Discriminative fear conditioning to context expressed by multiple measures of fear in the rat

Cardiovascular and behavioural components of conditioned fear to context after ganglionic and alpha-adrenergic blockade

This study investigates the contribution of the peripheral nervous system to the cardiovascular component of long lasting (40 min) conditioned fear responses to context. The conditioned fear response evoked by reexposure to a footshock chamber was tested 10 min after intravenous injection of either the nicotinic ganglion blocker chlorisondamine (0.6 mg/kg) or the alpha-adrenoceptor antagonist phentolamine (10 mg/kg) in six rats implanted with telemetric probes. Compared to saline controls, chlorisondamine did not change the behavioural component of the response (freezing, ultrasonic vocalizations) but almost completely abolished its cardiovascular component (mean arterial pressure and heart rate). Phentolamine also abolished the pressor response but increased the cardiac response, and ultrasonic vocalizations were reduced by half. The results indicate that the long lasting pressor response of conditioned fear to context is sympathetically mediated like the much shorter pressor response of conditioned fear to a discrete stimulus.

Conditioned memory modulation, freezing, and avoidance as measures of amygdala-mediated conditioned fear

Three conditioned aversive responses were used to infer the existence of an unobservable central state of "conditioned fear," and the roles of certain amygdala subregions in producing these responses were investigated. Rats received tone-shock pairings in one compartment of a shuttle box and no tones or shocks in the other, distinctive, compartment. They were then trained to find food in one arm of a Y-maze. After the final training trial they were exposed to different sets of stimuli in the shuttle box with no shock. Twenty-four hours later rats that had received immediate posttraining exposure to the conditioned stimuli (in the shock-paired compartment) made significantly more correct responses on the Y-maze than rats that had been exposed to the neutral stimuli (in the no-shock compartment) or rats that had received delayed posttraining exposure to the conditioned stimuli. This constitutes a demonstration of posttraining memory modulation by conditioned aversive stimuli. Freezing increased during posttraining exposure to the conditioned stimuli compared to the neutral stimuli. When subsequently allowed to move freely between the two compartments, the rats in all groups also showed significant conditioned avoidance of the compartment containing the conditioned stimuli. In a second experiment the effects of lesions confined to specific parts of the amygdala on the three conditioned responses (memory modulation, freezing, avoidance) were tested. Lesions of the central nucleus impaired all three conditioned responses; lesions of the medial nucleus impaired conditioned modulation and avoidance. These lesions had no effect on freezing during the training trials. Lesions of the lateral and basolateral nuclei attenuated freezing during both training and testing. The findings suggest that the central and medial nuclei of the amygdala may be important parts of neural circuits mediating conditioned responses that constitute conditioned aversive states, but that conditioned freezing may be mediated independently.

Nucleus accumbens amphetamine microinjections unconditionally elicit 50-kHz ultrasonic vocalizations in rats

The authors have hypothesized that, in adult rats, 50-kHz ultrasonic vocalizations (USVs) index a state characterized by high arousal and expectations of reward. This study was conducted to investigate whether dopamine agonism of the nucleus accumbens (NAcc) could evoke such an appetitive state, by examining the effects of NAcc amphetamine (AMPH) microinjections on USVs. Intra-NAcc AMPH injections (0.3, 1.0, 3.0, 10.0 microg unilaterally) produced robust, dose-dependent increases in 50-kHz USVs, which could not be accounted for by concomitant increases in locomotor activity (LA). However, AMPH injections into dorsal control caudate putamen sites produced a modest, dose-dependent increase in LA without significant increases in 50-kHz USVs. These findings indicate that NAcc AMPH microinjections selectively evoke 50-kHz USVs in rats, supporting the notion that dopamine elevations in the NAcc may unconditionally elicit a state of reward anticipation.

Sex differences, context preexposure, and the immediate shock deficit in Pavlovian context conditioning with mice

The acquisition of context fear in rats is affected by variables such as the sex of the animal, the placement to shock interval (PSI), and preexposure to the context. The current experiments assessed the effects of these variables on context conditioning in mice (C57BL/6). In Experiment 1, mice were placed in a chamber and received a single shock 5s, 20 s, 40s, 60s, 180s, or 720s later. Increasing the PSI produced corresponding increases in conditional freezing during the context test. In addition, male mice acquired more context conditioning than female mice did but only at intermediate PSIs. In Experiment 2, preexposure to the context before training alleviated the sex difference found with an intermediate PSI. The results are discussed in terms of configural learning theory and are argued to be contrary to the predictions of scalar expectancy theory.

