The calcium-binding protein calbindin-D28k is critical for hippocampal function and cognition1-3, but its expression is markedly decreased in various neurological disorders associated with epileptiform activity and seizures4-7. In Alzheimer's disease (AD) and epilepsy, both of which are accompanied by recurrent seizures8, the severity of cognitive deficits reflects the degree of calbindin reduction in the hippocampal dentate gyrus (DG)4,9,10. However, despite the importance of calbindin in both neuronal physiology and pathology, the regulatory mechanisms that control its expression in the hippocampus are poorly understood. Here we report an epigenetic mechanism by which seizures chronically suppress hippocampal calbindin expression and impair cognition. We demonstrate that ΔFosB, a highly stable transcription factor, is induced in the hippocampus of mouse models of AD and seizures, where it binds and triggers histone deacetylation at the calbindin gene (Calb1) promoter, and downregulates Calb1 transcription. Notably, increasing DG calbindin levels, either by direct virus-mediated expression or inhibition of ΔFosB signaling, improves spatial memory in a mouse model of AD. Moreover, levels of ΔFosB and calbindin expression are inversely related in DG of patients with temporal lobe epilepsy (TLE) or AD, and correlate with performance on the Mini-Mental State Examination (MMSE). We propose that chronic suppression of calbindin by ΔFosB is one mechanism by which intermittent seizures drive persistent cognitive deficits in conditions accompanied by recurrent seizures.
Summary Alzheimer's disease (AD) is characterized by cognitive decline and 5–10 fold increased seizure incidence. How seizures contribute to cognitive decline in AD or other disorders is unclear. We show spontaneous seizures increase expression of ΔFosB, a highly stable Fos-family transcription factor, in the hippocampus of an AD mouse model. ΔFosB suppressed expression of the immediate early gene c-Fos, which is critical for plasticity and cognition, by binding its promoter and triggering histone deacetylation. Acute HDAC inhibition or inhibition of ΔFosB activity restored c-Fos induction and improved cognition in AD mice. Administration of seizure-inducing agents to nontransgenic mice also resulted in ΔFosB-mediated suppression of c-Fos, suggesting this mechanism is not confined to AD mice. These results explain observations that c-Fos expression increases after acute neuronal activity but decreases with chronic activity. Moreover, these results indicate a general mechanism by which seizures contribute to persistent cognitive deficits even during seizure-free periods.
SUMMARY Adult hippocampal neurogenesis has been reported to be decreased, increased, or not changed in Alzheimer’s disease (AD) patients and related transgenic mouse models. These disparate findings may relate to differences in disease stage, or the presence of seizures, which are associated with AD and can stimulate neurogenesis. In this study, we investigate a transgenic mouse model of AD that exhibits seizures similarly to AD patients and find that neurogenesis is increased in early stages of disease, as spontaneous seizures became evident, but is decreased below control levels as seizures recur. Treatment with the antiseizure drug levetiracetam restores neurogenesis and improves performance in a neurogenesis-associated spatial discrimination task. Our results suggest that seizures stimulate, and later accelerate the depletion of, the hippocampal neural stem cell pool. These results have implications for AD as well as any disorder accompanied by recurrent seizures, such as epilepsy.
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