Lateral hypothalamic lesions: effects on Pavlovian cardiac and eyeblink conditioning in the rabbit

A model of amygdala-hippocampal-prefrontal interaction in fear conditioning and extinction in animals

Empirical research has shown that the amygdala, hippocampus, and ventromedial prefrontal cortex (vmPFC) are involved in fear conditioning. However, the functional contribution of each brain area and the nature of their interactions are not clearly understood. Here, we extend existing neural network models of the functional roles of the hippocampus in classical conditioning to include interactions with the amygdala and prefrontal cortex. We apply the model to fear conditioning, in which animals learn physiological (e.g. heart rate) and behavioral (e.g. freezing) responses to stimuli that have been paired with a highly aversive event (e.g. electrical shock). The key feature of our model is that learning of these conditioned responses in the central nucleus of the amygdala is modulated by two separate processes, one from basolateral amygdala and signaling a positive prediction error, and one from the vmPFC, via the intercalated cells of the amygdala, and signaling a negative prediction error. In addition, we propose that hippocampal input to both vmPFC and basolateral amygdala is essential for contextual modulation of fear acquisition and extinction. The model is sufficient to account for a body of data from various animal fear conditioning paradigms, including acquisition, extinction, reacquisition, and context specificity effects. Consistent with studies on lesioned animals, our model shows that damage to the vmPFC impairs extinction, while damage to the hippocampus impairs extinction in a different context (e.g., a different conditioning chamber from that used in initial training in animal experiments). We also discuss model limitations and predictions, including the effects of number of training trials on fear conditioning.

Neural circuits and mechanisms involved in Pavlovian fear conditioning: a critical review

Pavlovian or classical fear conditioning is recognized as a model system to investigate the neurobiological mechanisms of learning and memory in the mammalian brain and to understand the root of fear-related disorders in humans. In recent decades, important progress has been made in delineating the essential neural circuitry and cellular-molecular mechanisms of fear conditioning. Converging lines of evidence indicate that the amygdala is necessarily involved in the acquisition, storage and expression of conditioned fear memory, and long-term potentiation (LTP) in the lateral nucleus of the amygdala is often proposed as the underlying synaptic mechanism of associative fear memory. Recent studies further implicate the prefrontal cortex-amygdala interaction in the extinction (or inhibition) of conditioned fear. Despite these advances, there are unresolved issues and findings that challenge the validity and sufficiency of the current amygdalar LTP hypothesis of fear conditioning. The purpose of this review is to critically evaluate the strengths and weaknesses of evidence indicating that fear conditioning depend crucially upon the amygdalar circuit and plasticity.

Progressive postnatal assembly of limbic-autonomic circuits revealed by central transneuronal transport of pseudorabies virus

The development of neuronal projections to a target and the establishment of synaptic connections with that target can be temporally distinct events, which typically are distinguished by functional assessments. We have applied a novel neuroanatomical approach to characterize the development of limbic forebrain synaptic inputs to autonomic neurons in neonatal rats. Transneuronal labeling of preautonomic forebrain neurons was achieved by inoculating the ventral stomach wall with pseudorabies virus (PRV) on postnatal day 1 (P1), P4, or P8. In each age group, PRV-positive neurons were present in autonomic and preautonomic regions of the spinal cord and brainstem 62-64 hr after inoculation. Transneuronal forebrain labeling in rats injected on P8 was similar to the transneuronal labeling reported previously in adult rats and included neurons in the medial and lateral hypothalamus, amygdala, bed nucleus of the stria terminalis, and visceral cortices. However, no cortex labeling and only modest amygdala and bed nucleus labeling were observed in rats injected with PRV on P4, and only medial hypothalamic labeling was observed in rats injected on P1. Additional tracing experiments involving central injections of PRV or cholera toxin beta indicated that lateral hypothalamic and telencephalic regions projected to the medullary dorsal vagal complex several days before establishing synaptic connections with gastric-related autonomic neurons. These results demonstrate a novel strategy for evaluating synaptic connectivity in developing neural circuits and show a temporally segregated postnatal emergence of medial hypothalamic, lateral hypothalamic, and telencephalic synaptic inputs to central autonomic neurons.

