Glycolysis
4 results on this topic.
Research Papers
CDK8/CDK19 inhibition restores T-cell homeostasis in primary immune thrombocytopenia
CD4+CD25+Foxp3+ regulatory T cells (Tregs) are pivotal negative regulators of the adaptive immune system. Abnormalities in the number and/or function of Tregs contribute to the pathogenesis of primary immune thrombocytopenia (ITP). Strategies aimed at modulating Tregs offer potential therapeutic opportunities for ITP management. In this study, we demonstrated that inhibition of cyclin-dependent kinase 8 (CDK8) and CDK19 activity by the small-molecule inhibitor AS2863619 (AS) robustly promoted the conversion of CD4+CD25- effector T cells (Teffs) into CD4+CD25+Foxp3+ Tregs, endowing the converted Tregs with lineage stability and potent suppressive capacity. Mechanistically, AS rapidly augmented STAT5 phosphorylation and subsequent Foxp3 induction. STAT5 blockade completely abrogated this effect, confirming that the Treg-promoting activity of AS was critically dependent on STAT5 signaling. In parallel, AS suppressed STAT3 phosphorylation under IL-6-driven conditions, thereby attenuating Th17 polarization. These mechanistic findings were supported by global transcriptomic analysis, which revealed a profound transcriptional shift by broadly suppressing gene programs of Teff differentiation and function while simultaneously upregulating a robust signature characteristic of stable Tregs. Crucially, unbiased upstream analysis of these changes pinpointed STAT5, STAT3, and FOXP3 as the core transcription factors mediating the drug's effect. Functional metabolic analysis further revealed that AS mediated metabolic reprogramming in T cells by suppressing glycolysis, thereby providing the necessary metabolic adaptations for Treg conversion. In a murine model of active ITP, CDK8/CDK19 inhibition elevated Treg frequencies and ameliorated thrombocytopenia in a STAT5-dependent manner. Collectively, our study highlighted the therapeutic potential of CDK8/CDK19 inhibition in restoring immune homeostasis and managing ITP.
Metabolic reinvigoration of NK cells by IL-21 enhances immunotherapy against MHC class I-deficient solid tumors.
Natural killer (NK) cells, a type of potent cytotoxic lymphocyte, are particularly promising for the treatment of cancers that lose or downregulate major histocompatibility complex class I (MHC class I) expression to evade T cell-mediated immunotherapy. However, the hostile and immunosuppressive tumor microenvironment (TME) greatly hinders the function of tumor-infiltrating NK cells, thus limiting the therapeutic efficacy. Here, we show a fusion protein of interleukin 21 (IL-21-Fc) that safely and effectively reprograms NK cell metabolism and restores their effector function in vivo. IL-21-Fc synergizes with IL-15 superagonist (IL-15SA) or adoptive NK cell transfer to eradicate MHC class I-deficient tumors and confer durable protection across multiple murine models. Mechanistically, we uncover that IL-21-Fc enhances NK cell effector function by upregulating glycolysis in a lactate dehydrogenase A (LDHA)-dependent manner. This study reveals LDHA-dependent metabolic reprogramming as a key axis for NK cell rejuvenation and positions IL-21-Fc as a promising, clinically translatable strategy to overcome TME-mediated suppression in solid tumors.
Guanine nucleotides drive ribosome biogenesis and glycolytic reprogramming in acute myeloid leukemia stem cells
Abstract Therapy resistance in acute myeloid leukemia (AML) remains a major clinical obstacle, particularly because of the persistence of leukemia stem cells (LSC) capable of metabolic adaptation. Although venetoclax (Ven) inhibits oxidative phosphorylation (OXPHOS), we found that Ven-resistant LSC undergo glycolytic reprogramming to bypass OXPHOS inhibition. This metabolic shift is supported by enhanced ribosome biogenesis, which is sustained by upregulated de novo guanine nucleotide biosynthesis. Abundant guanine nucleotides suppress the impaired ribosome biogenesis checkpoint (IRBC), leading to TP53 destabilization and persistent MYC expression. The inhibition of inosine monophosphate dehydrogenases (IMPDH1/2) depletes guanine nucleotides, activates IRBC, stabilizes TP53, represses MYC, and impairs the metabolic shift to glycolysis. This metabolic rewiring disrupts LSC stemness and suppresses the reconstitution of human AML cells in xenotransplantation experiments. Notably, the suppression of LSC stemness was observed regardless of Ven resistance or the TP53 mutational status of AML cells. These findings reveal that mutation-independent TP53 inactivation is involved in resistant AML and suggest that targeting guanine nucleotide biosynthesis may offer a clinically actionable strategy to eradicate therapy-resistant LSC.
Lactylation fuels nucleotide biosynthesis and facilitates deuterium metabolic imaging of tumor proliferation in preclinical models of H3K27M-mutant gliomas
Hyperactivation of glucose metabolism to lactate is a metabolic hallmark of cancer. However, the functional role of lactate in pediatric diffuse midline glioma (DMG) cells is unclear. Here, using stable isotope tracing and loss-of-function studies in clinically relevant patient-derived DMG models, we show that the oncogenic histone H3K27M mutation epigenetically up-regulates the rate-limiting glycolytic enzyme phosphoglycerate kinase 1 (PGK1) and drives lactate production from [U- 13 C]-glucose in DMGs. Mechanistically, lactate posttranslationally activates the nucleoside diphosphate kinase NME1 through lactylation and facilitates the synthesis of nucleoside triphosphates that are essential for DNA replication and tumor proliferation. This mechanistic link between glycolysis and nucleotide biosynthesis provides the opportunity for deuterium metabolic imaging of tumor growth and response to therapy. Spatially mapping 2 H-lactate production from [6,6- 2 H]-glucose allows visualization of the metabolically active tumor lesion and provides an early readout of response to standard of care and targeted therapy that precedes extended survival and reflects pharmacodynamic alterations in tumor tissues in preclinical DMG models in vivo at clinical field strength (3 T). Overall, we have identified an H3K27M-lactate-NME1 axis that drives DMG proliferation and facilitates noninvasive in vivo metabolic imaging of DMGs.