Flux In Cancer Cells Research Articles

Promising and challenging phytochemicals targeting LC3 mediated autophagy signaling in cancer therapy.

Phytochemicals possess a wide range of anti-tumor properties, including the modulation of autophagy and regulation of programmed cell death. Autophagy is a critical process in cellular homeostasis and its dysregulation is associated with several pathological conditions, such as cancer, neurodegenerative diseases, and diabetes. In cancer, autophagy plays a dual role by either promoting tumor growth or suppressing it, depending on the cellular context. During autophagy, autophagosomes engulf cytoplasmic components such as proteins and organelles. LC3-II (microtubule-associated protein 1 light chain 3-II) is an established marker of autophagosome formation, making it central to autophagy monitoring in mammals. To explore the regulatory role of phytochemicals in LC3-mediated autophagy and their potential therapeutic impact on cancer. The review emphasizes the involvement of autophagy in tumor promotion and suppression, particularly focusing on autophagy-related signaling pathways like oxidative stress through the NRF2 pathway, and its implications for genomic stability in cancer development. The review focuses on a comprehensive analysis of bioactive compounds including Curcumin, Celastrol, Resveratrol, Kaempferol, Naringenin, Carvacrol, Farnesol, and Piperine. Literature on these compounds was examined to assess their influence on autophagy, LC3 expression, and tumor-related signaling pathways. A systematic literature search was conducted across databases including PubMed, Scopus, and Web of Science from inception to 2023. Studies were selected from prominent databases, focusing on their roles in cancer diagnosis and therapeutic interventions, particularly in relation to LC3-mediated mechanisms. Phytochemicals have been shown to modulate autophagy through the regulation of LC3-II levels and autophagic flux in cancer cells. The interaction between autophagy and other cellular pathways such as oxidative stress, inflammation, and epigenetic modulation highlights the complex role of autophagy in tumor biology. For instance, Curcumin and Resveratrol have been reported to either induce or inhibit autophagy depending on cancer type, influencing tumor progression and therapeutic responses. Targeting autophagy through LC3 modulation presents a promising strategy for cancer therapy. The dual role of autophagy in tumor suppression and promotion, however, necessitates careful consideration of the context in which autophagy is induced or inhibited. Future research should aim to delineate these context-specific roles and explore how phytochemicals can be optimized for therapeutic efficacy. Novel therapeutic strategies should focus on the use of bioactive compounds to fine-tune autophagy, thereby maximizing tumor suppression and inducing programmed cell death in cancer cells.

Disrupting Na+ ion homeostasis and Na+/K+ ATPase activity in breast cancer cells directly modulates glycolysis in vitro and in vivo

BackgroundGlycolytic flux is regulated by the energy demands of the cell. Upregulated glycolysis in cancer cells may therefore result from increased demand for adenosine triphosphate (ATP), however it is unknown what this extra ATP turnover is used for. We hypothesise that an important contribution to the increased glycolytic flux in cancer cells results from the ATP demand of Na+/K+-ATPase (NKA) due to altered sodium ion homeostasis in cancer cells.MethodsLive whole-cell measurements of intracellular sodium [Na+]i were performed in three human breast cancer cells (MDA-MB-231, HCC1954, MCF-7), in murine breast cancer cells (4T1), and control human epithelial cells MCF-10A using triple quantum filtered 23Na nuclear magnetic resonance (NMR) spectroscopy. Glycolytic flux was measured by 2H NMR to monitor conversion of [6,6-2H2]d-glucose to [2H]-labelled l-lactate at baseline and in response to NKA inhibition with ouabain. Intracellular [Na+]i was titrated using isotonic buffers with varying [Na+] and [K+] and introducing an artificial Na+ plasma membrane leak using the ionophore gramicidin-A. Experiments were carried out in parallel with cell viability assays, 1H NMR metabolomics of intracellular and extracellular metabolites, extracellular flux analyses and in vivo measurements in a MDA-MB-231 human-xenograft mouse model using 2-deoxy-2-[18F]fluoroglucose (18F-FDG) positron emission tomography (PET).ResultsIntracellular [Na+]i was elevated in human and murine breast cancer cells compared to control MCF-10A cells. Acute inhibition of NKA by ouabain resulted in elevated [Na+]i and inhibition of glycolytic flux in all three human cancer cells which are ouabain sensitive, but not in the murine cells which are ouabain resistant. Permeabilization of cell membranes with gramicidin-A led to a titratable increase of [Na+]i in MDA-MB-231 and 4T1 cells and a Na+-dependent increase in glycolytic flux. This was attenuated with ouabain in the human cells but not in the murine cells. 18FDG PET imaging in an MDA-MB-231 human-xenograft mouse model recorded lower 18FDG tumour uptake when treated with ouabain while murine tissue uptake was unaffected.ConclusionsGlycolytic flux correlates with Na+-driven NKA activity in breast cancer cells, providing evidence for the ‘centrality of the [Na+]i-NKA nexus’ in the mechanistic basis of the Warburg effect.