Descending projections of infralimbic cortex that mediate stimulation-evoked changes in arterial pressure

The infralimbic cortex (IL) of the rat can modify autonomic nervous system activity, but the critical pathway(s) that mediate this influence are unclear. To define the potential pathways, the first series of experiments characterizes the descending projections of IL and the neighboring cortical areas using Phaseolus vulgaris leucoagglutinin (PHA-L). IL has prominent projections to the central nucleus of the amygdala (Ce), the mediodorsal nucleus of the thalamus (MD), the lateral hypothalamic area (LHA), the periaqueductal gray (PAG), the parabrachial nucleus (Pb), and the nucleus of the solitary tract (NTS). The density and selectivity of these projections suggest that the LHA and the PAG mediate the ability of the IL to regulate cardiovascular function. The second series of experiments demonstrates that locally anesthetizing neurons in either the LHA or PAG with lidocaine attenuates the hypotensive effects produced by electrical stimulation of the IL. Similarly, microinjections of cobalt chloride (a neurotransmission blocker) into the anterior portion of the LHA also decrease the arterial pressure responses to IL stimulation, suggesting that the ability of lidocaine to reversibly block the evoked response is due to inactivation of neurons in the LHA. These data indicate that hypotension evoked by stimulation of IL is mediated, at least in part, by direct or indirect projections to the LHA and through the PAG.

Physiological properties of central medial and central lateral amygdala neurons

Mounting evidence implicates the central (CE) nucleus of the amygdala in the mediation of classically conditioned fear responses. However, little data are available regarding the intrinsic membrane properties of CE amygdala neurons. Here, we characterized the physiological properties of CE medial (CE(M)) and CE lateral (CE(L)) amygdala neurons using whole cell recordings in brain slices maintained in vitro. Several classes of CE neurons were distinguished on the basis of their physiological properties. Most CE(M) cells (95%), here termed "late-firing neurons," displayed a marked voltage- and time-dependent outward rectification in the depolarizing direction. This phenomenon was associated with a conspicuous delay between the onset of depolarizing current pulses and the first action potential. During this delay, the membrane potential (V(m)) depolarized slowly, the steepness of this depolarizing ramp increasing as the prepulse V(m) was hyperpolarized from -60 to -90 mV. Low extracellular concentrations of 4-aminopyridine (30 microM) reversibly abolished the outward rectification and the delay to firing. Late-firing CE(M) neurons displayed a continuum of repetitive firing properties with cells generating single spikes at one pole and high-frequency (> or =90 Hz) spike bursts at the other. In contrast, only 56% of CE(L) cells displayed the late-firing behavior prevalent among CE(M) neurons. Moreover, these CE(L) neurons only generated single spikes in response to membrane depolarization. A second major class of CE(L) cells (38%) lacked the characteristic delay to firing observed in CE(M) cells, generated single spikes in response to membrane depolarization, and displayed various degrees of inward rectification in the hyperpolarizing direction. In both regions of the CE nucleus, two additional cell types were encountered infrequently (< or =6% of our samples). One type of neurons, termed "low-threshold bursting cells" had a behavior reminiscent of thalamocortical neurons. The second type of cells, called "fast-spiking cells," generated brief action potentials at high rates with little spike frequency adaptation in response to depolarizing current pulses. These findings indicate that the CE nucleus contains several types of neurons endowed with distinct physiological properties. Moreover, these various cell types are not distributed uniformly in the medial and lateral sector of the CE nucleus. This heterogeneity parallels anatomic data indicating that these subnuclei are part of different circuits.

Reciprocal changes in the firing probability of lateral and central medial amygdala neurons

