Abstract
Memory impairment is a hallmark cognitive deficit in Rett syndrome (RTT). Yet, long-term memory deficits in RTT animal models remain poorly understood, largely due to the technical challenges inherent in tracking neural activity over extended periods. Here, we used longitudinal two-photon calcium imaging to follow the same population of hippocampal CA1 neurons as RTT mice and their littermate controls formed cognitive maps of their environment during a spatial learning task. Neural representations in RTT mice were marked by excessive place cell (PC) activity, with individual PCs exhibiting pronounced instability across days. This disrupted single-cell stability propagated to the population level, resulting in unstable ensemble codes that poorly retained previously learned task information. Both excessive PC recruitment and instability could be attributed to a higher incidence of behavioral timescale synaptic plasticity (BTSP) in RTT mice. In wild-type littermates, place-cell consolidation across days is reflected by an increased likelihood of neuron-specific synaptic plasticity at the location of prior PC coding. This cellular mechanism of memory consolidation based on the location of BTSP was disrupted in RTT mice, where excessive and ectopic plasticity reduced PC stability, and degraded long-term stable representations. Backed by theoretical modeling, these results identify a plausible cellular and circuit-level mechanism underlying memory impairments in RTT mice and suggest principles that may be generalized to other neurological disorders involving memory deficits.