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Пишет bioRxiv Subject Collection: Neuroscience (![[info]](http://lj.rossia.org/img/syndicated.gif){kind=small} syn_bx_neuro)@ 2025-08-01 19:45:00 |
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Next Generation AAV-F Capsid gene therapy rescues disease pathology in a model of Pyruvate Dehydrogenase Complex Deficiency
Pyruvate dehydrogenase complex deficiency (PDHD) is a severe mitochondrial disorder most frequently caused by pathogenic variants in PDHA1, leading to neurodevelopmental delay and early mortality, necessitating brain-targeted interventions. Using a brain-specific Pdha1 knockout mouse model, we compared intracerebroventricular delivery of AAV9 capsid and a recently described synthetic neurotropic AAV-F capsid, both expressing human PDHA1 coding sequence driven by a constitutive CAG promoter. Newborn mice received, titre matched AAV9 or AAV-F or AAV9 at ten-fold higher dose. Low-dose AAV-F and high-dose AAV9 significantly improved survival, and restored PDH enzyme activity, metabolite profiles, and brain histopathology to near wild-type levels. However, treated mice showed reduced locomotion by P100 and impaired motor function. Importantly, AAV-F achieved broad CNS transduction with minimal liver expression, outperforming AAV9 at lower dose. There results support the therapeutic potential of AAV-based gene therapy for PDHD and highlighting AAV-F as a promising capsid for efficient, CNS specific delivery.
Pyruvate dehydrogenase complex deficiency (PDHD) is a severe mitochondrial disorder most frequently caused by pathogenic variants in PDHA1, leading to neurodevelopmental delay and early mortality, necessitating brain-targeted interventions. Using a brain-specific Pdha1 knockout mouse model, we compared intracerebroventricular delivery of AAV9 capsid and a recently described synthetic neurotropic AAV-F capsid, both expressing human PDHA1 coding sequence driven by a constitutive CAG promoter. Newborn mice received, titre matched AAV9 or AAV-F or AAV9 at ten-fold higher dose. Low-dose AAV-F and high-dose AAV9 significantly improved survival, and restored PDH enzyme activity, metabolite profiles, and brain histopathology to near wild-type levels. However, treated mice showed reduced locomotion by P100 and impaired motor function. Importantly, AAV-F achieved broad CNS transduction with minimal liver expression, outperforming AAV9 at lower dose. There results support the therapeutic potential of AAV-based gene therapy for PDHD and highlighting AAV-F as a promising capsid for efficient, CNS specific delivery.
