Authors
Ahmad Al Saneh, Lionel Gissot, Christopher A Ahern
Published in
Nucleic acids research. Volume 54. Issue 13. Jul 03, 2026.
Abstract
Protein-truncating variants caused by stop codons are the most prevalent class of rare variant mutations in neurodevelopmental diseases, with UGA codons being most common. Suppressor transfer RNA (sup-tRNA) has therapeutic potential for premature termination codon (PTC) rescue but has thus far underperformed by traditional AAV delivery platforms, and progress has been hampered by the lack of methods to non-invasively assess in vivo activity in mammalian brain. To fill this material gap, we utilize transcranial in vivo bioluminescence imaging data from a luciferase-UGA mouse model to optimize viral payloads with sup-tRNA genes. These data demonstrate that U6 promoter-driven and single-stranded AAV2/9 constructs show variable and dose-dependent activity, whereas self-complementary AAV2/9 with the tRNA in a minimal 100-bp genomic context provides broad and efficacious PTC rescue. Further, payload tRNA multiplexing and use of tRNA introns enable efficacy of low viral titers and sustained rescue. tRNA sequencing of scAAV-delivered ArgUCA sup-tRNA in brain demonstrates no effects on endogenous tRNA levels, their acylation, or processing, and these features are also maintained in the delivered ArgUCA sup-tRNA. Collectively, this work defines a scalable strategy for precision UGA PTC stop codon suppression, supporting development of durable genetic rescue therapies for neurodevelopmental disorders in the mammalian brain.
PMID:
42460447
Bibliographic data and abstract were imported from PubMed on 16 Jul 2026.
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