Drug and drug target identification for Friedreich ataxia
Wilson, Robert B.   
University of Pennsylvania, Philadelphia, PA, United States

We developed a primary, high-throughput drug-screening assay for Friedreich ataxia (FRDA) using a yeast model system, as well as a secondary screening assay using primary FRDA fibroblasts. Both assays are phenotypic and are based on the critical role of mitochondrial dysfunction in the signs and symptoms of FRDA. In the primary assay we turn off the expression of the yeast frataxin homologue, Yfh1p, using an inducible/repressible promoter, and then follow mitochondrial function in 96-well plates using a simple spectrophotometric readout. We optimized our assay to S/B values of > 8, and Z' scores of > 0.7. We successfully implemented our assay at the Southern Research Institute, which is in the process of screening the 102,000-compound NINDS library. The Southern Research Institute will also perform counter-screens (to identify false-positives) and dose-response analyses of all bona fide hit compounds. This proposal describes our plan to: 1) prioritize hit compounds based on secondary assays in yeast and human cells, 2) determine mechanisms of action, and 3) identify potential target proteins and pathways for FRDA therapeutics. Our overall goal is to identify compounds and cellular targets for the treatment of FRDA.
Our Specific Aims are: 1. To test hit compounds from the primary screen in a secondary yeast assay. We will determine the effects of hit compounds on overall ATP production in the yeast model of FRDA. 2. To test compounds from Aim 1 in primary FRDA fibroblasts. We will determine the effects of compounds on tetrazolium dye reduction and on survival in the context of glutathione depletion. 3. To test compounds for mechanisms of action. We will take advantage of the complete library of yeast knockout strains to determine target proteins and pathways. We will confirm our findings in primary FRDA fibroblasts. 4. To perform a genetic suppressor analysis of Yfh1 -depleted cells. We will take advantage of the complete library of yeast knockout strains to identify additional target proteins and pathways using genetic suppressor analysis. We will confirm our findings in primary FRDA fibroblasts. ? ? ?