Litcius/Paper detail

Combined intermittent fasting and ERK inhibition enhance the anti-tumor effects of chemotherapy via the GSK3β-SIRT7 axis

Xiaolong Tang, Guo Li, Lei Shi, Fengting Su, Minxian Qian, Zuojun Liu, Meng Yuan, Shimin Sun, Ji Li, Baohua Liu

2021Nature Communications56 citationsDOIOpen Access PDF

Abstract

Dietary interventions such as intermittent fasting (IF) have emerged as an attractive strategy for cancer therapies; therefore, understanding the underlying molecular mechanisms is pivotal. Here, we find SIRT7 decline markedly attenuates the anti-tumor effect of IF. Mechanistically, AMP-activated protein kinase (AMPK) phosphorylating SIRT7 at T263 triggers further phosphorylation at T255/S259 by glycogen synthase kinase 3β (GSK3β), which stabilizes SIRT7 by decoupling E3 ligase UBR5. SIRT7 hyperphosphorylation achieves anti-tumor activity by disrupting the SKP2-SCF E3 ligase, thus preventing SKP2-mediated K63-linked AKT polyubiquitination and subsequent activation. In contrast, GSK3β-SIRT7 axis is inhibited by EGF/ERK2 signaling, with ERK2 inactivating GSK3β, thus accelerating SIRT7 degradation. Unfavorably, glucose deprivation or chemotherapy hijacks the GSK3β-SIRT7 axis via ERK2, thus activating AKT and ensuring survival. Notably, Trametinib, an FDA-approved MEK inhibitor, enhances the efficacy of combination therapy with doxorubicin and IF. Overall, we have revealed the GSK3β-SIRT7 axis that must be fine-tuned in the face of the energetic and oncogenic stresses in malignancy.

Topics & Concepts

GSK-3Ubiquitin ligaseProtein kinase BCancer researchMAPK/ERK pathwayAMPKTrametinibMdm2HyperphosphorylationPhosphorylationGSK3BMEK inhibitorMedicineBiologyChemistryCell biologyUbiquitinProtein kinase AApoptosisBiochemistryGeneSirtuins and Resveratrol in MedicineMetabolism, Diabetes, and CancerPI3K/AKT/mTOR signaling in cancer
Combined intermittent fasting and ERK inhibition enhance the anti-tumor effects of chemotherapy via the GSK3β-SIRT7 axis | Litcius