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Two chemical series, oxalamides and benozothiazoles, produced toxicity in particular lung cancer cells. These compounds were metabolized in these sensitive cells by the cytochrome P450 enzyme CYP4F11 into potent inhibitors of stearoyl CoA desaturase. A hallmark of targeted cancer therapies is selective toxicity among cancer cell lines. We evaluated results from a viability screen of over 200,000 small molecules to identify two chemical series, oxalamides and benzothiazoles, that were selectively toxic at low nanomolar concentrations to the same 4 of 12 human lung cancer cell lines. Sensitive cell lines expressed cytochrome P450 (CYP) 4F11, which metabolized the compounds into irreversible inhibitors of stearoyl CoA desaturase (SCD). SCD is recognized as a promising biological target in cancer and metabolic disease. However, SCD is essential to sebocytes, and accordingly SCD inhibitors cause skin toxicity. Mouse sebocytes did not activate the benzothiazoles or oxalamides into SCD inhibitors, providing a therapeutic window for inhibiting SCD in vivo . We thus offer a strategy to target SCD in cancer by taking advantage of high CYP expression in a subset of tumors.

During focal ischemia, neurons can use lactate as an alternative source of energy through its oxidation into pyruvate by the lactate dehydrogenase (LDH). After cardiac arrest, the neurological consequences of this phenomenon are unknown. Experimental study. Experimental laboratory. Male New-Zealand rabbits. Animals were surgically instrumented and randomly divided into five groups receiving short infusion duration of either lactate or pyruvate or a pre-cardiac arrest infusion of oxamate (an inhibitor of the lactate dehydrogenase) or injection of fluorocitrate (an inhibitor of astrocytic tricarboxylic acid), or Saline (lactate, pyruvate, Oxa, FC and Control groups, respectively). After randomization, animals were submitted to 10 min of ventricular fibrillation and subsequent resuscitation. All animals were then either followed during 4 h, for the evaluation of the cerebral net uptake and concentrations of metabolites by microdialysis (n = 6 in each experimental group, n = 12 in control group), or during 48 h for the evaluation of their neurological outcome (n = 7 in each groups and n = 14 in control group). Cardiac arrest was associated with a dramatic increase in cerebral net uptake of lactate during 120 min after resuscitation, which was increased by lactate or pyruvate administration. This was associated with an increase in the mean neurological dysfunction score (66.7 ± 4.7, 79.0 ± 4.5 vs 57.7 ± 1.5 in Lactate, Pyruvate and Control group respectively) at 48 h after cardiac arrest. Oxamate and FC administration were associated with a lower lactate cerebral uptake after cardiac arrest and with an improvement of the neurological recovery (28.85 ± 9.4, 23.86 ± 6.2 vs 57.7 ± 1.5 in Oxa, FC and Control group respectively). After cardiac arrest, immediate isotonic lactate or pyruvate administration is deleterious. Pre-cardiac arrest LDH inhibition was potently neuroprotective in this setting.

Neuronal activity within the physiologic range stimulates lactate production that, via metabolic pathways or operating through an array of G-protein-coupled receptors, regulates intrinsic excitability and synaptic transmission. The recent discovery that lactate exerts a tight control of ion channels, neurotransmitter release, and synaptic plasticity-related intracellular signaling cascades opens up the possibility that lactate regulates synaptic potentiation at central synapses. Here, we demonstrate that extracellular lactate (1–2 mM) induces glutamatergic potentiation on the recurrent collateral synapses of hippocampal CA3 pyramidal cells. This potentiation is independent of lactate transport and further metabolism, but requires activation of NMDA receptors, postsynaptic calcium accumulation, and activation of a G-protein-coupled receptor sensitive to cholera toxin. Furthermore, perfusion of 3,5- dihydroxybenzoic acid, a lactate receptor agonist, mimics this form of synaptic potentiation. The transduction mechanism underlying this novel form of synaptic plasticity requires G-protein βγ subunits, inositol-1,4,5-trisphosphate 3-kinase, PKC, and CaMKII. Activation of these signaling cascades is compartmentalized in a synapse-specific manner since lactate does not induce potentiation at the mossy fiber synapses of CA3 pyramidal cells. Consistent with this synapse-specific potentiation, lactate increases the output discharge of CA3 neurons when recurrent collaterals are repeatedly activated during lactate perfusion. This study provides new insights into the cellular mechanisms by which lactate, acting via a membrane receptor, contributes to the memory formation process.

