Project Summary Porphyrias are genetic disorders caused by mutations in enzymes involved in eight sequential biosynthetic conversions that combine glycine and succinyl coenzyme-A in the first enzymatic step to ultimately generate heme. Porphyrin accumulation also occurs in ‘secondary porphyrias’ in association with other diseases such as hepatitis C virus infection. Current major unmet needs with regard to the porphyria disorders include: (a) our present limited understanding of the biochemical mechanism of cell and tissue injury, (b) the molecular triggers of porphyria acute attacks, (c) the reasons why some individuals develop significant organ complications such as end-stage liver disease that requires liver or bone marrow transplantation, while others do not, and (d) the limited availability of drugs to treat the different porphyrias. Our central hypothesis is that the liver is susceptible to light-independent porphyrin-mediated proteotoxic damage that leads to cell and tissue injury in porphyria, and that drugs can be identified that lead to increased or decreased porphyrin accumulation. This hypothesis will be tested by pursuing three interconnected specific aims: (i) Define the mechanism of light-independent porphyrin- induced protein aggregation in internal organs, with a focus on the liver; (ii) Elucidate the mechanism of detoxification of porphyrin-induced proteotoxic damage using in vitro and in vivo models; and (iii) Characterize small molecules that decrease or increase tissue porphyrin accumulation and porphyrin-mediated proteotoxicity. We have assembled extensive preliminary results to support the likely success of our aims, including substantial evidence for porphyrin-mediated protein aggregation that is light-independent, the reversibility of protein aggregation and enzymes that are likely to be involved in reversing protein oxidation, and the use of zebrafish high-throughput screening to identify known drugs that decrease or increase porphyrin accumulation in liver. The drugs that decrease porphyrin accumulation will be tested for their mechanism of action and examined in preclinical porphyria experimental models as drugs that may be repurposed as potential new therapies. In parallel, drugs that increase porphyrin accumulation will be characterized as potential candidate drugs to avoid in patients with porphyria. Completion of our proposed aims provides fundamental knowledge regarding which proteins are prone to porphyrin-mediated oxidation and aggregation, the molecular signatures that define such aggregation, the mechanism of aggregate turnover and disaggregation, whether compounds we characterize are candidates for testing in patients with porphyria, and whether currently used drugs in non-porphyria disorders might need to be avoided or monitored in patients with porphyria. This proposal uses state-of-the-art technologies, multiple biochemical and porphyria animal model tools including zebrafish and mice, and introduces the...