Temporal factors control hippocampal contributions to fear renewal after extinction.

Fear can be extinguished by repeated exposure to a cue that signals threat. However, extinction does not erase fear, as an extinguished cue presented in a context distinct from that of extinction results in renewed fear of that cue. The hippocampus, which is involved in the formation of contextual representations, is a natural candidate structure for investigations into the neural circuitry underlying fear renewal. Thus far, studies examining the necessity of the hippocampus for fear renewal have produced mixed results. We isolated the conditions under which the hippocampus may be required for renewal. Rats received lesions of the dorsal hippocampus either prior to tone fear conditioning or following extinction. Fear renewal was measured using discrete tone presentations or a long, continuous tone. The topography of fear responding at test was assessed by comparing "early" and "sustained" renewal, where early fear was determined by freezing to the first discrete tone or the equivalent initial segment of a continuous tone and sustained fear was determined by freezing averaged across all discrete tones or the entire continuous tone. We found that following pretraining damage of the hippocampus, early renewal remained intact regardless of lesion condition. However, sustained renewal only persisted in discrete, but not continuous, tone-tested animals. A more extensive analysis of the topography of fear responding revealed that the disruption of renewal was generated when the tone duration at test began to violate that used during extinction, suggesting that the hippocampus is sensitive to mismatches in CS-duration. Postextinction lesions resulted in an overall reduction of fear renewal. This pattern of results is consistent with those observed for contextual fear conditioning, wherein animals display a resistance to anterograde amnesia despite the presence of a strong retrograde amnesia for the same contextual information. Furthermore, the data support a role for the hippocampus in sustaining renewal when the CS duration at test does not match that used during extinction.

Post-training excitotoxic lesions of the dorsal hippocampus attenuate generalization in auditory delay fear conditioning.

An abundance of evidence indicates a role for the dorsal hippocampus (DH) in learning and memory. Pavlovian fear conditioning provides a useful model system in which to investigate DH function because conditioning to polymodal contextual cues, but generally not to discrete unimodal cues, depends upon the integrity of the DH. There is some suggestion that the hippocampus may be involved in generalization to discrete auditory stimuli following conditioning, but the available literature offers conflicting results regarding the nature of hippocampus involvement. The present experiments were designed to address a role for the DH in auditory generalization following delay fear conditioning. Rats were trained with two or 16 trials of delay fear conditioning and subsequently given a neurotoxic lesion of the DH or sham surgery. Upon recovery, they were tested for fear conditioned responding to the auditory stimulus they were trained with, as well as generalized responding to a novel auditory stimulus. Sham animals showed substantial generalization to the novel stimulus when trained with two or 16 trials. However, lesion animals showed much less generalization (better discriminative performance) to the novel stimulus following 16 conditioning trials while still showing substantial fear conditioned freezing to the trained stimulus. A second experiment showed that this effect was not the result of a non-associative response to the novel stimulus. We conclude that, with extended training, animals become capable of discriminating between trained and novel stimuli but another hippocampus-dependent process maintains generalized responding.

Dorsal hippocampus involvement in delay fear conditioning depends upon the strength of the tone-footshock association.

The hippocampus is important for the formation of spatial, contextual, and episodic memories. For instance, lesions of the dorsal hippocampus (DH) produce demonstrable deficits in contextual fear conditioning. By contrast, it is generally agreed that the DH is not important for conditioning to a discrete cue (such as a tone or light) that is paired with footshock in a temporally contiguous fashion (delay conditioning). There are, however, some reports of hippocampus involvement in delay conditioning. The present series of experiments was designed to assess the conditions under which the hippocampus-dependent component of delay fear conditioning performance may be revealed. Here, we manipulated the number of conditioning trials and the intensity of the footshock in order to vary the strength of conditioning. The results indicate that the DH contributes to freezing performance to a delay conditioned tone when the conditioning parameters are relatively weak (few trials or low footshock intensity), but not when strong parameters are used. The results are discussed in terms of two parallel memory systems: a direct tone-footshock association that is independent of the hippocampus and a hippocampus-dependent memory for the conditioning session.

Dorsal hippocampus involvement in trace fear conditioning with long, but not short, trace intervals in mice.

Placing a "trace" interval between a warning signal and an aversive shock makes consolidation of the memory for trace conditioning hippocampus dependent. To determine the trace at which memory consolidation requires the hippocampus, mice were trained with 0-s, 1-s, 3-s, or 20-s trace intervals and tested for freezing to context and tone. Posttraining dorsal hippocampus (DH) lesions decreased context conditioning regardless of trace interval. However, DH lesions attenuated only the 20-s trace tone freezing. Like eyeblink conditioning, the DH is necessary for trace fear conditioning only at long trace intervals, but the time scale for the effective interval in fear conditioning is about 40 times longer. Manipulations that alter trace fear conditioning with short trace intervals probably do not reflect altered DH function. Given this difference in time scale along with the use of posttraining DH lesions, hippocampus dependency of trace conditioning is not related to a bridging function or response timing.

Lesions of the dorsal hippocampus block trace fear conditioned potentiation of startle.

Several studies show that the hippocampus is critical for the memories mediating trace and contextual fear conditioning. This study investigates whether N-methyl-D-aspartate-induced lesions of the dorsal hippocampus made prior to training affect context fear conditioning and trace fear conditioning measured with the fear-potentiated startle. Pretraining excitotoxic lesions of the dorsal hippocampus blocked acquisition of trace fear conditioning to a tone stimulus but did not affect context fear conditioning. These data indicate that without a dorsal hippocampus rats are unable to acquire trace conditioning but can acquire contextual fear when fear is measured by potentiation of the startle response.