Yeasts as complementary model systems for the study of the pathological repercussions of enhanced synphilin‐1 glycation and oxidation

Abstract

Synphilin‐1 has previously been identified as an interaction partner of α‐Synuclein (αSyn), a primary constituent of neurodegenerative disease‐linked Lewy bodies. In this study, the repercussions of a disrupted glyoxalase system and aldose reductase function on Synphilin‐1 inclusion formation characteristics and cell growth were investigated. To this end, either fluorescent dsRed-tagged or non‐tagged human SNCAIP, which encodes the Synphilin‐1 protein, was expressed in Saccharomyces cerevisiae and Schizosaccharomyces pombe yeast strains devoid of enzymes Glo1, Glo2, and Gre3. Presented data shows that lack of Glo2 and Gre3 activity in S. cerevisiae increases the formation of large Synphilin‐1 inclusions. This correlates with enhanced oxidative stress levels and an inhibitory effect on exponential growth, which is most likely caused by deregulation of au-tophagic degradation capacity, due to excessive Synphilin‐1 aggresome build‐up. These findings illustrate the detrimental impact of increased oxidation and glycation on Synphilin‐1 inclusion for-mation. Similarly, polar‐localised inclusions were observed in wild‐type S. pombe cells and strains deleted for either glo1+ or glo2+. Contrary to S. cerevisiae, however, no growth defects were observed upon expression of SNCAIP. Altogether, our findings show the relevance of yeasts, especially S. cerevisiae, as complementary models to unravel mechanisms contributing to Synphilin‐1 pathology in the context of neurodegenerative diseases.