Background Neuropathic pain involves neuroinflammation and upregulation of glycolysis in the central nervous system. Unfortunately, few effective treatments are available for managing this type of pain. The overactivation of lactate dehydrogenase A (LDHA), an essential enzyme in glycolysis, can cause neuroinflammation and nociception. This study investigated the spinal role of LDHA in neuropathic pain. Method Using immunohistochemical analysis, nociceptive behavior, and western blotting, we evaluated the cellular mechanisms of intrathecal administration of LDHA inhibitors, including FX11 and oxamate, in chronic constriction injury (CCI)-induced neuropathic rats. Result FX11 and oxamate attenuated CCI-induced neuronal LDHA upregulation and nociceptive sensitization. Moreover, CCI-induced neuroinflammation, microglial polarization, and angiogenesis were attenuated by LDHA inhibitors. These inhibitors regulate the TANK binding kinase-1 (TBK1)/hypoxia-inducible factor 1 subunit alpha (HIF-1α) axis, crucial for controlling inflammation and new blood vessel growth. Additionally, CCI-induced nuclear LDHA translocation, as associated with oxidative stress resistance, was attenuated by LDHA inhibitors. Conclusion In conclusion, LDHA may be a potential therapeutic target for treating neuropathic pain by regulating neuroinflammation and angiogenesis.

Docetaxel (DOC) is one of the most effective chemotherapeutic agents against castration-resistant prostate cancer (CRPC). Despite an impressive initial clinical response, the majority of patients eventually develop resistance to DOC. In tumor metabolism, where tumors preferentially utilize anaerobic metabolism, lactate dehydrogenase (LDH) serves an important role. LDH controls the conversion of pyruvate to lactate, with LDH-A, one of the predominant isoforms of LDH, controlling this metabolic process. In the present study, the role of LDH-A in drug resistance of human prostate cancer (PC) was examined by analyzing 4 PC cell lines, including castration-providing strains PC3, DU145, LNCaP and LN-CSS (which is a hormone refractory cell line established from LNCaP). Sodium oxamate (SO) was used as a specific LDH-A inhibitor. Changes in the expression level of LDH-A were analyzed by western blotting. Cell growth and survival were evaluated with a WST-1 assay. Cell cycle progression and apoptotic inducibility were evaluated by flow cytometry using propidium iodide and Annexin V staining. LDH expression was strongly associated with DOC sensitivity in PC cells. SO inhibited growth of PC cells, which was considered to be caused by the inhibition of LDH-A expression. Synergistic cytotoxicity was observed by combining DOC and SO in LN-CSS cells, but not in LNCaP cells. This combination treatment induced additive cytotoxic effects in PC-3 and DU145 cells, caused cell cycle arrest in G2-M phase and increased the number of cells in the sub-G1 phase of cell cycle in LN-CSS cells. SO promoted DOC induced apoptosis in LN-CSS cells, which was partially caused by the inhibition of DOC-induced increase in LDH-A expression. The results strongly indicated that LDH-A serves an important role in DOC resistance in advanced PC cells and inhibition of LDH-A expression promotes susceptibility to DOC, particularly in CRPC cells. The present study may provide valuable information for developing targeted therapies for CRPC in the future.

Autophagy and the Warburg effect are two common pathways in pancreatic ductal adenocarcinoma (PDAC). To date, the reciprocal effects of these pathways have not yet been elucidated. Therefore, this study was designed to investigate the relationship between these factors in vitro and may provide therapeutic targets in the future. The Mia-Paca-2 and AsPc-1 cell lines were cultured under normal conditions. To achieve autophagy, starvation was induced by Hank’s balanced salt solution (HBSS), whereas autophagy was inhibited by 3-methyladenine (3-MA). The Warburg effect is mimicked by lactic acid, and the Warburg effect is inhibited by oxamate, the main inhibitor of lactate dehydrogenase. Cell viability was checked through the MTT assay method. Autophagy was checked via evaluation of Beclin-1 via western blotting. The amount of lactic acid was also measured with a lactate dehydrogenase (LDH) assay kit. The cells were incubated with different concentrations of 3-MA, lactic acid and oxamate. The viability of AsPc-1 cells decreased, and the IC 50 values were 1195 µM, 23.06 mM and 8.617 mM for 3-MA, lactic acid and oxamate, respectively. Similarly, the IC 50 values of Mia-Paca-2 were 873.9 µM, 35.9 mM and 26.74 mM for 3-MA, lactic acid and oxamate, respectively. Our data revealed that starvation increased the expression of the autophagy-related protein Beclin-1 ( P value < 0.05); however, 3-MA significantly reduced its expression ( P value < 0.05). In addition, lactic acid alone did not affect the expression level of Beclin-1 ( P value > 0.05), but oxamate treatment increased its expression ( P value < 0.05). We also showed that starvation reduced lactic acid levels, but an autophagy inhibitor, 3MA, significantly increased lactic acid production ( P value < 0.05). Our findings showed that lactic acid alone has no significant effect on autophagy and that oxamate induces autophagy, possibly because of caloric restriction. On the other hand, autophagy inhibits lactic acid production, whereas the inhibition of autophagy leads to increased lactic acid production. Graphical Abstract Autophagy and the Warburg effect are two common pathways in pancreatic ductal adenocarcinoma (PDAC). Starvation increased the expression of the autophagy-related protein Beclin-1; however, 3-MA significantly reduced its expression. In addition, lactic acid alone did not affect the expression level of Beclin-1, but oxamate treatment increased its expression. We also showed that starvation reduced lactic acid levels, but an autophagy inhibitor, 3MA, significantly increased lactic acid production. Hence, lactic acid alone has no significant effect on autophagy, and oxamate may induce autophagy because of caloric restriction. On the other hand, autophagy inhibits lactic acid production, whereas the inhibition of autophagy leads to increased lactic acid production.

