Genetically-Caused Blindness Reversed with Single Injection of Antisense Therapeutic

Genetically-Caused Blindness Reversed with Single Injection of Antisense Therapeutic
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A patient with a genetic form of childhood blindness gained vision for more than a year after receiving a single injection of an experimental antisense oligonucleotide, sepofarsen, into the eye. The clinical trial was conducted by researchers at the Scheie Eye Institute in the Perelman School of Medicine at the University of Pennsylvania. According to their study, which appeared in Nature Medicine the treatment led to marked changes at the fovea, the most important locus of human central vision.  

Almost a dozen antisense treatments have been approved by the FDA to date, including Vitravene (omivirsen), Kynamro (mipomerse), and Spinraza (nusinersen). Almost all of these are for orphan diseases, including the drug used in this study sepofarsen, targets Leber congenital amaurosis (LCA), but is specifically designed for LCA patients with the CEP290 mutation — one of the more commonly implicated genes in this disease. Patients with this form of LCA suffer from severe visual impairment, typically beginning in infancy.

“Our results set a new standard of what biological improvements are possible with antisense oligonucleotide therapy in LCA caused by CEP290 mutations,” said co-lead author Artur V. Cideciyan, Ph.D., a research professor of Ophthalmology. “Importantly, we established a comparator for currently-ongoing gene editing therapies for the same disease, which will allow comparison of the relative merits of two different interventions.” Trials are already underway using CRISPR-based treatments for this condition.

In an international clinical trial led at Penn Medicine by Cideciyan and Samuel G. Jacobson, M.D., Ph.D., a professor of Ophthalmology, participants received an intraocular injection of sepofarsen. This oligonucleotide works by increasing normal CEP290 protein levels in the eye’s photoreceptors and improving retinal function under day vision conditions.

In a previous study (Nature Medicine, 2019), Cideciyan, Jacobson, and collaborators found that injections of sepofarsen every three months resulted in continued vision gains in ten patients.

The eleventh patient’s treatment was detailed in this latest Nature Medicine paper. The patient had only one injection and was examined over a 15-month period. Prior to treatment, the patient had reduced visual acuity, small visual fields, and no night vision. After the initial dose, the patient decided to forgo the quarterly maintenance doses, because the regular dosing could lead to cataracts.

After a single injection of sepofarsen, more than a dozen measurements of visual function and retinal structure showed large improvements supporting a biological effect from the treatment. A key finding from the case was that this biological effect was relatively slow in uptake. The researchers saw vision improvement after one month, but the patient’s vision reached a peak effect after month two. Most striking, the improvements remained when tested over 15 months after the first and only injection.

According to the researchers, the extended durability of vision improvement was unexpected and provides implications for treating other ciliopathies — the broader category of diseases associated with genetic mutations encoding defective proteins, which results in the abnormal function of cilia, a protruding sensory organelle found on cells.

“This work represents a really exciting direction for RNA antisense therapy. It’s been 30 years since there were new drugs using RNA antisense oligonucleotides, even though everybody realized that there was great promise for these treatments,” said Jacobson. “The unexpected stability of the ciliary transition zone noted in the patient prompts reconsideration of dosing schedules for sepofarsen, as well as other cilium-targeted therapies.”

One reason why antisense oligonucleotide has proven successful in treating this rare disease, according to the researchers, is that these RNA molecules are small enough to get into the cell nucleus, but are not cleared very quickly, so they remain long enough to do their work.

“There are now, at least in the eye field, a series of clinical trials using antisense oligonucleotides for different genetic defects spawned by the success of the work in CEP290-associated LCA from Drs. Cideciyan and Jacobson,” said Joan O’Brien, MD, chair of Ophthalmology in the Perelman School of Medicine and director of the Scheie Eye Institute

For future studies, the Penn authors are planning gene-specific therapies for other currently incurable blinding inherited retinal disorders.