate the excitatory transmission from the basolateral amygdala to the central amygdala, and control behavioral anxiety. Genetic deletion of GluR5 or local injection of a GluR5 antagonist into the basolateral amygdala increases anxiety-like behavior. Activation of GluR5 selectively depolarized inhibitory neurons, thereby increasing GABA release and contributing to tonic GABA current in the basolateral amygdala. The enhanced GABAergic transmission leads to reduced excitatory inputs in the central amygdala. Our results suggest that GluR5 is a key regulator of inhibitory circuits in the amygdala and highlight the potential use of GluR5-specific drugs in the treatment of pathological anxiety.     

Expression of <Emphasis Type="Italic">c-fos</Emphasis> as an index of functional interaction of the frontal cortex and limbic cerebral structures in the course of food-procuring stereotyped movements in rats

We estimated expression of the c-fos gene (a marker of increase in neuronal activity) and manifestations of the histochemical reaction to NADPH-diaphorase (a marker of NO-generating neurons) in the medial prefrontal cortex (MPFC) and forebrain limbic structures of rats in the norm, in the state of starvation, and during realization of long-lasting (60 min) periodic (several times per minute) food-procuring movements of the forelimb. The starvation state or realization of motivated stereotyped forelimb movements were related to significant bilateral increases (P < 0.05) in the levels of c-fos expression in the anterior olfactory (AOP) and cortical (ACo) nuclei and the central (Ce) and basolateral (BLA) nuclei of the amygdala, and also in the pyriform (Pyr), prelimbic (PrL), and inferior limbic (IL) cortices. The described findings demonstrate that the high Fos immunoreactivity in the MPFC and amygdalar structures is related to the motivation state in animals and reflects the active involvement of limbic cerebral structures in the formation of motor programs and also in the stabilization and realization of operant reflexes. Neirofiziologiya/Neurophysiology, Vol. 40, No. 3, pp. 256–259, May–June, 2008.     

Effect of destruction of basolateral nuclei of the amygdala on the character of electrical activity of the dorsomedial thalamic nucleus in rats

Characteristics of slow global and of unit activity in the dorsomedial thalamic nucleus were studied at various times after destruction of nuclei of the basolateral amygdala in semichronic experiments on anesthetized rats. Destruction of this kind was found to cause periodic transformation of the neuronal discharge into rhythmic bursts of spikes, and into the development of bursts of paroxysmal activity in the form of groups of four to six pointed waves with a mean duration of 60.5±20.6 msec, appearing with a frequency of 1.5±0.3 Hz. A change in the coefficient of correlation was found between the duration of bursts and their frequency during the 20–22-sec period of their generation. Interference was demonstrated between bursts and orthodromic focal potentials, evoked by stimulation of the anterior periamygdalar cortex and anterior amygdalar region. Neurons were described with long (up to 1 sec) responses to stimulation of the periamygdalar cortex and amygdalar region, in the form of regular bursts of spikes or tonic activation, correlating with the appearance of a rhythmic after-discharge. Bursts of this kind, which were most marked during the first 3 or 4 days after destruction of the basolateral amygdala, were observed to begin to disappear toward the end of the first postoperative week. It is suggested that one mechanism of the change in the adaptive behavior of animals with destruction of the amygdala is a disturbance, linked with the bursts, of the relay and integrative functions of the dorsomedial thalamic nucleus.     

Imaging synaptic inhibition throughout the brain via genetically targeted Clomeleon

Here we survey a molecular genetic approach for imaging synaptic inhibition. This approach is based on measuring intracellular chloride concentration ([Cl(-)](i)) with the fluorescent chloride indicator protein, Clomeleon. We first describe several different ways to express Clomeleon in selected populations of neurons in the mouse brain. These methods include targeted viral gene transfer, conditional expression controlled by Cre recombination, and transgenesis based on the neuron-specific promoter, thy1. Next, we evaluate the feasibility of using different lines of thy1::Clomeleon transgenic mice to image synaptic inhibition in several different brain regions: the hippocampus, the deep cerebellar nuclei (DCN), the basolateral nucleus of the amygdala, and the superior colliculus (SC). Activation of hippocampal interneurons caused [Cl(-)](i) to rise transiently in individual postsynaptic CA1 pyramidal neurons. [Cl(-)](i) increased linearly with the number of electrical stimuli in a train, with peak changes as large as 4 mM. These responses were largely mediated by GABA receptors because they were blocked by antagonists of GABA receptors, such as GABAzine and bicuculline. Similar responses to synaptic activity were observed in DCN neurons, amygdalar principal cells, and collicular premotor neurons. However, in contrast to the hippocampus, the responses in these three regions were largely insensitive to antagonists of inhibitory neurotransmitter receptors. This indicates that synaptic activity can also cause Cl(-) influx through alternate pathways that remain to be identified. We conclude that Clomeleon imaging permits non-invasive, spatiotemporally precise recordings of [Cl(-)](i) in a large variety of neurons, and provides new opportunities for imaging synaptic inhibition and other forms of neuronal chloride signaling.     