Estimation of energy pathway fluxes in cancer cells - Beyond the Warburg effect

Glycolytic and respiratory fluxes were analyzed in cancer and non-cancer cells. The steady-state fluxes in energy metabolism were used to estimate the contributions of aerobic glycolytic and oxidative phosphorylation (OxPhos) pathways to the cellular ATP supply. The rate of lactate production - corrected for the fraction generated by glutaminolysis - is proposed as the appropriate way to estimate glycolytic flux. In general, the glycolytic rates estimated for cancer cells are higher than those found in non-cancer cells, as originally observed by Otto Warburg. The rate of basal or endogenous cellular O2 consumption corrected for non-ATP synthesizing O2 consumption, measured after inhibition by oligomycin (a specific, potent and permeable ATP synthase inhibitor), has been proposed as the appropriate way to estimate mitochondrial ATP synthesis-linked O2 flux or net OxPhos flux in living cells. Detecting non-negligible oligomycin-sensitive O2 consumption rates in cancer cells has revealed that the mitochondrial function is not impaired, as claimed by the Warburg effect. Furthermore, when calculating the relative contributions to cellular ATP supply, under a variety of environmental conditions and for different types of cancer cells, it was found that OxPhos pathway was the main ATP provider over glycolysis. Hence, OxPhos pathway targeting can be successfully used to block in cancer cells ATP-dependent processes such as migration. These observations may guide the re-design of novel targeted therapies.

Fusobacterium nucleatum outer membrane vesicles activate autophagy to promote oral cancer metastasis

IntroductionMetastasis is an important cause of high mortality and lethality of oral cancer. Fusobacterium nucleatum (Fn) can promote tumour metastasis. Outer membrane vesicles (OMVs) are secreted by Fn. However, the effects of Fn-derived extracellular vesicles on oral cancer metastasis and the underlying mechanisms are unclear. ObjectivesWe aimed to determine whether and how Fn OMVs mediate oral cancer metastasis. MethodsOMVs were isolated from brain heart infusion (BHI) broth supernatant of Fn by ultracentrifugation. Tumour-bearing mice were treated with Fn OMVs to evaluate the effect of OMVs on cancer metastasis. Transwell assays were performed to determine how Fn OMVs affect cancer cell migration and invasion. The differentially expressed genes in Fn OMV-treated/untreated cancer cells were identified by RNA-seq. Transmission electron microscopy, laser confocal microscopy, and lentiviral transduction were used to detect changes in autophagic flux in cancer cells stimulated with Fn OMVs. Western blotting assay was performed to determine changes in EMT-related marker protein levels in cancer cells. Fn OMVs’ effects on migration after blocking autophagic flux by autophagy inhibitors were determined by in vitro and in vivo experiments. ResultsFn OMVs were structurally similar to vesicles. In the in vivo experiment, Fn OMVs promoted lung metastasis in tumour-bearing mice, while chloroquine (CHQ, an autophagy inhibitor) treatment reduced the number of pulmonary metastases resulting from the intratumoral Fn OMV injection. Fn OMVs promoted the migration and invasion of cancer cells in vivo, leading to altered expression levels of EMT-related proteins (E-cadherin downregulation; Vimentin/N-cadherin upregulation). RNA-seq showed that Fn OMVs activate intracellular autophagy pathways. Blocking autophagic flux with CHQ reduced in vitro and in vivo migration of cancer cells induced by Fn OMVs as well as reversed changes in EMT-related protein expression. ConclusionFn OMVs not only induced cancer metastasis but also activated autophagic flux. Blocking autophagic flux weakened Fn OMV-stimulated cancer metastasis.

Abstract P3-07-21: Therapeutic efficacy of NGY-091 against triple negative breast cancer is mediated by direct cell killing and activation of antitumor immunity

