Transcriptomic Profiling Reveals Sex-Specific Epigenetic Dynamics Involving kdm6b and H3K27 Methylation in Cerebral Ischemia-Induced Neurogenesis and Recovery.

Cerebral ischemic stroke ranks among the leading causes of death and disability worldwide. A significant challenge, beyond the lack of effective therapies, is the frequent oversight of sex as a vital factor in stroke research. This study focuses on elucidating the sex-specific epigenetic mechanisms that contribute to neural damage and recovery in cerebral ischemia. In our previously reported study, we demonstrated that following ischemia-induced cerebral artery occlusion (ICAO), female striatal tissue exhibited an early reinstatement of H3K9me2 marks on the promoters of inflammatory genes compared to male striatal tissue. This restoration led to a reduction in the expression of inflammatory cytokines, ultimately contributing to accelerated recovery in females. Building upon these findings, the current study aimed to investigate the unidentified molecular pathways responsible for the accelerated recovery observed in females. To explore this, we performed illumina-RNA sequencing on striatal tissues 24-h post-ICAO. Interestingly, our analysis revealed differential regulation of H3K27me2 marks on the promoters of various neurogenic genes at an early stage, which facilitated early neurogenesis in the female striatum. This investigation identifies an epigenetic modulator, kdm6b/jmjd3, targeting H3K27, and delineates its sex-specific role in neural stem cell proliferation. The findings contribute to a comprehensive model linking gender-specific epigenetic regulation, neurogenesis, and post-ICAO recovery. In conclusion, the identified epigenetic modulators and their roles in neurogenesis offer potential targets for refined therapeutic interventions, emphasizing the importance of personalized and sex-specific considerations in stroke studies.