The amygdala is essential for classical fear conditioning. According to the current model of auditory fear conditioning, the lateral nucleus is the input station of the amygdala for conditioned auditory stimuli, whereas the central nucleus is the output station for conditioned fear responses. Yet, the lateral nucleus does not project to the central medial nucleus, where most brainstem projections of the amygdala originate. The available evidence suggests that the basal nuclei could transmit information from the lateral to the central medial nucleus. However, interposed between the basolateral complex and the central nucleus are clusters of GABAergic cells, the intercalated neurons, which receive inputs from the lateral and basal nuclei and contribute a massive projection to the central medial nucleus. Because it is impossible to predict the consequences of these connections, we correlated the spontaneous and auditory-evoked activity of multiple simultaneously recorded neurons of the lateral, basal, and central nuclei. The spontaneous activity of lateral and basolateral neurons was positively correlated to that of central lateral cells but negatively correlated to that of central medial neurons. In response to auditory stimuli, the firing probability of lateral and central medial neurons oscillated in phase opposition, initially being excited and inhibited, respectively. In light of previous anatomical findings, we propose that the lateral nucleus exerts two indirect actions on central medial neurons: an excitation via the basal nuclei and an inhibition via intercalated neurons.

Intra-amygdaloid projections of the basolateral and basomedial nuclei in the cat: Phaseolus vulgaris-leucoagglutinin anterograde tracing at the light and electron microscopic level

The amygdaloid complex plays an essential role in auditory fear conditioning of the Pavlovian type. The available evidence suggests that the lateral nucleus is the input station of the amygdala for auditory conditioned stimuli, whereas the central medial nucleus is the output for conditioned fear responses. However, the intrinsic pathway transmitting auditory information about the conditioned stimulus from the lateral to the central medial nuclei is unknown as there are no direct projections between these nuclei. The present study was undertaken to determine if the main intra-amygdaloid targets of the lateral nucleus, namely the basomedial and basolateral nuclei, project to the central medial nucleus. To this end, iontophoretic injections of the anterograde tracer Phaseolus vulgaris-leucoagglutinin were performed in these nuclei. To rule out the possibility that the anterograde labeling reflected passing fibers merging with the major fiber bundles that course in and around the central medial nucleus, labeled terminals and varicosities were observed in the electron microscope. It was determined that the basolateral and basomedial nuclei have partially overlapping intraamygdaloid targets. They both project to the central medial nucleus, nucleus of the lateral olfactory tract and peri-amygdaloid cortex, but have limited projections to each other. Small Phaseolus vulgaris-leucoagglutinin injections in both nuclei gave rise to prominent intranuclear projections but only the basomedial nucleus was found to project to the lateral and anterior cortical nuclei. At the electron microscopic level, all labeled axon terminals and varicosities formed asymmetric synapses (n = 245) with dendritic spines (83%) or with dendritic shafts (17%). This is the first unambiguous demonstration that the basolateral and basomedial nuclei project to the central medial nucleus. Since these nuclei constitute the main intra-amygdaloid targets of the lateral nucleus, they represent likely candidates for the transmission of auditory conditioned stimuli to the central medial nucleus in auditory fear conditioning.

The effect of medial frontal cortex lesions on cardiovascular conditioned emotional responses in the rat

The effect of ventral medial frontal cortex (MFC) lesions on heart rate and blood pressure during conditioned emotional responses (CER) was investigated. Male Sprague-Dawley rats were divided into two groups: MFC-lesioned rats (n = 11) sustained bilateral lesions of the infralimbic and ventral prelimbic regions of the MFC via microinjection of the neurotoxin N-methyl-D-aspartate; Controls (n = 13) received sterile saline. Following a 2-week recovery period, all animals were trained; one of two tones served as the conditioned stimulus (CS) and a 2 mA footshock served as the unconditioned stimulus (US). The CS+ tone was consistently paired with the US, while the CS- tone was randomly paired with the US. Heart rate and blood pressure were recorded during CS+ and CS- presentations before and after administration of the following pharmacological agents: atropine, atenolol, and atropine + atenolol. All animals responded to the CS+ with increased BP compared to baseline; the increase was not significantly different between groups. Controls responded to the CS+ with increased HR, while MFC-lesioned animals displayed a bimodal HR response which was not significantly different from baseline, but was significantly different from Controls. Pharmacological blockade of the HR response revealed coactivation of the sympathetic and parasympathetic nervous systems during the CS+, with a significant decrease (52%) in the sympathetic tachycardia component of the CS+ HR response in MFC-lesioned rats as compared to Controls; the parasympathetic bradycardia component was not altered by MFC lesions. In all cases, CS- responses were smaller than the CS+ responses. Pharmacological analysis revealed that the CS- HR response was mediated by the sympathetic component only, which was also significantly reduced in MFC-lesioned animals as compared to Controls. This significant reduction in the sympathetically mediated HR component of both the reinforced CER (CS+) and the unreinforced CER (CS-) following ventral MFC lesions implies that the MFC is necessary for complete sympathetic activation of cardiovascular responses to both severely and mildly stressful stimuli. The role of the MFC in emotion is also discussed.