Abstract Aberrant metabolic reprogramming is known to drive triple negative breast cancer progression and metastasis. The increase in glycolytic flux in cancer cells creates a lactate-rich tumor microenvironment (TME) that is exploited by tumors to their advantage by activating immunosuppressive cell populations, such as Tregs and MDSCs, that thrive on lactate as a fuel source. Therefore, blockade of lactate export from glycolytic cancer cells while inhibiting lactate entry into suppressive immune cells is a novel therapeutic strategy to treat cancer. Lactate transport in cells is predominantly mediated by MCT1 and MCT4 transporters. We have developed a compound, NGY-091, that is a first-in-class small molecule dual inhibitor of the MCT1 and MCT4 lactate transporters. NGY-091 treatment exhibited a potent in vitro cytotoxicity against breast cancer cells with various levels of MCT1 and MCT4 expressions. The on-target activity of NGY-091 was validated by measuring intracellular and extracellular lactate levels. NGY-091 strongly blocked MCT1 mediated lactate import and lactate export through MCT4 in vitro. Furthermore, a direct in vivo tumor cell killing was evident in human TNBC CDX (MDA MB 231) and PDX models with the treatment of NGY-091. In a syngeneic model of 4T1, we observed a significant reduction in tumor growth and synergistic tumor regression when combined with immune checkpoint blockade therapy. Profiling of lymphoid and myeloid cells in NGY-091 treated tumors by flow cytometry revealed a significant alteration in immune architecture suggesting activation of antitumor immunity. NGY-091 treated tumors induced a profound increase in effector T cell populations, CD8/Treg ratio and tumor-suppressive M1 macrophages while significantly downregulating M2 macrophages. To further investigate if NGY-091 directly alters immune cell activation and functionality in vitro, we treated CD4 T, CD8 T, Tregs and MDSCs in a lactate-rich culture condition mimicking lactate level in the TME. NGY-091 treatment strongly increased effector CD4 and CD8 T cells while significantly reducing suppressive function of Treg and MDSCs in vitro. These findings indicate the direct effect of NGY-091 on immune cell and validate the in vivo observations in 4T1 tumors. Therefore, NGY-091 intervenes two key hallmarks of cancer – metabolism and immunity and provides a novel avenue to therapeutically target aggressive breast cancer. Citation Format: Sambad Sharma, Sanath Wijerathna, Kerui Wu, Abhishek Tyagi, Shih-Ying Wu, Kounosuke Watabe, Nelly Kuklin, Jaime Escobedo, Vincent Sandanayaka. Therapeutic efficacy of NGY-091 against triple negative breast cancer is mediated by direct cell killing and activation of antitumor immunity [abstract]. In: Proceedings of the 2022 San Antonio Breast Cancer Symposium; 2022 Dec 6-10; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2023;83(5 Suppl):Abstract nr P3-07-21.

Targeting VPS41 induces methuosis and inhibits autophagy in cancer cells

The homotypic fusion and vacuole protein sorting (HOPS) complex mediates membrane trafficking involved in endocytosis, autophagy, lysosome biogenesis, and phagocytosis. Defects in HOPS subunits are associated with various forms of cancer, but their potential as drug targets has rarely been examined. Here, we identified vacuolar protein sorting-associated protein 41 homolog (VPS41), a subunit of the HOPS complex, as a target of methyl 2,4-dihydroxy-3-(3-methyl-2-butenyl)-6-phenethylbenzoate (DMBP), a natural small molecule with preferable anticancer activity. DMBP induced methuosis and inhibited autophagic flux in cancer cells by inhibiting the function of VPS41, leading to the restrained fusion of late endosomes and autophagosomes with lysosomes. Moreover, DMBP effectively inhibited metastasis in a mouse metastatic melanoma model. Collectively, the current work revealed that targeting VPS41 would provide a valuable method of inhibiting cancer proliferation through methuosis.

Micro-Slab Coil Design for Hyperpolarized Metabolic Flux Analysis in Multiple Samples.

Abnormal metabolism is a hallmark of cancer cells. Accumulating evidence suggests that metabolic changes are likely to occur before other cellular responses in cancer cells upon drug treatment. Therefore, the metabolic activity or flux in cancer cells could be a potent biomarker for cancer detection and treatment monitoring. Magnetic resonance (MR)-based sensing technologies have been developed with hyperpolarized molecules for real-time flux analysis, but they still suffer from low sensitivity and throughput. To address this limitation, we have developed an innovative miniaturized MR coil, termed micro-slab MR coil, for simultaneous analysis of metabolic flux in multiple samples. Combining this approach with hyperpolarized probes, we were able to quantify the pyruvate-to-lactate flux in two different leukemic cell lines in a non-destructive manner, simultaneously. Further, we were able to rapidly assess flux changes with drug treatment in a single hyperpolarization experiment. This new multi-sample system has the potential to transform our ability to assess metabolic dynamics at scale.

