Abstract Background Targeting glucose uptake by glucose transporter (GLUT) inhibitors is a therapeutic opportunity, but efforts on GLUT inhibitors have not been successful in the clinic and the underlying mechanism remains unclear.We aim to identify the Pre-Roll Injector Machine key metabolic changes responsible for cancer cell survival from glucose limitation and elucidate its mechanism.Methods The level of phosphorylated YAP was analyzed with Western blotting and Phos-tag immunoblotting.
Glucose limitation-induced metabolic changes were analyzed using targeted metabolomics (600MRM).The anti-cancer role of metabolite was examined using colony formation assay and APC min/+ mice.Co-immunoprecipitation, LS-MS, qRT-PCR, and immunofluorescence were performed to explore the underlying mechanisms.
Results We found that D-Ribose-5-phosphate (D5P), a product of the pentose phosphate pathway connecting glucose metabolism and nucleotide metabolism, functions as a metabolic checkpoint to activate YAP under glucose limitation to promote cancer cell survival.Mechanistically, in glucose-deprived cancer cells, D5P is decreased, which facilitates the interaction between MYH9 and LATS1, resulting MEDI C PLUS W/MG in MYH9-mediated LATS1 aggregation, degradation, and further YAP activation.Interestingly, activated YAP further promotes purine nucleoside phosphorylase (PNP)-mediated breakdown of purine nucleoside to restore D5P in a feedback manner.
Importantly, D5P synergistically enhances the tumor-suppressive effect of GLUT inhibitors and inhibits cancer progression in mice.Conclusions Our study identifies D5P as a metabolic checkpoint linking glucose limitation stress and YAP activation, indicating that D5P may be a potential anti-cancer metabolite by enhancing glucose limitation sensitivity.