Scientific Reports (Nov 2021)

Proteins related to ictogenesis and seizure clustering in chronic epilepsy

  • Woo-Jin Lee,
  • Jangsup Moon,
  • Jung-Ah Lim,
  • Daejong Jeon,
  • Jung-Suk Yoo,
  • Dong-Kyu Park,
  • Dohyun Han,
  • Soon-Tae Lee,
  • Keun-Hwa Jung,
  • Kyung-Il Park,
  • Sang Kun Lee,
  • Kon Chu

DOI
https://doi.org/10.1038/s41598-021-00956-6
Journal volume & issue
Vol. 11, no. 1
pp. 1 – 13

Abstract

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Abstract Seizure clustering is a common phenomenon in epilepsy. Protein expression profiles during a seizure cluster might reflect the pathomechanism underlying ictogenesis. We performed proteomic analyses to identify proteins with a specific temporal expression pattern in cluster phases and to demonstrate their potential pathomechanistic role. Pilocarpine epilepsy model mice with confirmed cluster pattern of spontaneous recurrent seizures by long-term video-electroencpehalography were sacrificed at the onset, peak, or end of a seizure cluster or in the seizure-free period. Proteomic analysis was performed in the hippocampus and the cortex. Differentially expressed proteins (DEPs) were identified and classified according to their temporal expression pattern. Among the five hippocampal (HC)-DEP classes, HC-class 1 (66 DEPs) represented disrupted cell homeostasis due to clustered seizures, HC-class 2 (63 DEPs) cluster-onset downregulated processes, HC-class 3 (42 DEPs) cluster-onset upregulated processes, and HC-class 4 (103 DEPs) consequences of clustered seizures. Especially, DEPs in HC-class 3 were hippocampus-specific and involved in axonogenesis, synaptic vesicle assembly, and neuronal projection, indicating their pathomechanistic roles in ictogenesis. Key proteins in HC-class 3 were highly interconnected and abundantly involved in those biological processes. This study described the seizure cluster-associated spatiotemporal regulation of protein expression. HC-class 3 provides insights regarding ictogenesis-related processes.