Infection-associated blindness caused by herpesviruses is a leading cause of vision loss in the United States. Frontline therapies include the use of nucleoside analogs such as acyclovir which inhibit the viral thymidine kinase to restrict viral DNA replication. However, emergence of drug resistance and lack of strong corneal bioavailability have made it an urgent priority to develop alternative therapeutics. We have recently discovered a new mechanism through which herpesviruses, exemplified by herpes simplex virus type-1 (HSV-1), propagate in the corneal epithelium. We have shown that endoplasmic reticulum (ER)-localized host protein cyclic adenosine 3′,5′-monophosphate (cAMP) response element-binding protein 3 (CREB3) is essential to HSV-1 replication. Our findings shift the current understanding that CREB3 is only a cellular homolog of HSV-1 VP16. We showed that it is an important pro-viral factor that can be exploited to generate novel therapeutics against HSV infections. We for the first time showed that its modulation via a chemical chaperone 4- phenylbutyrate sodium (Na-PBA), can alleviate, ER stress, reduce CREB3 expression and inhibit viral replication. PBA is currently approved to treat urea cycle disorder. Our translational results are supported by strong in vivo murine data that suggests antiviral efficacy and topical dosage safety of Na-PBA. Due to the high sodium burden associated with Na-PBA administration, its unpalatability, and inability to penetrate sufficiently through corneal epithelium upon topical administration, we have developed various sodium-free PBA nanoformulations to overcome limitations associated with oral and topical delivery of Na-PBA. The purpose of this R24 application is to generate preclinical data in two animal models that support an IND application for repurposing PBA to treat ocular HSV infection. This will be achieved via 3 well thought, exhaustive specific aims. In the first aim, we will evaluate dose-dependent pharmacokinetics, and safety of orally and topically delivered Na-PBA solution and various sodium-free PBA nanoformulations. Furthermore, we will also determine oral and topical, and oral antiviral efficacy of Na-PBA and sodium-free PBA nanoformulations in murine models of ocular HSV-1 infection. The second aim will use the most effective oral and topical formulation(s) and test their safety, PK, and efficacy in guinea pig and rabbit models of primary and reactivated ocular HSV-1 infection. Finally aim 3, we will investigate the potential of Na-PBA and sodium-free PBA formulations to synergize with existing antiviral therapies to determine their potential as an add-on modality to the existing treatment. The latter is likely and significant since PBA is a rare drug that works via alleviating ER stress and aiding the host cell’s response to viral infection, and thereby reducing the chance for emergence of viral resistance. We have assembled a multidisciplinary team including scientists, clinicians,...