355 (PB135) - Cellular transporters as novel metabolic immune checkpoints: NGY-091, a small molecule dual MCT1/4 inhibitor for immuno oncology

Background: Aberrant metabolic reprogramming of malignant cells is known to drive cancer progression and metastasis. The increase in glycolytic flux in cancer cells creates a lactate-rich tumor microenvironment (TME), which tumors exploit by expanding immunosuppressive cell populations such as Tregs and MDSCs that thrive on lactate as a fuel source. Blockade of lactate export from glycolytic cancer cells, while inhibiting lactate uptake by suppressive immune cells, is a novel therapeutic strategy to treat cancer. Lactate transport in cells is predominantly mediated by MCT1 and MCT4 transporters. We have developed a compound, NGY-091, a first-in-class small molecule dual inhibitor of the MCT1 and MCT4 lactate transporters. Materials and Methods: The direct cytotoxic effect of NGY-091 was examined in multiple cancer cell lines. The on-target activity of NGY-091 was validated by measuring intracellular and extracellular lactate levels. in vivo efficacy of NGY-091 was studied using CDX, PDX and syngeneic tumor models. Immune profiling of tumor was performed 2 weeks after treating animals with NGY-091 by flow cytometry. Results: NGY-091 treatment exhibited a potent in vitro cytotoxicity against cancer cells with various levels of MCT1 and MCT4 expressions. NGY-091 strongly blocked lactate import through MCT1 under high lactate conditions and lactate export through MCT4 in high glucose conditions. NGY-091 treatment also inhibited pyruvate entry into the mitochondria through MPC1. Furthermore, direct in vivo tumor cell killing was evident in multiple human CDX and PDX models with the treatment of NGY-091. In syngeneic models of 4T1 and MC38 murine tumors, we observed significant tumor growth inhibition with NGY-091 treatment, and strong synergistic tumor reduction when treatment was combined with various immune checkpoint inhibitors. Profiling of lymphoid and myeloid cells in NGY-091 treated tumors by flow cytometry revealed a significant alteration in immune architecture suggesting activation of antitumor immunity. NGY-091 treated tumors induced a profound increase in effector T cell populations, CD8/Treg ratio, and tumor-suppressive M1 macrophages, while significantly downregulating M2 macrophages. To further investigate if NGY-091 directly alters immune cell activation and functionality in vitro, we treated CD4 T, CD8T, Tregs, and MDSCs in a lactate-rich culture condition, which mimicked the lactate level in the TME. NGY-091 treatment strongly increased effector CD4+ and CD8+ T cells, meanwhile it significantly reduced suppressive function of Treg and MDSCs in vitro. Conclusions: These findings indicate the direct effect of NGY-091 on immune cells and validate the in vivo observations in 4T1 tumors. Therefore, NGY-091 intervenes with two key hallmarks of cancer, metabolism and immunity and provides a novel modality to therapeutically target cancer. Conflict of interest: Ownership: Nirogy Therapeutics

Rotating Magnetic Fields Inhibit Mitochondrial Respiration, Promote Oxidative Stress and Produce Loss of Mitochondrial Integrity in Cancer Cells.

Electromagnetic fields (EMF) raise intracellular levels of reactive oxygen species (ROS) that can be toxic to cancer cells. Because weak magnetic fields influence spin state pairing in redox-active radical electron pairs, we hypothesize that they disrupt electron flow in the mitochondrial electron transport chain (ETC). We tested this hypothesis by studying the effects of oscillating magnetic fields (sOMF) produced by a new noninvasive device involving permanent magnets spinning with specific frequency and timing patterns. We studied the effects of sOMF on ETC by measuring the consumption of oxygen (O2) by isolated rat liver mitochondria, normal human astrocytes, and several patient derived brain tumor cells, and O2 generation/consumption by plant cells with an O2 electrode. We also investigated glucose metabolism in tumor cells using 1H and 13C nuclear magnetic resonance and assessed mitochondrial alterations leading to cell death by using fluorescence microscopy with MitoTracker™ and a fluorescent probe for Caspase 3 activation. We show that sOMF of appropriate field strength, frequency, and on/off profiles completely arrest electron transport in isolated, respiring, rat liver mitochondria and patient derived glioblastoma (GBM), meningioma and diffuse intrinsic pontine glioma (DIPG) cells and can induce loss of mitochondrial integrity. These changes correlate with a decrease in mitochondrial carbon flux in cancer cells and with cancer cell death even in the non-dividing phase of the cell cycle. Our findings suggest that rotating magnetic fields could be therapeutically efficacious in brain cancers such as GBM and DIPG through selective disruption of the electron flow in immobile ETC complexes.

Autophagic flux in cancer cells at the invasive front in the tumor-stroma border.

