Phenylbutyrate modulates polyamine acetylase and ameliorates Snyder-Robinson syndrome in a Drosophila model and patient cells
Xianzun Tao, Yi Zhu, Zoraida Diaz-Perez, Seok-Ho Yu, Jackson R. Foley, Tracy Murray Stewart, Robert A. Casero Jr., Richard Steet, R. Grace Zhai
Xianzun Tao, Yi Zhu, Zoraida Diaz-Perez, Seok-Ho Yu, Jackson R. Foley, Tracy Murray Stewart, Robert A. Casero Jr., Richard Steet, R. Grace Zhai
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Research Article Genetics Therapeutics

Phenylbutyrate modulates polyamine acetylase and ameliorates Snyder-Robinson syndrome in a Drosophila model and patient cells

Abstract

Polyamine dysregulation plays key roles in a broad range of human diseases from cancer to neurodegeneration. Snyder-Robinson syndrome (SRS) is the first known genetic disorder of the polyamine pathway, caused by X-linked recessive loss-of-function mutations in spermine synthase. In the Drosophila SRS model, altered spermidine/spermine balance has been associated with increased generation of ROS and aldehydes, consistent with elevated spermidine catabolism. These toxic byproducts cause mitochondrial and lysosomal dysfunction, which are also observed in cells from SRS patients. No efficient therapy is available. We explored the biochemical mechanism and discovered acetyl-CoA reduction and altered protein acetylation as potentially novel pathomechanisms of SRS. We repurposed the FDA-approved drug phenylbutyrate (PBA) to treat SRS using an in vivo Drosophila model and patient fibroblast cell models. PBA treatment significantly restored the function of mitochondria and autolysosomes and extended life span in vivo in the Drosophila SRS model. Treating fibroblasts of patients with SRS with PBA ameliorated autolysosome dysfunction. We further explored the mechanism of drug action and found that PBA downregulates the first and rate-limiting spermidine catabolic enzyme spermidine/spermine N1-acetyltransferase 1 (SAT1), reduces the production of toxic metabolites, and inhibits the reduction of the substrate acetyl-CoA. Taken together, we revealed PBA as a potential modulator of SAT1 and acetyl-CoA levels and propose PBA as a therapy for SRS and potentially other polyamine dysregulation–related diseases.

Authors

Xianzun Tao, Yi Zhu, Zoraida Diaz-Perez, Seok-Ho Yu, Jackson R. Foley, Tracy Murray Stewart, Robert A. Casero Jr., Richard Steet, R. Grace Zhai

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Figure 3

PBA treatment partially restores mitochondria in a Drosophila SRS model.

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PBA treatment partially restores mitochondria in a Drosophila SRS model....
(A) Mitochondrial membrane protein ATP5α and contractile filament component F-actin staining of flight muscle of 10 DAE flies with or without PBA feed. The third row shows recognized mitochondria by automatic segregation of ATP5α staining signal using ImageJ H-watershed (NIH). The images are representatives of 5 flies in each group. Scale bar: 10 μm. The diagram of muscle fiber structure on the top right is adapted from (97). (B) Quantification of mitochondrial size indicated by segregated ATP5α signal. Each mitochondrion is marked as a dot. Multiple dots of mitochondria with the same size aggregate into a black line. The blue dash lines indicate the average values. The red bars indicate SD. (C) Quantification of mitochondrial shape indicated by circularity of segregated ATP5α signal. Each mitochondrion is marked as a dot. Multiple dots of mitochondria with the same circularity aggregate into a black line. The blue dash lines indicate the average values. The red bars indicate SD. (D) COX activity staining of flight muscle of 10 DAE flies with or without PBA feed. The image is a representative of 10 samples in each group. Scale bar: 50 μm. (E) Quantification of COX activity in D. n = 10; **P < 0.01, ***P < 0.001; ordinary 1-way ANOVA multiple comparisons in B, C, and E. Data represent mean ± SEM.