Efficient Viral Transduction in Fetal and Adult Human Inner Ear Explants with AAV9-PHP.B Vectors.
Edward S A van BeelenWouter H van der ValkThijs O VerhagenJohn C M J de GrootMargot A MadisonWijs ShadmanfarErik F HensenJeroen C JansenPeter Paul G van BenthemJeffrey R HoltHeiko LocherPublished in: Biomolecules (2022)
Numerous studies have shown the recovery of auditory function in mouse models of genetic hearing loss following AAV gene therapy, yet translation to the clinic has not yet been demonstrated. One limitation has been the lack of human inner ear cell lines or tissues for validating viral gene therapies. Cultured human inner ear tissue could help confirm viral tropism and efficacy for driving exogenous gene expression in targeted cell types, establish promoter efficacy and perhaps selectivity for targeted cells, confirm the expression of therapeutic constructs and the subcellular localization of therapeutic proteins, and address the potential cellular toxicity of vectors or exogenous constructs. To begin to address these questions, we developed an explant culture method using native human inner ear tissue excised at either fetal or adult stages. Inner ear sensory epithelia were cultured for four days and exposed to vectors encoding enhanced green fluorescent protein (eGFP). We focused on the synthetic AAV9-PHP.B capsid, which has been demonstrated to be efficient for driving eGFP expression in the sensory hair cells of mouse and non-human primate inner ears. We report that AAV9-PHP.B also drives eGFP expression in fetal cochlear hair cells and in fetal and adult vestibular hair cells in explants of human inner ear sensory epithelia, which suggests that both the experimental paradigm and the viral capsid may be valuable for translation to clinical application.
Keyphrases
- endothelial cells
- gene therapy
- gene expression
- induced apoptosis
- induced pluripotent stem cells
- sars cov
- poor prognosis
- pluripotent stem cells
- cell cycle arrest
- hearing loss
- dna methylation
- stem cells
- oxidative stress
- mouse model
- signaling pathway
- cell proliferation
- drug delivery
- risk assessment
- single cell
- cell therapy
- young adults
- human health
- childhood cancer