Cancer cells at the invasive front directly interact with stromal tissue that provides a microenvironment with mechanical, nutrient, and oxygen supply characteristics distinct from those of intratumoral tissues. It has long been known that cancer cells at the invasive front and cancer cells inside the tumor body exhibit highly differentiated functions and behaviors. However, it is unknown whether cancer cells at different locations exhibit a variety of autophagic flux, an important catabolic process to maintain cellular homeostasis in response to environmental changes. Here, using transmission electron microscopy (TEM), we found that invading cancer cells at the invasive front, which show mesenchymal transcriptomic traits, exhibit higher autophagic flux than cancer cells inside the tumor body in human primary non-small cell lung cancer (NSCLC) tissues. This autophagic feature was further confirmed by a live cell autophagic flux monitoring system combined with a 3D organotypic invasion coculture system. Additionally, the increased autophagic flux endows cancer cells with invasive behavior and positively correlates with the advanced tumor stages and the reduced survival period of lung cancer patients. These findings expand the understanding of autophagic dynamics during cancer invasion.

Abstract LT009: Stromal BCAT1 drives branched-chain ketoacid dependency in stromal-rich PDAC tumours

Abstract Branched chain amino acids (BCAAs) in cancer serve as requisite precursors for protein synthesis, maintaining metabolite pools in the tricarboxylic acid (TCA) cycle, and sustaining production of nucleotides and lipids. However, the role of stromal cancer associated fibroblasts (CAFs) in support of BCAA metabolism in tumors is still poorly understood. Since most studies in pancreatic cancers have focused on systemic or cancer cell autonomous BCAA metabolism, understanding cancer-stromal ecosystem requires insight into the intersection of cancer-associated transformations in the stroma with reprogramming of their BCAA metabolism. Deciphering the precise role of various cellular components in BCAA metabolism of tumors is complicated by conflicting evidence from past studies and the challenging nature of the intricate tumor microenvironment (TME). Neither systemic in vivo BCAA metabolism nor cancer cells’ BCAA metabolism alone is sufficient to dissect the stromal role. The difficulty in understanding BCAA metabolism in the tumor milieu is exacerbated by nutrient-scarcity, exchange reactions, and metabolite sharing between cancer and stromal cells. Both, the fibrotic environment and nutrient scarcity are difficult to mimic in aggressive murine PDAC models. The metabolic fates of the BCAAs, leucine, valine, and isoleucine, are cell- and tissue-dependent. BCAA transaminases (BCAT1/2), first deaminate BCAAs to branched chain a-ketoacids (BCKAs). The second step in BCAA metabolism involves irreversible BCKA oxidation catalyzed by the mitochondrial BCKA dehydrogenase (BCKDH) complex. Further, oxidation of BCKAs results in succinyl-CoA and acetyl-CoA that act as anaplerotic or ketogenic sources for the TCA cycle. Our recent study revealed differential BCAA metabolism in cancer and stromal compartments of PDAC tumors. We identified a strikingly higher BCAA catabolic flux in CAFs but increased BCKA oxidative flux in cancer cells. Further, CAF-secreted BCKAs were used for maintaining protein synthesis, augmenting TCA cycle metabolite pools, and increasing oxidative phosphorylation in cancer cells. To corroborate the mechanistic underpinnings discovered in our human CAF and cancer cell-line model, we employed two patient-derived models: circulating tumor cells (CTCs) and tumor slice cultures. Collectively, we elucidated an undiscovered metabolic-signaling crosstalk between PDAC and stromal cells and demonstrated that targeting BCAA metabolism in PDAC tumors could mitigate PDAC aggression. Ziwen Zhu, Abhinav Achreja, Noah Meurs, Olamide Animasahun, Sarah Owen, Anjali Mittal, Pooja Parikh, TingWen Lo, Janusz Franco-Barraza, Jiaqi Shi, Mara Sherman, Edna Cuikerman, Andrew Pickering, Anirban Maitra, Vaibhav Sahai, Meredith Morgan, Sunitha Nagrath, Thedore Lawrence, Deepak Nagrath, "Tumor Reprogrammed Stromal BCAT1 Fuels Branched Chain Ketoacid Dependency in Stromal-Rich PDAC Tumors", Nature Metabolism, 2 (8), 2020. Citation Format: Deepak Nagrath. Stromal BCAT1 drives branched-chain ketoacid dependency in stromal-rich PDAC tumours [abstract]. In: Proceedings of the AACR Virtual Special Conference on the Evolving Tumor Microenvironment in Cancer Progression: Mechanisms and Emerging Therapeutic Opportunities; in association with the Tumor Microenvironment (TME) Working Group; 2021 Jan 11-12. Philadelphia (PA): AACR; Cancer Res 2021;81(5 Suppl):Abstract nr LT009.