Intra-amygdaloid projections of the lateral nucleus in the cat: PHA-L anterograde labeling combined with postembedding GABA and glutamate immunocytochemistry

Research on the implication of the amygdala in classical fear conditioning suggests that the central amygdaloid nucleus is the output station of the amygdala for conditioned fear responses, while the lateral nucleus acts as the input nucleus, at least for auditory conditioned stimuli. However, the nature and locus of the plastic changes taking place between these two nuclei are unknown partly because the neurotransmitter(s) used by intra-amygdaloid projections of the lateral nucleus has not been identified. To address this issue in cats, anterograde tracing with Phaseolus vulgaris-leucoagglutinin (PHA-L) was combined with postembedding immunocytochemistry for gamma-aminobutyric acid (GABA) and glutamate. Two sectors can be recognized in the lateral nucleus of the cat: a shell located laterally along the external capsule, and a core. Iontophoretic injections of PHA-L in these two sectors revealed that they have nonoverlapping intra-amygdaloid targets with the exception of a common projection to the central lateral nucleus. The core projects mainly to itself and to the basomedial nucleus, whereas the shell contributes a massive projection to the basolateral nucleus. No projection of the lateral nucleus to the central medial nucleus was found. Electron microscopically, PHA-L-labeled axon terminals in the lateral, basomedial, basolateral, and central lateral nuclei as well as in the perirhinal and insular cortices formed asymmetric synapses (100%; n = 289) with dendritic spines (77-100%). Moreover, postembedding immunocytochemistry revealed that PHA-L-labeled axon terminals are immunoreactive for glutamate but not GABA. Since most amygdaloid projections to the brainstem originate in the central medial nucleus, these results suggest that intra-amygdaloid targets of the lateral nucleus are involved in the transmission of auditory conditioned stimuli to the central medial nucleus. Moreover, these findings imply that intra-amygdaloid projections of the lateral nucleus use glutamate but not GABA as a neurotransmitter.

Ibotenic acid lesions in the amygdaloid central nucleus but not in the lateral subthalamic area prevent the acquisition of differential Pavlovian conditioning of bradycardia in rabbits

The present study examined the effect of ibotenic acid lesions in the amygdaloid central nucleus (ACe) or in the lateral zona incerta of the subthalamus (LZI) on the acquisition of differential Pavlovian conditioning of bradycardia in rabbits. Previous work has shown that bilateral electrolytic lesions in either ACe or LZI abolished the retention of conditioned heart rate (HR) responses. In order to determine whether these findings were due to destruction of cells intrinsic to ACe or LZI, ibotenic acid lesions were placed bilaterally in either structure or in control sites. Following recovery, animals were subjected to differential Pavlovian conditioning in which one tone (CS+) was paired with periorbital shock and a second tone (CS-) was presented alone. It was found that destruction of cell bodies in ACe, but not LZI, prevented the acquisition of the differential bradycardiac conditioned response. In addition, ACe lesions did not interfere with baseline HR, the HR orienting response, the HR unconditioned response to shock, or the concomitantly conditioned corneoretinal potential. The results of this study suggest that destruction of cells intrinsic to ACe selectively prevents the acquisition of differentially conditioned HR, and perhaps other conditioned responses related to conditioned arousal, but does not affect unlearned HR responses or specific somatomotor conditioned responses.

