Effects of electrical stimulation of the amygdaloid central nucleus on neocortical arousal in the rabbit.

This study sought to determine whether electrical stimulation of the amygdaloid central nucleus (ACe) produces cholinergically mediated neocortical arousal manifested in the suppression of frontal cortex delta wave (1-4 Hz) activity. Stimulation in both anesthetized and conscious rabbits produced a suppression of delta activity that was accompanied by bradycardia and blocked by cholinergic antagonists. Stimulation of the adjacent putamen did not produce delta suppression, whereas stimulation of the adjacent ventral globus pallidus produced a suppression of shorter duration than that produced by ACe stimulation. The results suggest that the ACe influences neocortical arousal, which may be mediated by its influence on the activity of cholinergic neurons of the nucleus basalis.

Anatomical and physiological relationships between the anterior cerebellar vermis and the pontine parabrachial nucleus in the rabbit.

The anatomical connections between the midline cerebellum and the pontine parabrachial nucleus (PBN) were investigated in the rabbit using anterograde and retrograde axonal transport techniques. Small injections (20-50 nl) of cholera toxin conjugated to horseradish peroxidase (CT-HRP) or wheat germ agglutinin conjugated HRP (WGA-HRP) into the cortex of the anterior cerebellar vermis resulted in retrograde and anterograde-like label in the PBN. Focal injections of tracer into the PBN resulted in anterogradely labeled processes in the ACV and retrogradely labeled a small, but distinct group of Purkinje cells within the anterior vermis. Focal injections into the rostral fastigial nuclei (FN) resulted in anterograde-like label in the PBN, and PBN injections labeled FN neurons. Furthermore, the projection from the PBN to ACV is effective in driving cerebellar neurons as electrical microstimulation of the PBN evoked short-latency, phasic responses in ACV Purkinje cells. These experiments generated anatomical and physiological evidence for the existence of a neuroanatomical circuit connecting the midline cerebellum (ACV, FN) with the PBN, that may serve as a functional interface between the midline cerebellum and other brain stem nuclei with cardiovascular function, particularly with respect to the midline cerebellar role in classically conditioned cardiovascular responses.

The anterior cerebellar vermis: essential involvement in classically conditioned bradycardia in the rabbit.

The effects of lesions of the cerebellum on the acquisition and retention of aversive Pavlovian conditioned bradycardia were examined in rabbits. Lesions of the anterior cerebellar vermis severely attenuated the acquisition of simple conditioned bradycardia without disrupting baseline heart rate (HR), or unconditioned HR responses. Also, lesions of the vermis performed after the acquisition of conditioned bradycardia eliminated evidence of prior conditioning. Bilateral lesions of the cerebellar hemispheres did not affect conditioned or unconditioned HR responses. These results were interpreted to indicate that anterior vermis lesions specifically disrupted part of an essential conditioned response pathway without interfering with the neural circuits that mediate unconditioned HR responding. These lesion data, coupled with recent electrophysiological evidence of learning-related changes in neuronal activity within the anterior vermis of the fear-conditioned rabbit, suggest that the anterior cerebellar vermis is critically involved in the acquisition and retention of this rapidly learned autonomic conditioned response.

Purkinje cell responses in the anterior cerebellar vermis during Pavlovian fear conditioning in the rabbit.

Extracellular single-unit recordings of Purkinje cells in the anterior cerebellar vermis (ACV) of the rabbit found evidence of short-latency (20-30 ms) differential responses to discriminatively-conditioned auditory stimuli during Pavlovian fear conditioning procedures. These differential unit responses appeared to be a function of learning as differential ACV Purkinje cell responses were not observed in naive (untrained) animals. Some of these evoked neurophysiological responses were also correlated with the behavioral conditioned autonomic response. (CAR); a conditioned bradycardiac response. These electrophysiological data, coupled with previous lesion results, suggest that the ACV is part of an important neural circuit for Pavlovian conditioned bradycardia.

Hypothalamic modulation of Purkinje cell activity in the anterior cerebellar vermis.

Intricate anatomical connections exist between the cerebellar vermis and the hypothalamus. This study examined the effects of electrical microstimulation of the hypothalamus on Purkinje cell activity in the anterior cerebellar vermis (ACV) in the awake rabbit. Single-pulse stimulation of the hypothalamus evoked robust, short-latency modifications of Purkinje cell discharge. Heterogeneous response profiles were observed with cells demonstrating patterns of either unimodal excitation, biphasic excitation/inhibition or complex triphasic responses. These results support the hypothesis that the hypothalamus and ACV are functionally interactive, and may promote further understanding of the role of the ACV in emotional behavior and autonomic responses.

Medial cerebellum and long-term habituation of acoustic startle in rats.

Three experiments assessed the effects of damage to the medial cerebellum on long-term habituation (LTH) of the acoustic startle response. Experiment 1 replicated previous results. Lesions of the cerebellar vermis blocked LTH without affecting initial response levels or short-term habituation (STH). The lesions did not disrupt LTH of a simultaneously measured lick-suppression response. In Experiment 2, vermal lesions again blocked LTH of acoustic startle. Control lesions of the cerebellar hemispheres did not affect LTH. In Experiment 3, lesions to the medial (fastigial) cerebellar nuclei blocked LTH. Lesions to the lateral (dentate and interpositus) nuclei did not affect LTH. It is concluded that the medial cerebellum (cortex and nuclei) is part of the essential circuitry for LTH of acoustic startle, whereas the lateral cerebellum is not involved in the basic habituation process.

Lesions of the cerebellar vermis and cerebellar hemispheres: effects on heart rate conditioning in rats.