Gadolinium Oxide Nanoparticles Enhance the Cytotoxicity of Chemotherapeutic Drugs by Blocking Autophagic Flux in Human Ovarian Cancer Cells

Background: During chemotherapy, drugs can damage cancer cells’ DNA and cytomembrane structure, and then induce cell death. However, autophagy can increase the chemotherapy resistance of cancer cells, reducing the effect of chemotherapy. Objective: To block the autophagic flux in cancer cells, it is vital to enhance the anti-cancer efficacy of chemotherapy drugs; for this purpose, we test the gadolinium oxide nanoparticles (Gd2O3 NPs)’ effect on autophagy. Methods: The cytotoxicity of Gd2O3 NPs on HeLa cells was evaluated by a (4,5-dimethylthiazol-2- yl)-2,5-diphenyltetrazolium bromide assay. Then, monodasylcadaverine staining, immunofluorescence, immunoblot, and apoptosis assay were conducted to evaluate the effect of Gd2O3 NPs on autophagy and efficacy of chemotherapy drugs in human ovarian cancer cells. Results: We found that Gd2O3 NPs, which have great potential for use as a contrast agent in magnetic resonance imaging, could block the late stage of autophagic flux in a dose-dependent manner and then cause autophagosome accumulation in HeLa cells. When co-treated with 8 μg/mL Gd2O3 NPs and 5 μg/mL cisplatin, the number of dead HeLa cells increased by about 20% compared with cisplatin alone. We observed the same phenomenon in cisplatin-resistant COC1/DDP cells. Conclusion: We conclude that Gd2O3 NPs can block the late stage of autophagic flux and enhance the cytotoxicity of chemotherapeutic drugs in human ovarian cancer cells. Thus, the nanoparticles have significant potential for use in both diagnosis and therapy of solid tumor.

Histone acetyltransferase 1 is a succinyltransferase for histones and non-histones and promotes tumorigenesis.

Lysine succinylation (Ksucc) is an evolutionarily conserved and widespread post-translational modification. Histone acetyltransferase 1 (HAT1) is a type B histone acetyltransferase, regulating the acetylation of both histone and non-histone proteins. However, the role of HAT1 in succinylation modulation remains unclear. Here, we employ a quantitative proteomics approach to study succinylation in HepG2 cancer cells and find that HAT1 modulates lysine succinylation on various proteins including histones and non-histones. HAT1 succinylates histone H3 on K122, contributing to epigenetic regulation and gene expression in cancer cells. Moreover, HAT1 catalyzes the succinylation of PGAM1 on K99, resulting in its increased enzymatic activity and the stimulation of glycolytic flux in cancer cells. Clinically, HAT1 is significantly elevated in liver cancer, pancreatic cancer, and cholangiocarcinoma tissues. Functionally, HAT1 succinyltransferase activity and the succinylation of PGAM1 by HAT1 play critical roles in promoting tumor progression in vitro and in vivo. Thus, we conclude that HAT1 is a succinyltransferase for histones and non-histones in tumorigenesis.

EXTH-58. ONCOSCILLATORS: INDUCTION OF THE MITOCHONDRIAL PERMEABILITY TRANSITION IN CANCER CELLS

Abstract Magnetic fields in the mT range influence spin state pairing in redox-active radical pairs generating spin-forbidden quantum states which are kinetically inert. Studies examining the effects of static magnetic fields on mitochondrial electron transfer kinetics have demonstrated only modest effects. When neodymium super-magnets are securely attached to and precision-balanced on the shafts of electronically-controlled motors it is possible to generate rotating magnetic fields of desirable strengths and frequencies. Unlike a static magnetic field or an alternating field in a static electromagnetic coil, oscillating magnetic field (OMF) produced by rotating lines of force of a spinning permanent magnet can dynamically couple the electron spins of radical pairs within proteins whose orientations are ‘fixed’. The frequencies of rotation of magnets can also be tuned to appropriate electron cycling resonances within the proteins. Using OMF of appropriate field strength, frequency and on/off acceleration/deceleration profiles we can completely arrest electron transport in isolated respiring rat liver mitochondria. Parallel to this inhibition of electron flux, we also independently observe an increase in superoxide and hydrogen peroxide. Under certain OMF exposure regimes, we observe membrane permeability transition in these mitochondria when using succinate as substrate, and show that the mitochondrial membrane permeability transition effect can be blocked by bongkrekic acid. We have examined the effect of OMF on oxygen consumption in cultured primary cancer cells with a rotating magnet (oncoscillator) that is an integral component of a new anti-cancer Oncomagnetic device. We observe three main effects in addition to the inhibition of respiratory flux in cancer cells – damage to the respiratory complex, uncoupling and generation of superoxide/hydrogen peroxide. OMF generated by oncoscillators can induce mitochondrial permeability transition in primary cultured malignant meningioma, diffuse intrinsic pontine glioma and GBM cells. Parallel experiments with normal human astrocytes show only minor changes in cellular/mitochondrial function under these conditions.