Resolving emotional conflict: a role for the rostral anterior cingulate cortex in modulating activity in the amygdala

Effective mental functioning requires that cognition be protected from emotional conflict due to interference by task-irrelevant emotionally salient stimuli. The neural mechanisms by which the brain detects and resolves emotional conflict are still largely unknown, however. Drawing on the classic Stroop conflict task, we developed a protocol that allowed us to dissociate the generation and monitoring of emotional conflict from its resolution. Using functional magnetic resonance imaging (fMRI), we find that activity in the amygdala and dorsomedial and dorsolateral prefrontal cortices reflects the amount of emotional conflict. By contrast, the resolution of emotional conflict is associated with activation of the rostral anterior cingulate cortex. Activation of the rostral cingulate is predicted by the amount of previous-trial conflict-related neural activity and is accompanied by a simultaneous and correlated reduction of amygdalar activity. These data suggest that emotional conflict is resolved through top-down inhibition of amygdalar activity by the rostral cingulate cortex.     

Impulsation of hypothalamic and amygdalar neurons in bilateral derivations in the state of food motivation

The character of impulsation of single neurons in the lateral hypothalamic and amygdalar central nucleus of rabbits recorded in bilateral derivations during quiet wakefulness, after 24-h food deprivation, and after satiation was studied by plotting autocorrelation histograms and by counting the mean frequency of discharges. During the transition from hunger to satiation, the character of impulsation of neurons in hypothalamus and amygdala changed in different ways: (1) a greater number of hypothalamic than amygdalar neurons changed their mean discharge frequency (85 versus 56%, respectively); (2) in hunger, the number of hypothalamic neurons with delta-frequency oscillations decreased as compared to quiet wakefulness and satiation, and in the amyglala the number of neurons with beta2-frequency oscillations increased; (3) in hunger, the number of hypothalamic neurons with bursting and periodic discharges decreased and the number of amygdalar neurons with equiprobabilistic discharges increased. During state alternation (according to the autocorrelation histograms) the strongest changes in the character of neuronal discharges took place in the left hypothalamus and left amygdala. The maximum differences in neuronal impulsation between the left and right hypothalamus were observed in the state of hunger and between the left and right amygdala, after satiation.     

Effects of acoustic and immobilization stress on background impulse activity of neurons of the central and lateral nuclei of the Amygdala

It was shown that acoustic and immobilization stresses (developed due to a 2.5-h-long session of intensive, 100 dB, acoustic influence and a 2-h-long session of soft fixation of the body and extremities, respectively) result in significant modifications of the characteristics of background impulse activity of neurons of the nuclei of the rat amygdalar complex. Modifications were greater in the lateral nucleus of the amygdala. Possible roles of some structures of the monoaminergic cerebral systems in acute stress-related transformations of the impulse activity generated by neurons of the amygdalar complex are discussed. Neirofiziologiya/Neurophysiology, Vol. 38, No. 2, pp. 131–139, March–April, 2006.     

Formation of temporary connections in dogs following destruction of the amygdaloid complex, head of the caudate nucleus and orbital cortex]

Ablation of the orbital cortical zones in dogs after ablation of the basolateral part of the amygdala and the caudate nucleus head considerably impeded the elaboration of secretory conditioned alimentary reflexes, without affecting the rate of elaboration of simple instrumental food-procuring reaction. The dogs lost however the capacity to differentiate non-reinforced stimuli from reinforced ones, which was revealed in both secretory and instrumental reactions.     

