Abstracts

This study aims to elucidate the role of heme oxygenase-1 (HO-1)–mediated ferroptosis in epileptogenesis, and to uncover cell type– and stage–specific mechanisms linking iron dysregulation to seizure development.

A cobalt-induced neocortical epilepsy rat model was established. mRNA-seq and single-nucleus RNA sequencing (snRNA-seq) were conducted at 3, 9, and 15 days post-surgery to characterize the spatiotemporal expression of Hmox1 across glial cell populations. HO-1 protein expression, Fe²⁺ deposition, and lipid peroxidation (4-HNE) were assessed using immunohistochemistry and biochemical assays. The therapeutic impact of HO-1 inhibition was evaluated via intracerebral osmotic pump infusion.

Hmox1 was transiently expressed in both astrocytes and microglia during early epileptogenesis (day 3), but expression became predominantly microglial during the chronic phase (days 9 and 15). Persistent HO-1 upregulation in microglia was associated with pathological iron accumulation, elevated 4-HNE levels, and downregulation of neuronal glutamate transporters. HO-1 inhibition attenuated Fe²⁺ overload and significantly reduced seizure burden.

These findings identify microglial HO-1–driven ferroptosis as a time-dependent pathogenic mechanism in epileptogenesis. Temporal targeting of glial HO-1 offers a promising strategy to interrupt the iron–ferroptosis–seizure cascade and preserve neuronal homeostasis.