Abstract
Neuronal circuit disturbances that lead to hyperexcitability in the cortico-hippocampal network are one of the landmarks of temporal lobe epilepsy. The dentate gyrus (DG) network plays an important role in regulating the excitability of the entire hippocampus by filtering and integrating information received via the perforant path. Here, we investigated possible epileptogenic abnormalities in the function of the DG neuronal network in the Synapsin II (Syn II) knockout mouse (Syn II−/−), a genetic mouse model of epilepsy. Syn II is a presynaptic protein whose deletion in mice reproducibly leads to generalized seizures starting at the age of 2 months. We made use of a high-resolution microelectrode array (4096 electrodes) and patch-clamp recordings, and found that in acute hippocampal slices of young pre-symptomatic (3–6 week-old) Syn II−/− mice excitatory synaptic output of the mossy fibers is reduced. Moreover, we showed that the main excitatory neurons present in the polymorphic layer of the DG, hilar mossy cells, display a reduced excitability. We also provide evidence of a predominantly inhibitory regulatory output from mossy cells to granule cells, through feed-forward inhibition, and show that the excitatory-inhibitory ratio is increased in both pre-symptomatic and symptomatic Syn II−/− mice. These results support the key role of the hilar mossy neurons in maintaining the normal excitability of the hippocampal network and show that the late epileptic phenotype of the Syn II−/− mice is preceded by neuronal circuitry dysfunctions. Our data provide new insights into the mechanisms of epileptogenesis in the Syn II−/− mice and open the possibility for early diagnosis and therapeutic interventions.
Highlights
Epilepsy is a debilitating nervous system disorder mainly characterized by abnormal synchronization of neuronal activity
Field postsynaptic potentials, evoked by the stimulation of the perforant path with an extracellular electrode, were detected in the granule layer of the dentate gyrus (DG) and they further propagated to the hilus (Figure 1A)
The recorded signal on several neighboring electrodes on the APS-MICROELECTRODE ARRAY (MEA) correlated with the fine anatomy of the DG and its polarity corresponded to current sinks in the dendritic-granule layer and to current sources in the hilus (Figure 1D)
Summary
Epilepsy is a debilitating nervous system disorder mainly characterized by abnormal synchronization of neuronal activity. Intractable medial temporal lobe epilepsies (MTLE) are often successfully treated by excision of the hippocampus and nearby regions of the brain (Schwartzkroin, 1994) This brain area appears to be highly seizure-prone and provides a convenient model to study epileptiform events in vitro. One of the family of genes mutated in several epileptic patients, synapsins (Syns), are a family of abundant neuronal phosphoproteins playing important roles in synaptogenesis, synaptic transmission and plasticity In mammals, they are encoded by three related genes, SYN1-3 (Kao et al, 1999), translated into ten protein isoforms through alternative splicing (Syn Ia/Ib, Syn IIa/IIb, and IIIa/IIIf) (Cesca et al, 2010; Fassio et al, 2011). Given the large body of experimental evidence pointing toward the importance of the DG in epileptogenesis, here we have searched for pathological impairments of its circuitry in pre-symptomatic Syn II−/− mouse brain slices, using a combination of electrophysiological and morphological techniques
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