Systems Pharmacology Identifies Drug Targets for Stargardt Disease-associated Retinal Degeneration

Overview

Journal J Clin Invest

Specialty General Medicine

Date 2013 Nov 16

PMID 24231350

Citations 57

Authors

Yu Chen

Grazyna Palczewska

Debarshi Mustafi

Marcin Golczak

Zhiqian Dong

Osamu Sawada

Tadao Maeda

Akiko Maeda

Krzysztof Palczewski

Affiliations

Soon will be listed here.

Abstract

A systems pharmacological approach that capitalizes on the characterization of intracellular signaling networks can transform our understanding of human diseases and lead to therapy development. Here, we applied this strategy to identify pharmacological targets for the treatment of Stargardt disease, a severe juvenile form of macular degeneration. Diverse GPCRs have previously been implicated in neuronal cell survival, and crosstalk between GPCR signaling pathways represents an unexplored avenue for pharmacological intervention. We focused on this receptor family for potential therapeutic interventions in macular disease. Complete transcriptomes of mouse and human samples were analyzed to assess the expression of GPCRs in the retina. Focusing on adrenergic (AR) and serotonin (5-HT) receptors, we found that adrenoceptor α 2C (Adra2c) and serotonin receptor 2a (Htr2a) were the most highly expressed. Using a mouse model of Stargardt disease, we found that pharmacological interventions that targeted both GPCR signaling pathways and adenylate cyclases (ACs) improved photoreceptor cell survival, preserved photoreceptor function, and attenuated the accumulation of pathological fluorescent deposits in the retina. These findings demonstrate a strategy for the identification of new drug candidates and FDA-approved drugs for the treatment of monogenic and complex diseases.

Citing Articles

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