[Gene Replacement Therapy for Inherited Retinal Dystrophies]. / Genersatztherapie bei hereditären Netzhauterkrankungen.

Characteristics of inherited retinal dystrophies include deficiencies in light perception and nervous conduction within the retina, leading to reduced vision or even blindness. In this context, the loss of function of photoreceptor-specific genes causes a variety of clinically and aetiologically distinct syndromes - each of them belonging to the group of rare diseases. With a prevalence of 1 in 2500, however, inherited retinal diseases are clinically significant and important - especially since these diseases lead to restrictions of a patient's fitness for work and overall quality of life. More than 250 genetic mutations causing the various types of inherited retinal dystrophies have been identified by now (https://sph.uth.tmc.edu/Retnet). In recent years, preclinical research on suitable animal models has yielded important progress in the understanding of the mutations underlying the pathological and molecular biological processes of these diseases. These findings have led to the development of novel and innovative therapeutic strategies for the treatment of inherited retinal dysfunctions, which are still incurable. Meanwhile, many of the successful preclinical studies have led to translational research projects aiming to find treatment options for human patients. However, some preliminary results of these human translational studies indicate the need to optimise and refine the underlying therapeutic concepts.

[Gene replacement therapy in achromatopsia type 2]. / Genersatztherapie bei genetisch bedingter Zapfenblindheit.

Achromatopsia is an autosomal recessive inherited retinal disease caused by a complete loss of cone photoreceptor function. About 80 % of achromatopsia patients show mutations in the alpha or beta subunit (A3 and B3) of the cGMP controlled cation channel CNG (cyclic nucleotide-gated channel) of cone photoreceptors. Homologous to the human disease, CNGA3 deficient mice reveal a loss of cone specific functionality leading to degeneration of affected cone photoreceptors. The Institute for Ophthalmic Research in Tübingen has now succeeded in curing achromatopsia ACHM2 in an animal model. In this article, we explain the recombinant adeno-associated virus-based approach in detail. Furthermore, applied non-invasive diagnostic techniques for quality and success control, ERG, SLO and OCT, are described. The success of the therapy is indicated by a restored cone photoreceptor function as well as the neuronal processing of retinal signals resulting in a specific, cone-mediated behaviour. The outstanding results derived from the animal model are the starting point for the first human translation of a gene therapy for achromatopsia in Germany.