Project description:<p>The energy sensor AMPK promotes tumor cell survival under stress, but how to prevent AMPK activation to blunt tumor progression remains unclear. Here we show that the metabolite α-ketoglutarate (α-KG) controls AMPK translation through a TET-YBX1 axis, which can be exploited to sensitize human cancer cells to energy stress. α-KG-deficient cells fail to activate AMPK under glucose starvation, which elicits cytosolic NADPH depletion and cell death . Mechanistically, α-KG insufficiency inhibits TET-dependent transcription of YBX1, an RNA-binding protein required for human-specific AMPK translation. Similarly, α-KG competitors including succinate and itaconate inhibit the YBX1-AMPK axis and sensitize cancer cells to glucose starvation. Finally, co-targeting oncogenic YBX1 and GLUT1 creates a synthetic lethality and therapeutically blunts tumor growth&nbsp;in vivo. Together, our findings link α-KG to energy sensing through AMPK translation, and propose that targeting α-KG-YBX1-dependent AMPK translation can sensitize human cancer cells to energy stress for treatment.</p>

Project description:<p>The energy sensor AMPK promotes tumor cell survival under stress, but how to prevent AMPK activation to blunt tumor progression remains unclear. Here we show that the metabolite α-ketoglutarate (α-KG) controls AMPK translation through a TET-YBX1 axis, which can be exploited to sensitize human cancer cells to energy stress. α-KG-deficient cells fail to activate AMPK under glucose starvation, which elicits cytosolic NADPH depletion and cell death . Mechanistically, α-KG insufficiency inhibits TET-dependent transcription of YBX1, an RNA-binding protein required for human-specific AMPK translation. Similarly, α-KG competitors including succinate and itaconate inhibit the YBX1-AMPK axis and sensitize cancer cells to glucose starvation. Finally, co-targeting oncogenic YBX1 and GLUT1 creates a synthetic lethality and therapeutically blunts tumor growth&nbsp;in vivo. Together, our findings link α-KG to energy sensing through AMPK translation, and propose that targeting α-KG-YBX1-dependent AMPK translation can sensitize human cancer cells to energy stress for treatment.</p>

Project description:Cultured cancer cells frequently rely on the consumption of glutamine and its subsequent hydrolysis to glutamate by the mitochondrial enzyme glutaminase (GLS). However, this metabolic addiction can be lost in the tumor microenvironment (TME), rendering GLS inhibitors ineffective in the clinic. Here, we show that seemingly glutamine-addicted breast cancer cells ultimately adapt to chronic glutamine starvation, or targeted GLS inhibition, via the AMPK-mediated upregulation of the serine synthesis pathway (SSP). In this context, the key product of the SSP is not serine itself, but a-ketoglutarate (a-KG). Mechanistically, we find that the phylogenetically distinct transaminase phosphoserine aminotransferase 1 (PSAT1) has a unique capacity for sustained a-KG production when glutamate is severely depleted. Breast cancer cells with intrinsic or acquired resistance to glutamine starvation or GLS inhibition are highly dependent on SSP-supplied a-KG. Accordingly, pharmacological disruption of the SSP prevents adaptation to glutamine blockade, yielding a potent drug synergism that abolishes breast tumor growth in vivo. These findings highlight how metabolic redundancy can be context dependent, with the catalytic properties of different metabolic enzymes that act on the same substrate determining which pathways can support tumor growth in a particular nutrient environment. This in turn has practical consequences for therapies targeting cancer metabolism.

Project description:In recent years, gastric cancer (GC) has garnered significant attention due to its poor response to treatment, unfavorable prognosis, and the lack of reliable biomarkers for predicting disease progression and therapeutic outcomes. α-Ketoglutarate (α-KG), a critical metabolite involved in cellular energy metabolism and epigenetic regulation during tumor development, has emerged as a potential prognostic biomarker for GC. To explore this potential, we utilized publicly available datasets from the TCGA and GEO databases to analyze α-KG-related genes and establish the α-KG Index (AKGI). By evaluating the predictive performance of the AKGI model, we confirmed its robust capability to predict survival outcomes in gastric cancer patients.By analyzing signaling pathways and biological functions correlated with AKGI, we elucidated the regulatory mechanisms and biological roles of α-KG in gastric cancer. These insights were validated through cellular experiments, where α-KG treatment was shown to significantly inhibit gastric cancer cell proliferation, migration, and invasion.Taken together, our data demonstrate AKGI offers a valuable framework for advancing our understanding of the role and mechanisms of α-KG in gastric cancer.

