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Interdisciplinaria

versão On-line ISSN 1668-7027

Resumo

DANERI, María Florencia  e  MUZIO, Rubén Néstor. Evolution of basic learning phenomena in spatial memory tasks: Blocking, overshadowing and latent inhibition in amphibians. Interdisciplinaria [online]. 2015, vol.32, n.2, pp.275-288. ISSN 1668-7027.

This article describes blocking, overshadowing and latent inhibition phenomena from a comparative perspective, emphasizing their presence in spatial learning tasks. These learning phenomena, previously observed in other vertebrates and invertebrates classes, have been recently reported for the first time in amphibians, a vertebrate group with a phylogenetically ancient brain. We use the terrestrial toad Rhinella arenarum as animal model to analyze the three mentioned associative phenomena in a spatial learning situation: (1) blocking between visual cues associated to a goal, (2) overshadowing of a distant visual cue by the presence of a nearby cue, and (3) latent inhibition generated by the pre-exposure to a visual cue. All trainings were conducted in a white circular arena, using water as reward. Inside the arena, four green acrylic container were distributed in a cross shape against the side walls (only one with access to reward). On the inner walls of the circular arena they were placed several visual cues for guiding animals. In all studies described in this article toads were partially dehydrated to motivate them to search for water. In the blocking situation, experimental animals had the rewarded container signaled by a visual cue on the wall above the container. In the second phase of training other visual cue was added. The results revealed that in these animals the prior training with only one of the visual cues blocked the association of the reward with the other cue, when both cues were then presented simultaneously to indicate the position of reward. In the overshadowing situation, experimental animals had from the beginning the rewarded container signaled by two visual cues on the wall, one to 10 cm right (named near cue), and the other placed approximately 70 cm to the left (between the adjacent pool and the opposite, named far cue). The results indicated that the location of a visual cue located away from reward was overshadowed by the presence of a nearby cue. Finally, in the situation of latent inhibition, animals of pre-exposed group had five previous training sessions, where a visual cue was presented without reward. Then, when in the subsequent training this visual cue signaled the reward, animals pre-exposed needed more sessions to reach the asymptote of learning compared to other non-pre-exposed animals. Therefore, the pre-exposure to the visual cue (i.e., unreinforced exposure to the stimulus) significantly retarded the acquisition, delaying the association of this cue with the reward. Taking into account that these phenomena have been observed previously in birds and mammals, this first record in amphibians (using a spatial learning paradigm with near and far visual cues) suggests that biological mechanisms of these learning phenomena have emerged very early in the course of the evolution of fully terrestrial vertebrates and that they have been strongly preserved. With regard to the underlying neural substrates, the relationship of the hippocampal formation with the processes of learning and spatial memory is a constant in all vertebrate species studied. Analyzing the particular case of amphibians, compared with other groups of tetrapods, their telencephalon has a simple organization (in the evolutionary sense non-derived). In this aspect, the medial pallium, region in the dorso-medial quadrant of the hemisphere, is considered homologous to the mammalian hippocampal formation (based on their topographic position, its interconnections with other telencephalic areas and neurohistochemical data). Heretofore, the dependence of spatial learning with the functioning of the medial cortex was thought to be a primitive character of amniotes. However, this feature can now be extended to the group of amphibians, as recently has been observed that the lesion of the medial pallium impairs spatial learning. Thus, the evidence collected until this moment in amphibians suggests that this relationship may have emerged earlier than previously thought. On the whole, the comparative analysis of these findings will contribute to a better understanding of the biological mechanisms underlying spatial learning, thereby looking for common functional patterns with other vertebrate classes, potentially present in a common ancestor.

Palavras-chave : Blocking; Overshadowing; Latent inhibition; Spatial learning; Amphibians.

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