Abstract
Rett syndrome (RTT) is a severe X-linked neurodevelopmental disorder affecting approximately 1 in 10,000-15,000 females, most often caused by loss-of-function mutations in MECP2. Until the recent approval of trofinetide, management relied exclusively on symptomatic treatment and multidisciplinary supportive care. The therapeutic landscape is now undergoing a rapid shift, driven by multiple gene therapy approaches designed to restore functional MeCP2 expression and achieve true disease modification. As these therapies progress toward potential regulatory approval, neurologists will play central roles in identifying eligible patients, counseling families, supporting clinical trial enrollment, delivering treatments, monitoring long-term outcomes, and advocating for equitable access. This review provides neurologists with the essential framework needed to understand and navigate this evolving field. We examine in detail the two most advanced gene replacement therapies currently in clinical trials. TSHA-102 uses an intrathecally delivered miniMECP2 transgene regulated by a microRNA-based autoregulatory system, whereas NGN-401 delivers full-length MECP2 via intracerebroventricular administration using a synthetic expression-feedback circuit. Both approaches have shown encouraging early efficacy, with treated children achieving developmental gains that exceed natural history expectations. However, they differ substantially in molecular design, regulatory control, delivery method, and safety considerations. We also highlight challenges unique to RTT gene therapy, including the narrow therapeutic window between insufficient expression and MeCP2 overexpression toxicity, the impact of X-chromosome inactivation mosaicism, and lessons learned from a fatal hyperinflammatory adverse event. Beyond AAV-mediated gene replacement, we review next-generation strategies in preclinical development-CRISPR-Cas9 genome editing for permanent mutation correction, ADAR-based RNA editing, translation readthrough for nonsense variants, and X-chromosome reactivation to restore endogenous MECP2 expression. Finally, we address key translational considerations such as optimal timing of intervention, dosing constraints, outcome measurement in severely impaired populations, long-term safety surveillance, and barriers to broad and equitable access. The RTT gene therapy experience serves as a model for precision medicine in other monogenic neurodevelopmental disorders, illustrating both the transformative promise and the substantial complexities of translating genetic science into meaningful clinical benefit.
Percy AK, Ananth A, Neul JL. Rett Syndrome: The Emerging Landscape of Treatment Strategies. CNS Drugs. 2024 Nov;38(11):851-867. doi: 10.1007/s40263-024-01106-y. Epub 2024 Sep 9. PMID: 39251501; PMCID: PMC11486803.
Abstract
Rett syndrome (RTT) has enjoyed remarkable progress in achieving specific therapies. RTT, a unique neurodevelopmental disorder first described in 1966, progressed slowly until the landmark paper of Hagberg and colleagues in 1983. Thereafter, rapid advances were achieved including the development of specific diagnostic criteria and the active search for a genetic etiology, resulting 16 years later in identification of variants in the methyl-CpG-binding protein (MECP2) gene located at Xq28. Shortly thereafter, the NIH Office of Rare Diseases funded the RTT Natural History Study (NHS) in 2003, initiating the acquisition of natural history data on clinical features from a large population of individuals with RTT. This information was essential for advancement of clinical trials to provide specific therapies for this disorder. In the process, the International Rett Syndrome Association (IRSA) was formed (now the International Rett Syndrome Foundation-IRSF), which participated directly in encouraging and expanding enrollment in the NHS and, subsequently, in developing the SCOUT program to facilitate testing of potential therapeutic agents in a mouse model of RTT. The overall objective was to review clinical characteristics developed from the NHS and to discuss the status of specific therapies for this progressive neurodevelopmental disorder. The NHS study provided critical information on RTT: growth, anthropometrics, longevity, key comorbidities including epilepsy, breath abnormalities, gastroesophageal dysfunction, scoliosis and other orthopedic issues, puberty, behavior and anxiety, and progressive motor deterioration including the appearance of parkinsonian features. Phenotype-genotype correlations were noted including the role of X chromosome inactivation. Development of clinical severity and quality of life measures also proved critical for subsequent clinical trials. Further, development of biochemical and neurophysiologic biomarkers offered further endpoints for clinical trials. Initial clinical trials prior to the NHS were ineffective, but advances resulting from the NHS and other studies worldwide promoted significant interest from pharmaceutical firms resulting in several clinical trials. While some of these have been unrewarding such as sarizotan, others have been quite promising including the approval of trofinetide by the FDA in 2023 as the first agent available for specific treatment of RTT. Blarcamesine has been trialed in phase 3 trials, 14 agents have been studied in phase 2 trials, and 7 agents are being evaluated in preclinical/translational studies. A landmark study in 2007 by Guy et al. demonstrated that activation of a normal MECP2 gene in a null mouse model resulted in significant improvement. Gene replacement therapy has advanced through translational studies to two current phase 1/2 clinical trials (Taysha102 and Neurogene-401). Additional genetic therapies are also under study including gene editing, RNA editing, and X-chromosome reactivation. Taken together, progress in understanding and treating RTT over the past 40 years has been remarkable. This suggests that further advances can be expected.
Rett syndrome (RTT) has enjoyed remarkable progress in achieving specific therapies. RTT, a unique neurodevelopmental disorder first described in 1966, progressed slowly until the landmark paper of Hagberg and colleagues in 1983. Thereafter, rapid advances were achieved including the development of specific diagnostic criteria and the active search for a genetic etiology, resulting 16 years later in identification of variants in the methyl-CpG-binding protein (MECP2) gene located at Xq28. Shortly thereafter, the NIH Office of Rare Diseases funded the RTT Natural History Study (NHS) in 2003, initiating the acquisition of natural history data on clinical features from a large population of individuals with RTT. This information was essential for advancement of clinical trials to provide specific therapies for this disorder. In the process, the International Rett Syndrome Association (IRSA) was formed (now the International Rett Syndrome Foundation-IRSF), which participated directly in encouraging and expanding enrollment in the NHS and, subsequently, in developing the SCOUT program to facilitate testing of potential therapeutic agents in a mouse model of RTT. The overall objective was to review clinical characteristics developed from the NHS and to discuss the status of specific therapies for this progressive neurodevelopmental disorder. The NHS study provided critical information on RTT: growth, anthropometrics, longevity, key comorbidities including epilepsy, breath abnormalities, gastroesophageal dysfunction, scoliosis and other orthopedic issues, puberty, behavior and anxiety, and progressive motor deterioration including the appearance of parkinsonian features. Phenotype-genotype correlations were noted including the role of X chromosome inactivation. Development of clinical severity and quality of life measures also proved critical for subsequent clinical trials. Further, development of biochemical and neurophysiologic biomarkers offered further endpoints for clinical trials. Initial clinical trials prior to the NHS were ineffective, but advances resulting from the NHS and other studies worldwide promoted significant interest from pharmaceutical firms resulting in several clinical trials. While some of these have been unrewarding such as sarizotan, others have been quite promising including the approval of trofinetide by the FDA in 2023 as the first agent available for specific treatment of RTT. Blarcamesine has been trialed in phase 3 trials, 14 agents have been studied in phase 2 trials, and 7 agents are being evaluated in preclinical/translational studies. A landmark study in 2007 by Guy et al. demonstrated that activation of a normal MECP2 gene in a null mouse model resulted in significant improvement. Gene replacement therapy has advanced through translational studies to two current phase 1/2 clinical trials (Taysha102 and Neurogene-401). Additional genetic therapies are also under study including gene editing, RNA editing, and X-chromosome reactivation. Taken together, progress in understanding and treating RTT over the past 40 years has been remarkable. This suggests that further advances can be expected.
