ADP-dependent glucokinase as a novel onco-target for haematological malignancies.

Warburg effect or aerobic glycolysis provides selective growth advantage to aggressive cancers. However, targeting oncogenic regulators of Warburg effect has always been challenging owing to the wide spectrum of roles of these molecules in multitude of cells. In this study, we present ADP-dependent glucokinase (ADPGK) as a novel glucose sensor and a potential onco-target in specifically high-proliferating cells in Burkitt's lymphoma (BL). Previously, we had shown ADPGK to play a major role in T-cell activation and induction of Warburg effect. We now report ADPGK knock-out Ramos BL cells display abated in vitro and in vivo tumour aggressiveness, via tumour-macrophage co-culture, migration and Zebrafish xenograft studies. We observed perturbed glycolysis and visibly reduced markers of Warburg effect in ADPGK knock-out cells, finally leading to apoptosis. We found repression of MYC proto-oncogene, and up to four-fold reduction in accumulated mutations in translocated MYC in knock-out cells, signifying a successful targeting of the malignancy. Further, the activation induced differentiation capability of knock-out cells was impaired, owing to the inability to cope up with increased energy demands. The effects amplified greatly upon stimulation-based proliferation, thus providing a novel Burkitt's lymphoma targeting mechanism originating from metabolic catastrophe induced in the cells by removal of ADPGK.

ADP-dependent glucokinase regulates energy metabolism via ER-localized glucose sensing.

Modulation of energy metabolism to a highly glycolytic phenotype, i.e. Warburg effect, is a common phenotype of cancer and activated immune cells allowing increased biomass-production for proliferation and cell division. Endoplasmic reticulum (ER)-localized ADP-dependent glucokinase (ADPGK) has been shown to play a critical role in T cell receptor activation-induced remodeling of energy metabolism, however the underlying mechanisms remain unclear. Therefore, we established and characterized in vitro and in vivo models for ADPGK-deficiency using Jurkat T cells and zebrafish. Upon activation, ADPGK knockout Jurkat T cells displayed increased cell death and ER stress. The increase in cell death resulted from a metabolic catastrophe and knockout cells displayed severely disturbed energy metabolism hindering induction of Warburg phenotype. ADPGK knockdown in zebrafish embryos led to short, dorsalized body axis induced by elevated apoptosis. ADPGK hypomorphic zebrafish further displayed dysfunctional glucose metabolism. In both model systems loss of ADPGK function led to defective N- and O-glycosylation. Overall, our data illustrate that ADPGK is part of a glucose sensing system in the ER modulating metabolism via regulation of N- and O-glycosylation.

Cellular citrate levels establish a regulatory link between energy metabolism and the hepatic iron hormone hepcidin.

Expression of the hepatic peptide hormone hepcidin responds to iron levels via BMP/SMAD signaling, to inflammatory cues via JAK/STAT signaling, to the nutrient-sensing mTOR pathway, as well as to proliferative signals and gluconeogenesis. Here, we asked the question whether hepcidin expression is altered by metabolites generated by intermediary metabolism. To identify such metabolites, we took advantage of a comprehensive RNAi screen, which revealed effectors involved in citrate metabolism. We show that the inhibition of citrate-consuming enzymes increases hepcidin mRNA expression in primary murine hepatocytes. Consistently, citrate treatment of primary murine hepatocytes or intravenous injection of citrate in mice increases cellular citrate concentrations and hepcidin expression. We further demonstrate that the hepcidin response to citrate involves the SMAD signaling pathway. These results reveal links between iron homeostasis and energy metabolism that may help to explain why iron levels are frequently altered in metabolic disorders. KEY MESSAGES: • Elevated citrate levels increase hepcidin mRNA expression in primary hepatocytes. • Citrate treatment in primary hepatocytes activates hepcidin expression. • Intravenous injection of citrate in mice increases hepcidin mRNA levels. • The hepcidin response to citrate involves the BMP/SMAD signaling pathway.