In Silico Prediction of Metabolic Fluxes in Cancer Cells with Altered S-adenosylmethionine Decarboxylase Activity.

This paper investigates the redistribution of metabolic fluxes in the cell with altered activity of S-adenosylmethionine decarboxylase (SAMdc, EC: 4.1.1.50), the key enzyme of the polyamine cycle and the common target for antitumor therapy. To address these goals, a stoichiometric metabolic model was developed that includes five metabolic pathways: polyamine, methionine, methionine salvage cycles, folic acid cycle, and the pathway of glutathione and taurine synthesis. The model is based on 51 reactions involving 57 metabolites, 31 of which are internal metabolites. All calculations were performed using the method of Flux Balance Analysis. The outcome indicates that the inactivation of SAMdc results in a significant increase in fluxes through the methionine, the taurine and glutathione synthesis, and the folate cycles. Therefore, when using therapeutic agents inactivating SAMdc, it is necessary to consider the possibility of cellular tumor metabolism reprogramming. S-adenosylmethionine affects serine methylation and activates serine-dependent de novo ATP synthesis. Methionine-depleted cell becomes methionine-dependent, searching for new sources of methionine. Inactivation of SAMdc enhances the transformation of S-adenosylmethionine to homocysteine and then to methionine. It also intensifies the transsulfuration process activating the synthesis of glutathione and taurine.

Kinetic modeling of glucose central metabolism in hepatocytes and hepatoma cells

BackgroundKinetic modeling and control analysis of a metabolic pathway may identify the steps with the highest control in tumor cells, and low control in normal cells, which can be proposed as the best therapeutic targets. MethodsEnzyme kinetic characterization, pathway kinetic modeling and control analysis of the glucose central metabolism were carried out in rat (hepatoma AS-30D) and human (cervix HeLa) cancer cells and normal rat hepatocytes. ResultsThe glycogen metabolism enzymes in AS-30D, HeLa cells and hepatocytes showed similar kinetic properties, except for higher AS-30D glycogen phosphorylase (GP) sensitivity to AMP. Pathway modeling indicated that fluxes of glycogen degradation and PPP were mainly controlled by GP and NADPH consumption, respectively, in both hepatocytes and cancer cells. Likewise, hexose-6-phosphate isomerase (HPI) and phosphoglucomutase (PGM) exerted significant control on glycolysis and glycogen synthesis fluxes in cancer cells but not in hepatocytes. Modeling also indicated that glycolytic and glycogen synthesis fluxes could be strongly decreased when HPI and PGM were simultaneously inhibited in AS-30D cells but not in hepatocytes. Experimental assessment of these predictions showed that both the glycolytic and glycogen synthesis fluxes of AS-30D cells, but not of hepatocytes, were inhibited by oxamate, by inducing increased Fru1,6BP levels, a competitive inhibitor of HPI and PGM. ConclusionHPI and PGM seem suitable targets for decreasing glycolytic and glycogen synthesis fluxes in AS-30D cells but not in hepatocytes. General significanceThe present study identified new therapeutic targets within glucose central metabolism in the analyzed cancer cells, with no effects on non-cancer cells.

CDK4 Regulates Lysosomal Function and mTORC1 Activation to Promote Cancer Cell Survival.

Cyclin-dependent kinase 4 (CDK4) is well-known for its role in regulating the cell cycle, however, its role in cancer metabolism, especially mTOR signaling, is undefined. In this study, we established a connection between CDK4 and lysosomes, an emerging metabolic organelle crucial for mTORC1 activation. On the one hand, CDK4 phosphorylated the tumor suppressor folliculin (FLCN), regulating mTORC1 recruitment to the lysosomal surface in response to amino acids. On the other hand, CDK4 directly regulated lysosomal function and was essential for lysosomal degradation, ultimately regulating mTORC1 activity. Pharmacologic inhibition or genetic inactivation of CDK4, other than retaining FLCN at the lysosomal surface, led to the accumulation of undigested material inside lysosomes, which impaired the autophagic flux and induced cancer cell senescence in vitro and in xenograft models. Importantly, the use of CDK4 inhibitors in therapy is known to cause senescence but not cell death. To overcome this phenomenon and based on our findings, we increased the autophagic flux in cancer cells by using an AMPK activator in combination with a CDK4 inhibitor. The cotreatment induced autophagy (AMPK activation) and impaired lysosomal function (CDK4 inhibition), resulting in cell death and tumor regression. Altogether, we uncovered a previously unknown role for CDK4 in lysosomal biology and propose a novel therapeutic strategy to target cancer cells. SIGNIFICANCE: These findings uncover a novel function of CDK4 in lysosomal biology, which promotes cancer progression by activating mTORC1; targeting this function offers a new therapeutic strategy for cancer treatment.