Conditioned inhibition of the nictitating membrane response in rabbits following hypothalamic and mesencephalic lesions

Rabbits were trained on a Pavlovian conditioned inhibition (CI) task using light as the reinforced conditioned stimulus (CS+) and the same light compounded with a tone as the nonreinforced CS-. The conditioned response was the nictitating membrane response. After attaining a criterion of CI performance, animals received radio-frequency lesions of the hypothalamus (n = 11) or midbrain (n = 14). For the hypothalamic lesion cases, primary damage extended from the optic chiasm to the pretectal region. For the mesencephalic lesion cases, primary damage ranged from the most rostral portions of the periaqueductal grey (PAG) caudally to the tegmental reticular formation at the level of the third nerve. Prior research suggested that the hypothalamic lesions would disrupt retention of CI by increasing responding to the CS-. Except where a lesion impinged upon the zona incerta, no CI disruption was observed. In accordance with previous studies (Berthier, N.E. and Moore, J.W., Physiol. Behav., 25 (1980) 667-673; Mis, F.W., J. Comp. Physiol. Psychol., 91 (1977) 975-988), post-lesioning CI disruption was observed in some of the mesencephalic lesion cases involving the posterior commissure, PAG and/or accessory oculomotor nuclei. However, CI performance recovered over the course of retraining.

Role of the prefrontal--thalamic axis in classical conditioning

The major conclusion to be drawn from the above-described research on the role of the PFCag in classical conditioning is obviously that it plays a primary and perhaps necessary role in the establishment of visceral cues associated with exposure to classical conditioning contingencies. Specifically, these visceral changes appear to be of an inhibitory character. This is significant, since we have postulated that inhibitory cardiac changes invariably accompany initial processing of sensory stimuli for informational value. Such visceral changes are thus not epiphenomena associated with other simultaneously occurring physiological events. A variety of lesion experiments implicate the PFCm as a central structure in this process, since damage to this area greatly attenuates, and in the case of hypothalamic knife cuts, completely eliminates learned bradycardia. Neuroanatomical tract-tracing experiments revealed that the PFCm and lag have direct projections to the NTS and DVM in the dorsomedial medulla and the nucleus ambiguous in the ventral medulla, all of which provide medullary output control of visceral activities. The nucleus ambiguous and DVM have been specifically implicated in vagal control in the rabbit (Ellenberger et al., 1983). Electrical stimulation of the PFCm provides additional evidence that this area of the brain participates in parasympathetic activities, including cardiac inhibition, since stimulation of the entire MD projection cortex, including the PFCm, produces HR decelerations accompanied by depressor responses. However, since lesions of the Iag produced relatively little effect on conditioned bradycardia, this part of the PFCag does not appear to play a major role in the development of conditioned bradycardia. Electrophysiological recording studies, including both multiple unit as well as extracellular single unit studies reinforce these conclusions. A short latency (40-180 msec) CS-evoked increase in MUA was recorded from cells in both the dorsomedial as well as central PFCm. The magnitude of these CS-evoked neuronal changes (a) was correlated with the magnitude of concomitantly occurring conditioned bradycardia; (b) was trial-related; (c) was not obtained in a similar pseudoconditioning group; and (d) declined to pretraining levels during subsequent experimental extinction. Similar, but not identical, CS-evoked changes in neuronal activity were recorded from MD. Although tone-evoked increases in MUA were also obtained from the Iag, this activity did not show the characteristics of associative learning. Single unit analysis also suggests the importance of the PFCm in elicitation of conditioned bradycardia.(ABSTRACT TRUNCATED AT 400 WORDS)

Age-related changes in associative learning: studies in rabbits and rats

Two experimental models for studying age-related changes in associative learning are described. One involves classical (Pavlovian) conditioning of eyeblink and heart rate in the rabbit. The second involves Pavlovian leg flexion and heart rate conditioning in the rat. Advantages and disadvantages of each model are discussed. Results with both models suggest differential effects of aging on acquisition of autonomic and somatomotor responses, thus underlining the utility of assessing multiple response systems to adequately characterize age-related changes in learning and memory.

