Sugar-induced cell death in exponentially growing yeast depends on the functionality of the nonoxidative branch of the pentose phosphate pathway.

Sugar-induced cell death (SICD) remains an intriguing but poorly studied phenomenon in the physiology of Saccharomyces cerevisiae. Recently, it was shown that SICD development largely depends on the redirection of glucose fluxes between glycolysis and the pentose phosphate pathway (PPP). In particular, inhibition of glycolysis by iodoacetamide (IAA) was observed to reduce SICD levels. This study is devoted to further investigation of the relationship between SICD and the functionality of the two PPP branches. It was shown that deletion of the ZWF1 gene does not affect the decrease in SICD levels in IAA-treated cells. This allows us to conclude that the oxidative branch of the PPP is not involved in the suppression of SICD/ROS. Deletion of the GLR1 gene and attenuation of the TRR1 gene also did not restore SICD levels in cells after IAA treatment. The obtained results indicate that the level of reduced glutathione or thioredoxin does not affect SICD genesis. The addition of 5 mM ribose-5-phosphate (R5P) to the incubation medium led to suppression of SICD by 79%. At the same time, the addition of 5 mM ribose + 5 mM Pi suppressed SICD by only 20%. Suppression of SICD by 5 mM R5P in the{Delta} pho3 strain (83%) excludes the mechanism of extracellular dephosphorylation of R5P to ribose, its subsequent transport into the cell, and re-phosphorylation inside the cell. Furthermore, more than 70% suppression of SICD in the{Delta} end3 strain with 5 mM R5P excludes endocytosis as a mechanism of R5P import into the cell. The observed effect of R5P can be explained by the moonlighting function of some unknown protein. Thus, SICD development in S. cerevisiae cells depends on the final product of the non-oxidative PPP--R5P.