Investigating Polyphosphate Biology: From Post-Translational Modification to Rare Disease

Abstract

The first report of polyphosphates (polyP) was in 1890 by L. Liberman and since then, polyP’s role in biology has been explored. PolyPs are chains of phosphoanhydride-linked inorganic phosphates ranging from 3-1000s of units in length. These chains are implicated in many cellular pathways including blood clotting, bacterial virulence, and neuroproteotoxic disease. Given the diversity of polyP, they make an excellent candidate in the development of novel therapeutics. In yeast, polyP is synthesized by the vacuolar transporter chaperone (VTC) complex as a translocation event into the vacuole lumen. In 2015, polyP chains were found to act as a post-translational modification termed polyphosphorylation on yeast proteins (Nsr1 and Top1). This modification occurs non-enzymatically on lysine residues within poly-acidic, serine, and lysine (PASK) motifs and can only be detected via electrophoretic mobility shift on NuPAGE gels. We have since expanded the pool of yeast polyphosphorylated substrates to 25, with an enrichment of proteins with roles related to RNA biology. Additionally, we were the first group to demonstrate polyphosphorylation of 6 human proteins by expressing E. coli PPK1 in HEK293T cells. We next focused on elaborating how polyP is being regulated via the VTC complex by assessing which protein trafficking pathways are critical for VTC localization at the vacuole membrane. We found the adaptor protein 3 (AP-3) complex is responsible for localizing Vtc5 subunit to the vacuole membrane and in AP-3 mutants, Vtc5 becomes mislocalized to the vacuole lumen and degraded. Vtc5 degradation, upon AP-3 mutation, is mediated by the endosomal sorting complex required for transport (ESCRT) complex. The loss of polyP in AP-3 mutants is imparted by Vtc5 mislocalization. In humans, mutations in AP-3 cause a rare genetic disorder termed Hermansky-Pudlak Syndrome (HPS) which has a wide range of symptoms. These include defects in polyP accumulation in platelets, likely related to a loss of polyP. We expect that our work using yeast will provide a framework for understanding fundamental aspects of polyP biology related to HPS and other health conditions.