Project description:Increasing evidence suggests that ribosome composition and modifications contribute to translation control. Much less is known about the regulatory roles of mRNA binding by ribosomal proteins to specific mRNA translation and ribosome specialization. Here we used CRISPR-Cas9, to mutate the RPS26 C-terminal tail (RPS26dC) predicted to bind AUG upstream nucleotides at the exit channel. RPS26 binding to positions -10 to -16 of short 5’UTR mRNAs exerts positive and negative effects on translation directed by Kozak and TISU, respectively. Consistent with that, shortening the 5′UTR from 16 to 10 nt diminished Kozak and enhanced TISU-driven translation. As TISU is resistant and Kozak is sensitive to energy stress, we examined stress responses and found that the RPS26dC mutation confers resistance to glucose starvation and mTOR inhibition. Furthermore, the basal mTOR activity is reduced while AMPK is activated in RPS26dC cells, mirroring energy-deprived WT cells. Likewise, the translatome of RPS26dC cells is correlated to glucose-starved WT cells. Our findings uncover the central roles of RPS26 C-terminal RNA binding in energy metabolism, in the translation of mRNAs bearing specific features and in the translation tolerance of TISU genes to energy stress.

Project description:The aim of the experiment is to define p-AMPK binding sites across the genome upon mice starvation and treatment with Dexamethasone (GR ligand) and GW7647 (PPAR alpha ligand).

Project description:<p>Nutrient-deprived conditions in the tumor microenvironment (TME) restrain cancer cell viability due to increased free radicals and reduced energy production. In pancreatic cancer cells, a cytosolic metabolic enzyme, wild-type isocitrate dehydrogenase 1 (wtIDH1), enables the adaptation to these conditions. Under nutrient starvation, wtIDH1 oxidizes isocitrate to generate α-ketoglutarate (αKG) for anaplerosis, and NADPH to support antioxidant defense. In this study, we show that allosteric inhibitors of mutant IDH1 (mIDH1) are potent wtIDH1 inhibitors under conditions present in the TME. We demonstrate that low magnesium levels facilitate allosteric inhibition of wtIDH1, which is lethal to cancer cells when nutrients are limited. Furthermore, the FDA-approved mIDH1 inhibitor ivosidenib (AG-120) dramatically inhibited tumor growth in preclinical models of pancreatic cancer, highlighting this approach as a potential therapeutic strategy against wild-type IDH1 cancers.</p>

Project description:Here we uncover that TNF-receptor associated protein-1 (TRAP1) expression in TAMs is markedly reduced in the TME, a process mediated by the TIM4-AMPK signaling pathway. In addition, TRAP1 deficiency leads to increased activity of mitochondrial electron transport chain complexes and an elevated α-ketoglutarate (α-KG) to succinate ratio. The increase in α-KG facilitate JMJD3-mediated histone demethylation, altering genes expression associated with immunosuppressive activation in macrophages.

Project description:Background The cytosolic 5’-nucleotidase II gene (NT5C2, cN-II) is associated with disorders characterised by psychiatric and psychomotor disturbances. Common psychiatric risk alleles at the NT5C2 locus reduce expression of this gene in the foetal and adult brain, but downstream biological risk mechanisms remain elusive. Methods Distribution of the NT5C2 protein in the human DLPFC and cortical human neural progenitor cells (hNPCs) was determined using immunostaining, publicly available expression data, and reverse transcription quantitative PCR (RT-qPCR). Phosphorylation quantification of AMPK-alpha (Thr172) and ribosomal protein S6 (RPS6) (Ser235/Ser236) were performed using western blotting, to infer the degree of activation of AMPK signalling and the rate of protein translation. Knockdowns were induced in hNPCs and Drosophila melanogaster using RNA interference (RNAi). Transcriptomic profiling of hNPCs was performed using microarrays, and motility behaviour was assessed in flies using the climbing assay. Results Expression of NT5C2 was higher during neurodevelopment, and was neuronally enriched in the adult human cortex. Knockdown in hNPCs affected AMPK signalling, a major nutrient sensing mechanism involved in energy homeostasis, and protein translation. Transcriptional changes implicated in protein translation were observed in knockdown hNPCs, and expression changes to genes related to AMPK signalling and protein translation were confirmed using RT-qPCR. The knockdown in Drosophila was associated with drastic climbing impairment. Conclusions We provide an extensive neurobiological characterisation of the psychiatric risk gene NT5C2, describing its previously unknown role on the regulation of AMPK signalling and protein translation in neural stem cells, and its association with Drosophila melanogaster motility behaviour.

Project description:AMP-activated protein kinase (AMPK) is a key regulator of energy metabolism that, upon activation, phosphorylates a wide range of substrate proteins in order to restore cellular energy balance. AMPK is a heterotrimeric protein that is composed of three subunits: α, β and γ. The α and β subunits are encoded by two, the γ subunit by three genes that are expressed in a tissue- and species-specific manner. However, neither the mechanisms of how different trimer combinations affect AMPK downstream effects nor the functional properties of single isoforms are completely understood so far. We provide evidence that AMPKβ1- and β2-containing AMPK trimers lead to different gene expression profiles in a model of human induced pluripotent stem cells and thereby differentially affect lineage decision. The analysis of hiPSCs harboring a gene knockout for AMPK β1 (PRKAB1-/-) and for AMPK β2 (PRKAB2-/-) compared to WT hiPSCs revealed major differences in the gene expression profile in all the cell lines. This suggests an isoform-specific regulation of gene expression.