Neuronal correlates of classically conditioned bradycardia in the rabbit: studies of the medial prefrontal cortex

Multiple-unit activity (MUA) in the agranular medial prefrontal cortex (PFC) was recorded in conscious rabbits during a classical conditioning procedure involving repeated pairings of a 4-s tone conditioned stimulus (CS) with eye shock. Prior to behavioral training, significant tone-evoked increases in prefrontal MUA were observed; the magnitude of this evoked cortical discharge declined with repeated presentations of the tone alone. However, the first few paired presentations of tone with eye shock served to rapidly reestablish the evoked activity, and subsequent pairings resulted in a significant enhancement of CS-evoked discharge, relative to pretraining response levels. These associative training-induced changes in prefrontal MUA appeared to parallel the development of bradycardiac conditioned responses (CRs), and, in fact, significant correlations between the neuronal and behavioral responses were observed. In contrast to these associative effects, non-associative training procedures involving either unpaired presentations of tone and eye shock or repeated presentations of the tone alone resulted in progressive attenuation of tone-evoked MUA, relative to pretraining levels. We had previously reported that bilateral destruction of the medial PFC seriously compromises the development of discriminative heart rate CRs in the rabbit. In light of this finding, our present results lend further support to the suggestion that associative training-induced changes in CS-evoked neuronal activity in this cortical region contribute, at least in part, to the development of learned cardiovascular adjustments in this animal.

Role of auditory cortex in the acquisition of differential heart rate conditioning

Previous findings from our laboratory indicate that lesions of the auditory cortex disrupt the retention of differentially conditioned bradycardiac responses to tonal stimuli in rabbits. In the present experiment, the effect of lesions of the auditory cortex on the acquisition of differential bradycardiac conditioning was examined. The effect of lesions in the auditory cortex were compared to the effect produced by control lesions in the visual cortex. After 7 days of recovery, animals received 7 days of differential Pavlovian bradycardiac conditioning in which one tone (CS+) was paired with the unconditioned stimulus, and another tone (CS-) was never paired with the unconditioned stimulus. All animals demonstrated differential conditioning during the first 3 days of conditioning. On days 4-7, however, auditory cortex lesioned animals did not exhibit significant differential heart rate (HR) conditioning, whereas control animals with lesions in the visual cortex showed no loss of conditioning during this period. The loss of differential conditioning in animals with lesions in the auditory cortex appears to be due to an increase in the magnitude of the response to the CS-. These data support the hypothesis that the auditory cortex serves to inhibit the response to the CS- in differential conditioning of bradycardia to acoustic stimuli, and that the inhibition may be mediated by a descending corticothalamic or corticolimbic pathway.

Involvement of cortical and thalamic auditory regions in retention of differential bradycardiac conditioning to acoustic conditioned stimuli in rabbits

Our previous findings indicate that lesions in the medial division of the medial geniculate nucleus (mMGN) prevent the acquisition of differential conditioning of bradycardia to acoustic stimuli in rabbits. In the present experiment, the effect of lesions in mMGN on retention of differential bradycardiac conditioning was examined. In addition, the possible involvement of auditory cortex in differential conditioning was investigated. Electrodes were chronically implanted in mMGN, the ventral division of the medial geniculate nucleus (vMGN), or auditory cortex. After 7 days of recovery, animals received one differential Pavlovian conditioning session. At the end of the session, lesions were produced through the implanted electrodes. All animals demonstrated differential bradycardiac conditioning during the prelesion session. Animals with vMGN lesions also demonstrated differential conditioning during the postlesion session. However, mMGN and auditory cortex lesion animals failed to demonstrate differential conditioning during the postlesion session due to an increased response magnitude to the unpaired tone (CS-). These data support the hypothesis that mMGN plays a role in differential conditioning of bradycardia to tonal stimuli. In addition, these findings suggest that a possible corticothalamic pathway may be involved in the inhibition of the response to the CS-.

Comparison of 3H-spiperone binding in caudate nuclei of rabbits and rats

3H-Spiperone binding and inhibition by competing ligands were studied in caudate nucleus homogenates from Sprague-Dawley rats and New Zealand albino rabbits. 3H-Spiperone binding sites were very similar in the two species and had pharmacological profiles characteristic of D2-dopamine receptors, in accordance with previous reports. However, differences occurred between the species in the potencies with which dopaminergic ergots and other drugs interacted with these binding sites and with regard to the compounds used to define specific binding. These findings suggest that slight differences in relative proportions of subtypes of 3H-spiperone binding sites, or of neuroleptic potencies at these subtypes, may exist between rabbits and rats.

