Diverse Emerging Therapies Featured at the 2025 Hope in Focus Conference in Minneapolis

The development of diverse treatment approaches for Leber congenital amaurosis (LCA) is necessary because no single modality will work for everyone affected. While development of gene augmentation therapies (i.e., replacing mutated genes with healthy genes) has much momentum, other approaches also show promise as they move into and through clinical trials. Three of those emerging alternatives were discussed by a panel of experts at the Minneapolis meeting in June. The panel was moderated by Amy Laster, PhD, chief scientific officer, Foundation Fighting Blindness.

Ray Therapeutics’ Optogenetic Approaches

Raj Agrawal, MD, the vice president of clinical development at Ray Therapeutics, presented his company’s emerging optogenetic therapies which are moving into clinical trials for retinitis pigmentosa (RP), choroideremia, Stargardt disease, and age-related macular degeneration. While Ray isn’t currently targeting LCA, optogenetics is an approach which may be applicable to some LCA patients.

Optogenetics is a gene-independent approach for restoring some vision for people with advanced inherited retinal diseases (IRDs) who have lost most or all their photoreceptors (rods and cones), the retinal cells that make vision possible. Ray’s therapies deliver genes that express a light-sensing protein called channelrhodopsin to either bipolar or ganglion cells ⎯ cells that are normally not light sensitive but survive after photoreceptors are lost. In essence, the therapies enable bipolar or ganglion cells to work like a back-up system for photoreceptors. The therapies are delivered by a one-time injection into the vitreous, the soft gel in the middle of the eye. These non-invasive injections are performed thousands of times every day in retinal doctors’ offices for treatment of AMD and diabetic retinopathy.

While Ray’s clinical trials are at an early stage, Dr. Agrawal said early reports for safety and efficacy have been encouraging. Stay tuned.

Sepul Bio’s RNA Therapies for LCA10 and USH2A

In early 2022, the biotech company ProQR reported that sepofarsen, its RNA therapy for LCA10 (IVS26 mutation in CEP290), did not meet its primary endpoint in a Phase 2/3 clinical. That news came despite vision improvements, some significant, for many patients in the trial. The endpoint miss led ProQR to stop development of its ophthalmology assets ⎯ sepofarsen and ultevusen (exon 13 mutations in USH2A) ⎯ and find a company to acquire them. 

Mike Schwartz, who was then vice president, global project leader, at ProQR, said, “That was devastating for me, the doctors, and the patients.” He noted that one patient with LCA10 in the trial with only light perception gained enough vision after receiving sepoafarsen to see letters on an eye chart. Another LCA10 patient in the study was able to return to his work as a carpenter after treatment.

Fortunately, a year and a half later, the large European eye care company Théa acquired sepofarsen and ultevursen and formed the Sepul Bio business unit to move the therapies back into clinical trials. Many former ProQR staff went to Sepul Bio including Dr. Schwartz who is now their chief operating officer.

A Phase 2 clinical trial for ultevursen is underway and a global Phase 3 trial for sepofarsen is imminent. Using what was learned from the ProQR trials, the Sepul Bio team made significant changes to designs for the forthcoming trials ⎯ changes they believe will greatly improve chances for success. Mr. Schwartz thanked the Hope in Focus team for providing input from patients for the sepofarsen clinical development program.

Sepul Bio’s RNA therapies, known as antisense oligonucleotides (ASOs), are tiny pieces of genetic material that fix mutations in RNA, the genetic messages that cells read to make protein that’s critical to the cells’ health and function. Both sepofarsen and ultevursen are delivered by intravitreal injections every six months.

BlueRock Therapeutics’ Photoreceptor Replacement Therapy

The development of cell therapies for IRDs has been challenging for numerous reasons. Therapeutic cells haven’t been easy to source and enabling them to survive and integrate when transplanted into patients’ retinas has been difficult.

As a panelist for the session, I had the privilege of discussing a promising photoreceptor replacement therapy from BlueRock Therapeutics which came out of the lab of stem cell pioneer David Gamm, MD, PhD, University of Wisconsin-Madison. Excitingly, BlueRock’s therapy just moved into a clinical trial for people with RP and cone-rod dystrophy. Dr. Gamm said the cells might at some point be relevant to LCA patients.

The photoreceptor precursors used in the trial came from induced pluripotent stem cells (iPSC). The iPSC were derived from a small sample of mature blood or skin cells from a healthy donor. The cells were genetically tweaked to revert back to a stem cell state. The iPSC were then coaxed forward to develop into the photoreceptor precursors. As precursors, they aren’t fully mature. Dr. Gamm research showed that precursors have the best chance at survival and integration after transplantation.

BlueRock has the backing of two prominent companies: Bayer and Fuji Film. The Foundation Fighting Blindness funded Dr. Gamm’s previous iPSC-related lab research.

The BlueRock trial is moving forward methodically so that investigators can ensure safety for patients and best understand which patients and conditions can benefit most from the approach.