Lamotrigine rescues neuronal alterations and prevents seizure-induced memory decline in an Alzheimer's disease mouse model.

Epilepsy is a comorbidity associated with Alzheimer's disease (AD), often starting many years earlier than memory decline. Investigating this association in the early pre-symptomatic stages of AD can unveil new mechanisms of the pathology as well as guide the use of antiepileptic drugs to prevent or delay hyperexcitability-related pathological effects of AD. We investigated the impact of repeated seizures on hippocampal memory and amyloid-ß (Aß) load in pre-symptomatic Tg2576 mice, a transgenic model of AD. Seizure induction caused memory deficits and an increase in oligomeric Aß42 and fibrillary species selectively in pre-symptomatic transgenic mice, and not in their wildtype littermates. Electrophysiological patch-clamp recordings in ex vivo CA1 pyramidal neurons and immunoblots were carried out to investigate the neuronal alterations associated with the behavioral outcomes of Tg2576 mice. CA1 pyramidal neurons exhibited increased intrinsic excitability and lower hyperpolarization-activated Ih current. CA1 also displayed lower expression of the hyperpolarization-activated cyclic nucleotide-gated HCN1 subunit, a protein already identified as downregulated in the AD human proteome. The antiepileptic drug lamotrigine restored electrophysiological alterations and prevented both memory deficits and the increase in extracellular Aß induced by seizures. Thus our study provides evidence of pre-symptomatic hippocampal neuronal alterations leading to hyperexcitability and associated with both higher susceptibility to seizures and to AD-specific seizure-induced memory impairment. Our findings also provide a basis for the use of the antiepileptic drug lamotrigine as a way to counteract acceleration of AD induced by seizures in the early phases of the pathology.

Place cells in the claustrum remap under NMDA receptor control.

Place cells are cells that exhibit location-dependent responses; they have mostly been studied in the hippocampus. Place cells have also been reported in the rat claustrum, an underexplored paracortical region with extensive corto-cortical connectivity. It has been hypothesised that claustral neuronal responses are anchored to cortical visual inputs. We show rat claustral place cells remap when visual inputs are eliminated from the environment, and that this remapping is NMDA-receptor-dependent. Eliminating visual input decreases claustral delta-band oscillatory activity, increases theta-band oscillatory activity, and increases simultaneously recorded visual cortical activity. We conclude that, like the hippocampus, claustral place field remapping might be mediated by NMDA receptor activity, and is modulated by visual cortical inputs.

Synaptic Correlates of Anterograde Amnesia and Intact Retrograde Memory in a Mouse Model of Alzheimer's Disease.

BACKGROUND: Clinical evidence indicates that patients affected by Alzheimer's Disease (AD) fail to form new memories although their memories for old events are intact. This amnesic pattern depends on the selective vulnerability to AD-neurodegeneration of the hippocampus, the brain region that sustains the formation of new memories, while cortical regions that store remote memories are spared. OBJECTIVE: To identify the cellular mechanisms underlying impaired recent memories and intact remote memories in a mouse model of AD. METHODS: Glutamatergic synaptic currents were recorded by patch-clamp in acute hippocampal and anterior Cingulate Cortical (aCC) slices of AD-like Tg2576 mice and Wild-type (Wt) littermates subjected to the Contextual Fear Conditioning (CFC) task or in naïve conditions. RESULTS: We identified a deficit in the formation of recent memories, but not in the recall of remote ones, in Tg2576 mice. With electrophysiological recordings, we detected CFC-induced modifications of the AMPA/NMDA ratio in CA1 pyramidal cells of Wt, but not Tg2576, mice one day after training. CFC-induced changes in the AMPA/NMDA ratio were also detected in the aCC of both Wt and Tg2576 mice 8 days after training. CONCLUSION: Our data suggest that in the early AD stages synaptic plasticity of CA1 synapses, crucial to form new memories, is lost, while plasticity of aCC synapses is intact and contributes to the persistence of long-term memories.