The effects of lesions of the cerebellum on the acquisition of heart rate (HR) conditioned responses (CRs) were examined in rats. Large lesions of the cerebellar vermis severely attenuated the acquisition of differentially conditioned bradycardic responses in restrained rats without affecting unconditioned HR responses to the tone conditioned stimuli (CSs) or the shock unconditioned stimulus (UCS). In a second experiment, rats were trained unrestrained, and under these conditions the CR was tachycardia in control animals. Lesions of the vermis again severely attenuated acquisition of this CR without affecting unconditioned responses to the CSs or UCS. Bilateral lesions of the cerebellar hemispheres did not affect HR conditioning in either test procedure. It is concluded that the vermis of the cerebellum is an essential component of an HR conditioning circuit in the rat. The cerebellar hemispheres, which are critically involved in some discrete somatomotor CRs, apparently have no essential functional contribution to HR conditioning. The results of these experiments implicating the midline cerebellar vermis in autonomic conditioning are discussed in relation to contributions from a forebrain system involved in HR conditioning and in relation to lateral cerebellar contributions to discrete somatomotor CRs.

Cerebellar vermis: essential for classically conditioned bradycardia in the rat.

The effects of lesions of the cerebellar vermis on the acquisition of heart-rate conditioning in rats was examined. Lesions of the vermis severely attenuated the acquisition of conditioned bradycardic responses in a simple conditioning procedure in restrained rats. Importantly, the vermal lesions did not affect resting heart-rate, unconditioned heart-rate orienting responses to a tone stimulus or unconditioned heart-rate responses to the shock unconditioned stimulus. It is concluded that the cerebellar vermis is an essential component of a heart-rate conditioned response circuit in the rat. The similarities between these effects and those following manipulations of the amygdala are discussed.

Response characteristics of neurons in the medial component of the medial geniculate nucleus during Pavlovian differential fear conditioning in rabbits.

Recent evidence suggests that the amygdaloid central nucleus (ACE) may contribute significantly to Pavlovian fear-conditioned bradycardic responses during the presentation of conditioned emotional stimuli. Because the medial component of the medial geniculate nucleus (MGm) is a major source of input to the region of the ACE, the extracellular single-unit responses of MGm neurons were examined during Pavlovian differentially conditioned bradycardic responding in rabbits. Conditioning involved pairing one tone (CS+) with paraorbital shock and presenting another tone (CS-) in the absence of shock. Two general classes of MGm neurons were identified based on their conditioned-response characteristics. Both groups responded differentially to the CSs. One group responded with greater increases in activity and at a shorter latency to the CS+ compared with the CS-, whereas the other group responded with greater increases in activity and at a shorter latency to the CS- compared with the CS+. Recordings from MGm neurons in naive rabbits prior to conditioning provided evidence that the acoustic stimuli used subsequently as the CS+ and CS- did not evoke differential responses. These results suggest that the MGm along with the ACE may be forebrain components of a neural circuit involved in the acquisition and/or expression of Pavlovian fear-conditioned bradycardic responses.

Effects of lesions of the cerebellar vermis on VMH lesion-induced hyperdefensiveness, spontaneous mouse killing, and freezing in rats.

In a series of independent experiments, we showed that lesions of the vermis of the cerebellum in rats blocked the hyperdefensiveness induced by lesions of the ventromedial hypothalamus (VMH), attenuated spontaneous mouse killing, and reduced unconditioned freezing and other signs of fear in the presence of a cat. The vermal lesions did not significantly affect foot-shock conditioned freezing. Control lesions of the cerebellar hemispheres did not affect VMH lesion-induced hyperdefensiveness or freezing in the presence of a cat. The hemispheric lesions did attenuate foot-shock conditioned freezing. The data are discussed in terms of the striking similarities and differences between the behavioral effects of cerebellar vermal lesions and amygdala lesions and the interaction of a number of brain areas in modulating agonistic behaviors. The results leave no doubt that the medial cerebellum is significantly involved in the control of species-specific agonistic behaviors. The specific dimension of agonistic behaviors and the details of the interactions with other brain areas remain a puzzle which we approached here by expanding the behavioral profile of animals with lesions of the cerebellar vermis.

Effects of cerebellar vermal lesions on species-specific fear responses, neophobia, and taste-aversion learning in rats.

The cerebellar vermis has extensive anatomical connections with many brain stem and forebrain structures which have been implicated in emotional or affective behavior. Previous reports indicate that lesions of the vermis in a variety of experimental animals result in altered emotional behavior. The studies reported here attempted to clarify the nature of the change in emotional behavior following vermal lesions in rats by testing the animals in a variety of fear-eliciting situations. As compared with controls, vermal-lesioned rats froze less in the presence of a cat and showed fewer signs of fear in an open field. However, their responses to footshock did not differ fundamentally from controls. They recovered more quickly than controls from the neophobic response to a novel taste but showed robust taste-aversion learning. The results are discussed in terms of the role of the cerebellum in the modulation of fear-related behaviors and in terms of similarities and differences with the effects of amygdala lesions. The results expand the body of data implicating the cerebellum in the modulation of complex motivational behavior.

Cerebellar vermis: essential for long-term habituation of the acoustic startle response.

The acoustic startle response in rats shows both short-term habituation, which recovers in seconds or minutes, and long-term habituation, which is effectively permanent. Lesions of the cerebellar vermis significantly attenuated long-term habituation without affecting the short-term process or altering initial response levels. In this response system the cerebellar vermis is part of an essential circuit for long-term habituation.