Mechanisms of Inherited Retinal Dystrophies Using Whole Genome Sequencing and in Vitro and in Vivo Models

IRDs are rare neurodegenerative and genetically heterogeneous conditions with a wide spectrum of presentations, even among affected members of the same family. These disorders exhibit a large range of phenotypes with significant overlap, that can be broadly divided into three main groups: those principally affecting the periphery such as retinitis pigmentosa (RP) and choroideremia; those primarily involving the macula, known as 'macular' or 'central' dystrophies; and those affecting both the centre and periphery as seen in cone-rod or rod-cone dystrophies. Collectively, IRDs have an incidence of 1:2000, impacting approx. 2 million people worldwide and patients are progressively visually impaired. Affected individuals can be followed-up by visual acuity measurements, visual field evaluations, electroretinography recordings (ERG), structural imaging with autofluorescence, spectral-domain optical coherence tomography (OCT), and OCT angiography. Although an accurate clinical diagnosis can be reached by these innovative and non-invasive tools, genetic testing is necessary to confirm a specific phenotype, and segregation analysis can address the inheritance pattern. Gene discovery approaches clarified that mutations of about 280 different genes involved in eyes development, photoreceptor survival, phototransduction mechanisms, retinoid cycle, retinal enzymatic function, or cell structure are responsible for these degenerative diseases (RetNet. Available at: https://sph.uth.edu/retnet/) and the inheritance pattern can be autosomal dominant, recessive, or X-linked.

To improve the success rate of genetic/genomic diagnosis, new sequencing technologies have been explored, starting from targeted sequencing focused on multigene panels to whole exome sequencing (WES) and sequencing of the entire genome (WGS). Because of the genetic heterogeneity of IRDs, the congruence of clinical and molecular diagnosis is a necessary goal to characterize exactly the phenotype and to increase the chance of therapeutically beneficial strategies.

A major challenge consists in identifying novel genes encoding for the diseases. This extreme genetic heterogeneity accounts for about 30% of the detection failure of molecular diagnosis. With the possibility of investigating WES or WGS, broader windows are opened for gene discovery.