Rats with hippocampal damage are impaired on place learning in the water task when overtrained under constrained conditions

To date, numerous investigations have been conducted on the mammalian hippocampus to determine its precise function. This research has implicated a fundamental role for the hippocampus in the formation of a spatial map that an animal can use to appropriately guide behavior in complex relational tasks. Despite substantial evidence to support this view, there have been challenges to this theory of hippocampal function. One alternative view suggests that the hippocampus is involved with the integration and updating of voluntary movement. Therefore, any impairments expressed by rats with hippocampal damage are not due to the inability to form or use a spatial map, but rather arise because they are unable to accurately control and monitor on-line movement. Accordingly, investigators, supporting the latter, claim that animals with hippocampal lesions are able to solve a spatial version of the water task if they are given explicit training on how to get to the hidden platform. In the present study we trained rodents with or without hippocampal damage on a cue/place water task for 40 days. In using behaviorally constraining procedures and by overtraining these animals, we provided them with knowledge of how to get to the hidden platform, and ensured enough time to learn the task. Our findings revealed that although rats with hippocampal lesions showed some place responses, they were significantly impaired on all measures of place learning compared to sham animals under these intensive procedures. Overall, the results of the present study do not support the idea that the hippocampus is not specifically involved in acquisition of place information in the water task.

Is the hippocampus necessary for contextual fear conditioning?

The hippocampus is widely believed to be essential for learning about the context in which conditioning occurs. This view is based primarily on evidence that lesions of the dorsal hippocampus disrupt freezing to contextual cues after fear conditioning. However, lesions that disrupt freezing produce no effect on fear-potentiated startle, a second measure of contextual fear. Moreover, hippocampal lesions also do not disrupt the contextual 'blocking' phenomenon, which provides an indirect measure of contextual fear. In these paradigms, at least, it appears that hippocampal lesions disrupt the expression of freezing, rather than contextual fear itself. This interpretation is supported by the finding that rats showing preserved contextual blocking after hippocampal lesions show deficits not only in contextual freezing, but also in unconditioned freezing. These findings are consistent with a growing body of data from other conditioning paradigms that contextual learning is spared after lesions of the dorsal hippocampus. Nonetheless, there remain some reports of impaired contextual fear conditioning after hippocampal lesions that cannot be attributed easily to a disruption of freezing. Thus, it is concluded that the hippocampus may be involved in contextual learning under certain--as yet, unspecified--circumstances, but is not critical for contextual learning in general.

Conditioned fear to environmental context: cardiovascular and behavioral components in the rat

This study compares the time course of the cardiovascular changes (mean arterial blood pressure, heart rate) and behavioral changes (freezing, rearing, grooming and activity) evoked by 30 min long exposures to a footshock chamber before and after conditioning with footshocks. The main finding is that the conditioned fear evoked by re-exposure to the footshock chamber after conditioning is associated with a prolonged freezing response, a marked rise in mean arterial pressure (+35 mm Hg above a resting baseline of 105 mm Hg) and a delayed rise in heart rate. The pattern of behavioral and cardiovascular changes is the same as with conditioned fear to a discrete stimulus but the effect is a lot longer.

Disruption of contextual freezing, but not contextual blocking of fear-potentiated startle, after lesions of the dorsal hippocampus

The role of the dorsal hippocampus in contextual fear conditioning was investigated with a contextual blocking paradigm. In Experiment 1, rats were given pairings of a light conditioned stimulus (CS) and footshock after preexposure either to footshock or to the context alone. The group preexposed to footshock showed poorer fear conditioning to the light CS, as measured by the fear-potentiated startle reflex. In Experiment 2, a group preexposed to footshock in the same context showed poorer fear conditioning to the light CS than did a group preexposed to footshock in a different context, indicating contextual blocking of fear-potentiated startle. In Experiment 3, lesions of the dorsal hippocampus had no effect on contextual blocking, even though contextual freezing was disrupted. The sparing of contextual blocking indicated that contextual memory was intact following hippocampal lesions, despite the disruption of contextual freezing.

Lesions of the medial or lateral perforant path have different effects on hippocampal contributions to place learning and on fear conditioning to context

The axons of the neurons in the medial and lateral components of the entorhinal cortex (MEC and LEC) form the medial and lateral perforant paths (MPP and LPP) which represent the major source of cortical input to the hippocampus. Anatomical, physiological, and pharmacological studies have shown that MPP and LPP are distinct. Unfortunately, assessment of the functional significance of damage to either of these pathways has not used tasks known to be sensitive to hippocampal function in the rodent. In this study, we performed dissociated lesions of MPP and LPP using a combined physiological and anatomical method. Rats with lesions of either the MPP or the LPP were tested on place learning in the water task and on a discriminative fear conditioning to context task. The results indicated that the MPP, but not LPP, lesions resulted in impaired place learning. The context discrimination data revealed an amygdala-like, reduced fear effect of MPP lesions and an enhanced discriminative fear conditioning to context effect of LPP lesions. Consistent with a two-stage model of spatial learning proposed by Buzsaki (Buzsaki G. Two-stage model of memory trace formation: a role for 'noisy' brain states. Neuroscience 1989;31(3):551-570), the impairment in the water task can be interpreted as reflecting the higher efficiency of the MPP synapses in activating hippocampal neurons. The context discrimination results can be explained by either a dissociation of sensory information that reaches the MEC and LEC, or alternatively, by a dissociation between the limbic nature of the MEC and the sensory nature of the LEC.