Effect of successive lesions of the hippocampus and amygdaloid body on conditioned-reflex alimentary reactions in rabbits

Bilateral electrolytic lesions of the dorsal hippocamp and basolateral amygdalar complex impede the differential and extinctive inhibition. The damage of the corticomedial amygdala against a background of the dorsal hippocamp deficiency facilitates differentiation and extinction of alimentary reflexes induced by a decrease of the alimentary motivation and by weakening of alimentary conditioned reflexes. Lesions of the dorsal hippocamp after the corticomedial amygdala damage facilitates the training of positive alimentary reflexes, but weakens inhibitory conditioned reflexes.     

Electrical activity of the lateral hypothalamus related to food-procuring movements of rats

On freely moving albino rats we demonstrated that, when fast food-procuring movements are performed, the mass electrical activity of the lateral hypothalamus (LH) is suppressed 1.6–2.0 sec before the movement beginning recorded with a photoelectrical device. Videorecording of the movements and recording of the spike activity of LH units showed that the latter are activated 1.0–0.1 sec before the movement initiation. The LH is considered a motivation-related structure, which serves as a source providing an increase in the excitability of the structures involved in the control of food-procuring movements and, further on, supporting this increased excitability. The LH is also a component of the mechanisms providing formation of the motor program. The role of the LH in the ensemble of motor centers, which organize and control voluntary movements, is discussed.     

Identification of a neuropeptide S responsive circuitry shaping amygdala activity via the endopiriform nucleus

Neuropeptide S (NPS) and its receptor are thought to define a set of specific brain circuits involved in fear and anxiety. Here we provide evidence for a novel, NPS-responsive circuit that shapes neural activity in the mouse basolateral amygdala (BLA) via the endopiriform nucleus (EPN). Using slice preparations, we demonstrate that NPS directly activates an inward current in 20% of EPN neurons and evokes an increase of glutamatergic excitation in this nucleus. Excitation of the EPN is responsible for a modulation of BLA activity through NPS, characterized by a general increase of GABAergic inhibition and enhancement of spike activity in a subset of BLA projection neurons. Finally, local injection of NPS to the EPN interferes with the expression of contextual, but not auditory cued fear memory. Together, these data suggest the existence of a specific NPS-responsive circuitry between EPN and BLA, likely involved in contextual aspects of fear memory.     

Correlation of unit activity of the right and left amygdala in food motivation and emotional stress

Correlation between activities of neurons in the right and left central nuclei of amygdala of rabbits recorded during quiet wakefulness, after 24-h food deprivation, after satiation and during emotional stress (demonstration of a dog) was studied by plotting crosscorrelation histograms. The histogram peaks shifted from zero were observed in 50-67% cases. In hungry animals, in a greater number of cases (52%), the discharge of a neuron in the left amygdala was the first in a pair, and the discharge of the right neuron was delayed (peaks from 10 to 50 and from 130 to 150 ms). The opposite order of discharges was less frequent (36%). When a rabbit saw a dog, the number of common inputs to neurons increased and the leading role of the right amygdalar neurons grew (57%) due to an increase in inhibitory influences from the right to the left amygdala. In most cases, the interaction between amygdalar neurons occurred at the frequencies of the delta range, predominantly, from 2 to 4 Hz.     

Organization of a program of automatized food-procuring movement in rats

With the use of techniques of video- and photorecording, local destruction of the brain structures, and recording of the spike responses, roles of the suprasegmental brain structures in organization and control of automatized food-procuring movements were studied in rats under conditions of unrestrained behavior. It is shown that there are several neuronal populations in the prefrontal cortex related to programing, initiation, and current control of the efficacy of performance of food-procuring movements. The lateral hypothalamus is considered a motivational structure. It acts as the source providing an increase in the excitability and further support of the excitation level in the structures, which are links of the systems controlling food-procuring movements. The lateral hypothalamus is also involved in a system providing formation and final application of motor programs.     

Dependence of the electrical activity of the amygdaloid complex on motivation level and emotional status in the dog

On the basis of spectral analysis of prolonged realizations (hundreds of seconds) of electrosubcorticograms of the amygdalar complexes of three dogs, the effect of increase in power of amygdalar rhythmic activity was found, at the change of motivation level in conditions of dominance of alimentary or defensive motivation independently of its kind. Resonance characteristics of the system responsible for the generation of the given rhythm remain unchanged; this allows to explain the increase of the spectral peak by the rise of the inflow of afferent impulse activity to the amygdala. At presence of competitive motivations no summation of their influences is observed; a more complex effect on the rhythm arises in the amygdala.