Development of an IOP-lowering gene therapy treatment for glaucoma

ABSTRACT c Sustained ocular hypertension in open angle glaucoma (OAG) and congenital glaucoma causes degeneration of the optic nerve and death of retinal ganglion cells, leading to irreversible vision loss. Whilst reducing intra-ocular pressure (IOP) using a combination of pharmacological and surgical approaches is

known to effectively prevent glaucoma progression, the therapeutic efficacy of such a strategy is critically undermined by poor patient compliance, with fewer than 25% of patients maintaining treatment over a one- year period. Owing to poor compliance and the need maintain a life-long daily treatment regimen,

glaucomatous patients regularly suffer bouts of uncontrolled ocular hypertension that dramatically increase the risk of developing severe sight-threatening complications, even when diagnosed early. As a consequence, there is a clear need to develop a long-acting therapy that lowers IOP without requiring daily intervention. Herein we propose that IOP may be permanently and safely lowered using a

gene therapy strategy aimed at modifying cells of the cornea and aqueous humor outflow pathway (AHOP) to synthesize and secrete prostaglandin F2α, (PGF2α), a drug that is known clinically to effectively lower IOP in OAG patients when administered daily as an eye drop. We present robust preliminary data demonstrating

that cells of the cornea and AHOP can be effectively targeted using intracameral injection of recombinant adeno-associated virus (rAAV) vector, that expression of prostaglandin F synthase (PTGS2) and prostaglandin F receptor (PTGFR) catalyzes de novo biosynthesis and secretion of PGF2α into the aqueous

humor, and that this causes a highly significant, dose-dependent reduction in IOP that is maintained for over 12-months in normotensive animals. In this multi-PI application, we will evaluate the feasibility, safety and long-term therapeutic efficacy of our novel gene therapy treatment in the Pitx2+/- mouse model of congenital

glaucoma (Aim 1) and the ADAMTS10 beagle model of OAG (Aim 2). Demonstrating the ability to permanently lower IOP in glaucomatous eyes would represent a paradigm shift in the clinical management of glaucoma by obviating the need for adherence to a daily treatment regimen and the data generated from this work is expected to support clinical translation and the instigation of an investigator led clinical trial. The

Ocular Gene Therapy Laboratory of the Medical College of Wisconsin (MCW), directed by Dr Daniel Lipinski (contact PI/PD), and the laboratory of Dr András Komáromy (PI/PD) at the College of Veterinary Medicine at Michigan State University (MSU) provide the perfect environment in which to complete the

proposal. Finally, our proposal addresses an emerging need identified in the NEI Publication “Vision Research: Needs, Gaps, and Opportunities” specifically: 1) Define the genetic architecture of glaucoma to provide direct potential targets for therapy; 2) develop animal models that better approximate human

glaucoma and predict safety and efficacy of novel treatments.