Abstract
Rett syndrome is a severe neurodevelopmental disorder that occurs primarily in females and is caused by mutations in the methyl-CpG-binding protein 2 (MECP2) gene located on the X chromosome. Though MECP2 acts as a representative transcriptional regulator and affects gene expression both directly and indirectly, a complete understanding of this disease and the treatment mechanism has not been established yet. MECP2 plays a particularly important role in synaptic development, neuronal maturation, and epigenetic regulation in the brain. In this study, we summarize the molecular structure of MECP2, mutation-specific pathogenesis, and the role of MECP2 in regulating chromatin remodeling, RNA splicing, and miRNA processing to provide a comprehensive understanding of Rett syndrome. Additionally, we describe abnormal phenotypes manifested in various brain regions and other tissues owing to MECP2 dysfunction. Finally, we discuss current and future therapeutic approaches, including AAV-based gene therapy, RNA editing, X chromosome reactivation, and pharmacological interventions. Understanding the diverse functions and pathological mechanisms of MECP2 provides an important foundation for developing targeted therapies for Rett syndrome.