Disconnection of the perirhinal and insular cortices severely disrupts taste neophobia.

It is well known that the perirhinal (Prh) and insular (IC) cortices are reciprocally connected, mainly through ipsilateral projections. Although some studies have demonstrated that excitotoxic lesions to these regions, each separately, disrupt taste neophobia, it is not yet known whether the two regions have functional interactions with one another. To find out if they form a functional unit, we examined the effects of crossed excitotoxic lesions to the Prh and the contralateral IC (contralateral group). This group's performance was compared to that of rats with ipsilateral Prh and IC lesions (ipsilateral group) and to that of control-operated rats. All the animals received a 0.3% saccharin solution for fifteen minutes on five consecutive days. Rats with contralateral Prh-IC lesions drank significantly higher amounts of saccharin than the other groups during the first encounter with the novel taste, indicating a disruption in neophobia. However, the lesions did not disrupt attenuation of neophobia, with the contralateral group reaching asymptote in trial 2 and the rest of the groups after 3-5 days of exposure to the saccharin. These findings suggest that both Prh and IC play a necessary role in taste neophobia. Additionally, the two cortices function interdependently and their interaction is critical for normal expression of taste neophobia.

Activation of cortical M1 muscarinic receptors and related intracellular signaling is necessary for reactivation-induced object memory updating.

Reactivated long-term memories can become labile and sensitive to modification. Memories in this destabilized state can be weakened or strengthened, but there is limited research characterizing the mechanisms underlying retrieval-induced qualitative updates (i.e., information integration). We have previously implicated cholinergic transmission in object memory destabilization. Here we present a novel rodent paradigm developed to assess the role of this cholinergic mechanism in qualitative object memory updating. The post-reactivation object memory modification (PROMM) task exposes rats to contextual information following object memory reactivation. Subsequent object exploratory performance suggests that the contextual information is integrated with the original memory in a reactivation- and time-dependent manner. This effect is blocked by interference with M1 muscarinic receptors and several downstream signals in perirhinal cortex. These findings therefore demonstrate a hitherto unacknowledged cognitive function for acetylcholine with important implications for understanding the dynamic nature of long-term memory storage in the normal and aging brain.

Perirhinal cortex lesions that impair object recognition memory spare landmark discriminations.

Rats with lesions in the perirhinal cortex and their control group learnt to discriminate between mirror-imaged visual landmarks to find a submerged platform in a watermaze. Rats initially learnt this discrimination passively, in that they were repeatedly placed on the platform in one corner of a square watermaze with walls of different appearance, prior to swimming to that same location for the first time in a subsequent probe trial. Perirhinal cortex lesions spared this passively learnt ability, despite the common visual elements shared by the guiding landmarks. These results challenge models of perirhinal function that emphasise its role in solving discriminations between stimuli with ambiguous or overlapping features, while underlining how this cortical region is often not required for spatial processes that involve the hippocampus.