Ibotenic acid lesions in the medial geniculate region prevent the acquisition of differential Pavlovian conditioning of bradycardia to acoustic stimuli in rabbits

The present study examined the effect of ibotenic acid lesions in the medial portion of the medial geniculate nucleus (mMGN) on differential heart rate (HR) conditioning to acoustic stimuli in rabbits. Lesions in mMGN prevented the acquisition of differential HR conditioned responses but not bradycardiac responses to the conditioned stimuli. The data suggest that cells in this region play an important role in the discriminative component of HR conditioning.

Sinoaortic denervation does not prevent differential Pavlovian conditioning of bradycardia in rabbits

Recent findings suggest that descending projections from the amygdaloid central nucleus (ACE) to the nucleus of the solitary tract (NTS) may modulate the baroreceptor reflex and thereby facilitate the expression of the bradycardiac conditioned response (CR) in rabbits. The purpose of the present study was to examine the role of the afferent limb of the baroreceptor reflex in differential Pavlovian conditioning of bradycardia in rabbits. Animals received either aortic denervation, sinoaortic denervation or sham denervation. After recovery from surgery, animals received one differential Pavlovian conditioning session per day over the next 6 days. Sinoaortic denervation abolished the baroreceptor reflex as assessed by intravenous injections of phenylephrine. In addition, sinoaortic denervation increased baseline heart rate (HR), altered the topography of the HR unconditioned response, but did not abolish the HR orienting response or prevent the acquisition of bradycardiac CRs. The findings of the present study suggest that afferent barosensory input is necessary for the expression of the HR CR in rabbits. However, descending ACE projections may still play a role in the HR CR by directly affecting NTS neurons.

Effects of electrical stimulation of the pontine A5 cell group on blood pressure and heart rate in the rabbit

The effects of electrical stimulation of the A5 noradrenergic cell group of the ventrolateral pons was assessed in rabbits. Stimulation administered through either concentric bipolar or monopolar electrodes produced current-intensity related increases in mean arterial pressure (MAP). Decreases in heart rate (HR) accompanied the increases in MAP, but were essentially eliminated by bilateral vagotomy or destruction of the nucleus and tractus solitarii (NTS), thereby indicating that the HR decelerations were secondary to activation of baroreceptor reflexes. Neither vagotomy nor midcollicular section of the brainstem altered the MAP response to A5 stimulation. Bilateral destruction of the NTS slightly enhanced the response. Several rabbits received microinjections of 6-hydroxydopamine (6-OHDA) into the A5 region 2 weeks before the experiment. Other rabbits received vehicle injections and served as control subjects for the non-specific effects of the 6-OHDA injections. 6-OHDA injections, but not vehicle injections, prevented the vasopressor effects of A5 stimulation. However, stimulation of the A1 noradrenergic nucleus of the ventrolateral medulla produced decreases in MAP in rabbits given prior microinjections of 6-OHDA into A5. These observations are interpreted to indicate that the 6-OHDA injections produced neurotoxic effects which were relatively restricted to the A5 region. Furthermore, the data from all of these experiments are interpreted as indicating that the vasopressor effects observed as a consequence of electrical stimulation of A5 are due to excitation of the noradrenaline-containing neuron cell bodies of this region and that this effect is mediated via pathways arising from this region and terminating in the intermediolateral cell column of the spinal cord.

The role of amygdaloid central nucleus in the retention of differential pavlovian conditioning of bradycardia in rabbits

The present study examined the role of the amygdaloid central nucleus (ACE) in the retention of differential pavlovian conditioning of bradycardia in rabbits. Electrodes were implanted bilaterally in ACE or in control sites just dorsal and rostral to ACE. Following recovery, animals were subjected to differential pavlovian conditioning in which one tone (CS+) was paired with periorbital shock and a second tone (CS-) was presented alone. Subsequent electrolytic lesions abolished the heart rate (HR) conditioned response (CR), yet had no effect on HR orienting response, unconditioned response, or baseline. In a follow-up experiment, corneoretinal potential (CRP) and HR were recorded. Bilateral ACE lesions profoundly attenuated or abolished the HR CR without abolishing CRP CRs. The major finding of this study is that bilateral lesions of ACE selectively attenuate the HR CR while not necessarily abolishing other CRs.