Loss of Peter Pan (PPAN) Affects Mitochondrial Homeostasis and Autophagic Flux.

Nucleolar stress is a cellular response to inhibition of ribosome biogenesis or nucleolar disruption leading to cell cycle arrest and/or apoptosis. Emerging evidence points to a tight connection between nucleolar stress and autophagy as a mechanism underlying various diseases such as neurodegeneration and treatment of cancer. Peter Pan (PPAN) functions as a key regulator of ribosome biogenesis. We previously showed that human PPAN localizes to nucleoli and mitochondria and that PPAN knockdown triggers a p53-independent nucleolar stress response culminating in mitochondrial apoptosis. Here, we demonstrate a novel role of PPAN in the regulation of mitochondrial homeostasis and autophagy. Our present study characterizes PPAN as a factor required for maintaining mitochondrial integrity and respiration-coupled ATP production. PPAN interacts with cardiolipin, a lipid of the inner mitochondrial membrane. Down-regulation of PPAN enhances autophagic flux in cancer cells. PPAN knockdown promotes recruitment of the E3-ubiquitin ligase Parkin to damaged mitochondria. Moreover, we provide evidence that PPAN knockdown decreases mitochondrial mass in Parkin-expressing cells. In summary, our study uncovers that PPAN knockdown is linked to mitochondrial damage and stimulates autophagy.

Kallikrein-related peptidase 6 can cleave human-muscle-type 6-phosphofructo-1-kinase into highly active shorter fragments

PurposeCancer cells consume more glucose than normal human cells and convert most glucose into lactate. It has been proposed that deregulated glycolysis is triggered by the posttranslational modification of 85 kDa muscle-type 6-phosphofructo-1-kinase (PFK-M) which is cleaved by a specific protease to form shorter, highly active, feedback-inhibition-resistant PFK-M fragments. Principal resultsTo find the protease involved in PFK-M modification, analyses of the protease target sites on the human PFK-M enzyme yielding 45–47 kDa fragments were performed in silico. The results suggested that an enzyme in the kallikrein (KLK) family may be involved. Kallikreins can be self-activated in the cytosol and are often overexpressed in cancer cells. After incubating the internally quenched FRET peptide with a sequence characteristic of the target site, along with the active KLK6, the cleavage of the peptide was observed. The ability of KLK6 to cleave native PFK-M and form highly active citrate-resistant 45 kDa fragments was further confirmed by enzymatic tests and SDS-PAGE. A role of KLK6 in the posttranslational modification of native PFK-M was ultimately confirmed in vivo. A yeast strain that encoded native human PFK-M as the only PFK1 enzyme was additionally transformed with proKLK6 or KLK6 genes under the control of an inducible promoter. The transformants growth rate was found to increase after the induction of proKLK6 gene expression as compared to the strain with the native PFK-M enzyme. ConclusionKLK6 may be the key protease involved in the modification of PFK-M and trigger deregulated glycolytic flux in cancer cells.

Characterization of the interactions of potent allosteric inhibitors with glutaminase C, a key enzyme in cancer cell glutamine metabolism

Altered glycolytic flux in cancer cells (the "Warburg effect") causes their proliferation to rely upon elevated glutamine metabolism ("glutamine addiction"). This requirement is met by the overexpression of glutaminase C (GAC), which catalyzes the first step in glutamine metabolism and therefore represents a potential therapeutic target. The small molecule CB-839 was reported to be more potent than other allosteric GAC inhibitors, including the parent compound bis-2-(5-phenylacetamido-1,2,4-thiadiazol-2-yl)ethyl (BPTES), and is in clinical trials. Recently, we described the synthesis of BPTES analogs having distinct saturated heterocyclic cores as a replacement for the flexible chain moiety, with improved microsomal stability relative to CB-839 and BPTES. Here, we show that one of these new compounds, UPGL00004, like CB-839, more potently inhibits the enzymatic activity of GAC, compared with BPTES. We also compare the abilities of UPGL00004, CB-839, and BPTES to directly bind to recombinant GAC and demonstrate that UPGL00004 has a similar binding affinity as CB-839 for GAC. We also show that UPGL00004 potently inhibits the growth of triple-negative breast cancer cells, as well as tumor growth when combined with the anti-vascular endothelial growth factor antibody bevacizumab. Finally, we compare the X-ray crystal structures for UPGL00004 and CB-839 bound to GAC, verifying that UPGL00004 occupies the same binding site as CB-839 or BPTES and that all three inhibitors regulate the enzymatic activity of GAC via a similar allosteric mechanism. These results provide insights regarding the potency of these inhibitors that will be useful in designing novel small-molecules that target a key enzyme in cancer cell metabolism.