Conditioned taste aversion (CTA) is a learning paradigm in which an animal avoids a taste (conditioned stimulus) previously associated with visceral toxic effects [or unconditioned stimulus (US)]. Although many studies have implicated glutamate-mediated neurotransmission in memory consolidation of different types of learning tasks, including CTA, the exact role of this neurotransmitter system in memory formation is not known. Thus, we set out to determine whether glutamate mediates signaling of the US in CTA. We present evidence obtained by in vivo microdialysis that the US (i.p. injection of lithium chloride) induced a dramatic increase in glutamate release in the amygdala and a modest but significant release in the insular cortex. Moreover, CTA can be elicited by intra-amygdalar microinjections of glutamate; consequently, when glutamate is administered just before the presentation of a weak US, a clear CTA is induced. In contrast, the injection of glutamate alone or glutamate 2 h after the suboptimal US did not have any effect on the acquisition of CTA. These results indicate that glutamate activation of the amygdala can partially substitute the US in CTA, thus providing a clear indication that the amygdala conveys visceral information for this kind of memory.A number of studies (1-5) have implicated glutamatemediated transmission in consolidation of memory for different types of training, such as inhibitory avoidance, Morris water maze, and conditioned taste aversion (CTA). CTA is a learning paradigm in which the novel taste of food or drink (conditioned stimulus, CS) is paired with visceral signals of poisoning (unconditioned stimulus, US). Consequently, the animals avoid consuming the food or drink previously associated with toxic effects. CTA has unique properties; it is established after a single trial, permits long delays between stimuli presentation, and lasts for very long periods of time, even weeks. This feature makes it possible to separate the acquisition process into phases-CS presentation and US presentation-which can be studied independently under different experimental treatments (6).CTA is established by the interaction of brainstem, limbic, and neocortical structures underlying different phases of the acquisition storage and retrieval of gustatory memory (7). Among the structures involved in the initial phases of taste memory formation are the gustatory neocortex and amygdala (8). Thus, damage to either the gustatory insular cortex (IC) or amygdala in adult rats leads to impaired acquisition of CTA (6,7,[9][10][11][12][13][14][15][16][17]. However, the functional roles of IC and amygdala seem to be different during the phases of taste memory formation. Functional blockade of IC before taste presentation, but not between taste presentation and lithium chloride (LiCl) injection, blocks CTA (16, 18), suggesting that the gustatory cortex is involved in taste processing and͞or memory but is not necessary for processing the visceral signals of poisoning. Conversely, amygdala functional inactivation...
In this paper, we will provide evidence of the putative molecular signals and biochemical events that mediate the formation of long-lasting gustatory memory trace. When an animal drinks a novel taste (the conditioned stimulus; CS) and it is later associated with malaise (unconditioned stimulus; US), the animal will reject it in the next presentation, developing a long-lasting taste aversion, i.e., the taste cue becomes an aversive signal, and this is referred to as conditioning taste aversion. Different evidence indicates that the novel stimulus (taste) induces a rapid and strong cortical acetylcholine activity that decreases when the stimulus becomes familiar after several presentations. Cholinergic activation via muscarinic receptors initiates a series of intracellular events leading to plastic changes that could be related to short- and/or long-term memory gustatory trace. Such plastic changes facilitate the incoming US signals carried out by, in part, the glutamate release induced by the US. Altogether, these events could produce the cellular changes related to the switch from safe to aversive taste memory trace. A proposed working model to explain the biochemical sequence of signals during taste memory formation will be discussed.
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