The role of the medial geniculate region in differential Pavlovian conditioning of bradycardia in rabbits

The present study examined the role of the medial geniculate region (MGN) in differential Pavlovian conditioning of bradycardia and corneo-retinal potential (CRP) to acoustic stimuli in rabbits. Injections of horseradish peroxidase into the amygdala central nucleus, an area that mediates the bradycardia-conditioned response (CR), produced cell body and fiber labeling at the ventral and medial borders of the MGN. Then, bilateral electrolytic lesions were made at the medial border of the MGN or in control sites dorsal and/or rostral to the MGN. Ten days after surgery, lesioned and unoperated control animals were subjected to 7 days of differential Pavlovian conditioning. In the control lesion and unoperated groups, the CS+ consistently elicited larger bradycardia responses than the CS-. However, animals with bilateral lesions in the medial MGN did not demonstrate differential bradycardia CRs. Bradycardia response magnitude in MGN lesion animals was not affected. Evidence of CRP differential conditioning was present in each group. The present findings suggest that a region just medial to the MGN is involved in bradycardia differential conditioning in rabbits. The fact that bradycardia responses were still present after medial MGN lesions suggests that other auditory regions may also be involved in the mediation of the bradycardia CR.

Pizotifen (BC-105) attenuates orienting and Pavlovian heart rate conditioning in rabbits

The cardiac component of the orienting reflex (OR) was elicited in rabbits by 75 dB, 4-sec duration tones of either 304 or 1216 Hz. The conditioned cardiac response was also studied using the same tones and paraorbital electric shock as conditioned and unconditioned stimuli, respectively, using a differential Pavlovian conditioning paradigm. Subcutaneous injections of the central 5-HT antagonist pizotifen (BC-105), the peripheral 5-HT antagonist xylamidine, the central 5-HT agonist d-lysergic acid diethylamide (LSD), and LSD in conjunction with BC-105 were administered 15 min prior to behavioral assessment. Both the heart rate (HR) conditioned response (CR) and the OR consisted of bradycardia. BC-105 attenuated, but xylamidine had no effect on, OR habituation. LSD reduced the magnitude of the OR, an effect which was blocked by BC-105. BC-105 also produced a dose-related attenuation of the bradycardiac HR CR; however, xylamidine had no effect on HR conditioning, suggesting that the attenuation of the HR CR by BC-105 was central rather than peripheral in origin. LSD potentiated the bradycardiac HR CR, but BC-105 in conjunction with LSD attenuated this response. These results suggest that central 5-HT neurons may modulate the magnitude of bradycardiac responses during orienting and aversive Pavlovian conditioning.

Multiple unit activity recorded from amygdala central nucleus during Pavlovian heart rate conditioning in rabbit

Using a Pavlovian heart rate conditioning paradigm, a rapid development of short latency increases in the multiple unit activity of the amygdala central nucleus were observed in response to a tone conditioned stimulus. In some cases the increase in multiple unit response showed a parallel development with the conditioned decelerative heart rate response and were significantly correlated with it. These results suggest a direct role for the central nucleus in the expression of conditioned heart rate responding in rabbit.

Forebrain norepinephrine and serotonin concentrations and cardiac conditioning in normal rabbits and rabbits with septal lesions

Septal lesioned or sham operated rabbits were subjected to two days of differential Pavlovian (classical) heart rate (HR) conditioning in which tones served as the conditioned stimuli and paraorbital electric shock served as the unconditioned stimulus. After completion of training, norepinephrine (NE) and serotonin (5-HT) concentrations were determined in the hippocampus and neocortex to determine if lesion-induced amine depletion was related to changes in HR conditioned response (CR). The magnitude of the bradycardiac CR was increased by septal lesions during the initial session but during the second session. several lesioned animals revealed accelerative HR changes resulting in an attenuated HR CR in the septal damaged group. The more accelerative HR responding in the septal lesioned animals was accompanied by increased EMG activity which appeared to be related to damage to more posteroventral areas of the septum. Septal lesions produced a depletion of forebrain NE of approximately 30%, but NE concentrations did not appear to be specifically related to lesion-induced changes in the HR CR. However, both NE and 5-HT concentrations were correlated with the magnitude of the HR CR in intact, but not in lesioned, animals.