Gene-based replacement therapy for hearing loss

Details

Hearing loss is the most common sensory dysfunction in humans, and it is associated with social isolation and depression. Approximately 1 billion people in the world will be affected by hearing loss by 2050 (World Health Organization). Although the aetiology underlying hearing loss can be quite diverse, genetic mutations cause about 70-75% of congenital deafness (https://hereditaryhearingloss.org/). Currently, there are no treatments for hearing loss and, although beneficial, hearing aids and cochlear implants cannot completely restore hearing. However, recent developments in gene replacement technologies have highlighted promising therapeutic interventions.

Sound is detected by sensory cells, named hair cells, that are located in the cochlea. These cells convert sound waves into an electrical current that is then sent to the brain via afferent fibres, allowing us to perceive sound such as speech and music. However, most of the cells present in the cochlea are glial-like supporting cells. These cells are interconnected by an intricate network of channels that are required for essential physiological processes such as the maintenance of cochlear fluid homeostasis and the supply of nutrients from the blood to the hair cells. These channels, known as gap-junctions, are made from proteins called connexins. Connexins are vital for hearing since nearly half of all cases of hearing impairment present at birth in humans are due to mutations in the genes encoding for connexin 26 (Cx26) and connexin 30 (Cx30) (Mammano, 2019).

The objective of this project is to replace a defective connexin gene with a functional one in a mouse model of hearing loss (Johnson et al., 2017) using AAV-based gene therapy and then investigate the level of hearing function recovery. This proposal will require the student to perform state-of-the-art techniques that are well established in the lab (e.g., Jeng et al., 2022), including in vivo AAV-gene delivery, in vivo animal physiology and several ex vivo approaches such as electrophysiology, immunolabelling combined with confocal imaging and electron microscopy. These experimental approaches, combined with large data analysis, will require the student to think beyond their immediate expertise and will allow them to acquire unique skills that can be transferred to other research fields.

The PhD student will join a highly dynamic Hearing Research group with outstanding expertise in hearing function/dysfunction, and with an excellent track record of training, mentorship, and supervision. The PI is also a leading member of the Institute of Neuroscience, which provides an environment that exposes members, including students, to multidisciplinary interactions across multiple faculties.

Prof Walter Marcotti

@HearingShef

https://www.sheffield.ac.uk/hearing

https://www.sheffield.ac.uk/biosciences/people/academic-staff/walter-marcotti

Science Graduate School

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