Phenformin (phenethylbiguanide; an anti-diabetic agent) plus oxamate [lactate dehydrogenase (LDH) inhibitor] was tested as a potential anti-cancer therapeutic combination. In in vitro studies, phenformin was more potent than metformin, another biguanide, recently recognized to have anti-cancer effects, in promoting cancer cell death in the range of 25 times to 15 million times in various cancer cell lines. The anti-cancer effect of phenformin was related to complex I inhibition in the mitochondria and subsequent overproduction of reactive oxygen species (ROS). Addition of oxamate inhibited LDH activity and lactate production by cells, which is a major side effect of biguanides, and induced more rapid cancer cell death by decreasing ATP production and accelerating ROS production. Phenformin plus oxamate was more effective than phenformin combined with LDH knockdown. In a syngeneic mouse model, phenformin with oxamate increased tumor apoptosis, reduced tumor size and (18)F-fluorodeoxyglucose (FDG) uptake on positron emission tomography/computed tomography compared to control. We conclude that phenformin is more cytotoxic towards cancer cells than metformin. Furthermore, phenformin and oxamate have synergistic anti-cancer effects through simultaneous inhibition of complex I in the mitochondria and LDH in the cytosol, respectively.

Oxamate (OXA) is a pyruvate analogue that directly inhibits the lactate dehydrogenase (LDH)-catalyzed conversion process of pyruvate into lactate. Earlier and recent studies have shown elevated blood lactate levels among insulin-resistant and type 2 diabetes subjects and that blood lactate levels independently predicted the development of incident diabetes. To explore the potential of OXA in the treatment of diabetes, db/db mice were treated with OXA in vivo. Treatment of OXA (350-750 mg/kg of body weight) for 12 weeks was shown to decrease body weight gain and blood glucose and HbA1c levels and improve insulin secretion, the morphology of pancreatic islets, and insulin sensitivity in db/db mice. Meanwhile, OXA reduced the lactate production of adipose tissue and skeletal muscle and serum lactate levels and decreased serum levels of TG, FFA, CRP, IL-6, and TNF-α in db/db mice. The PCR array showed that OXA downregulated the expression of Tnf, Il6, leptin, Cxcr3, Map2k1, and Ikbkb, and upregulated the expression of Irs2, Nfkbia, and Pde3b in the skeletal muscle of db/db mice. Interestingly, LDH-A expression increased in the islet cells of db/db mice, and both treatment of OXA and pioglitazone decreased LDH-A expression, which might be related to the improvement of insulin secretion. Taken together, increased lactate production of adipose tissue and skeletal muscle may be at least partially responsible for insulin resistance and diabetes in db/db mice. OXA improved glycemic control and insulin sensitivity in db/db mice primarily via inhibition of tissue lactate production. Oxamic acid derivatives may be a potential drug for the treatment of type 2 diabetes.

Enhancement of glycolysis has been reported in tumor cells, and it is believed that this enhancement is important for maintaining the stemness of tumor cells and contributes to malignant phenotypes. Here, we investigated the effects of Oxamate, which inhibits glycolysis by blocking the conversion of pyruvate to lactate, on radiosensitivity and its molecular mechanisms in T98G glioblastoma cells. Oxamate significantly enhanced radiosensitivity by delaying DNA repair, as indicated by the persistence of γ-H2AX foci up to four days post-irradiation. Mechanistically, Oxamate suppressed the expression and phosphorylation of key DNA repair factors. Furthermore, Oxamate induced apoptosis and promoted cellular senescence, as evidenced by the accumulation of SA-β-gal and the upregulation of pS15-p53 and p21. In addition, Oxamate downregulated EGFR expression, reduced the levels of stem cell markers, and modulated epithelial–mesenchymal transition (EMT) markers, suggesting a potential suppression of EMT-related pathways. Together, these results demonstrate that Oxamate enhances radiosensitivity in glioblastoma cells through multiple mechanisms, including the inhibition of DNA repair, induction of apoptosis and senescence, and suppression of cancer stem cell properties and EMT. Our findings provide new insights into the potential use of Oxamate as a radiosensitizer and warrant further investigation of its clinical application in glioblastoma therapy.

ErbB2 has been shown to activate signaling molecules that may regulate glucose metabolism. However, there is no evidence reported to directly link ErbB2 to glycolysis, and the mechanism underlying ErbB2-enhanced glycolysis is poorly understood. In this study, we investigated the role and mechanism of ErbB2 in regulating glycolysis. We found that ErbB2-overexpressing cells possessed a significantly higher level of glycolysis when compared to the ErbB2-low-expressing cells, and the downregulation of ErbB2 markedly decreased glycolysis. Overexpression of ErbB2 increased the expression of glycolysis-regulating molecules lactate dehydrogenase A (LDH-A) and heat shock factor 1 (HSF1). ErbB2 activated HSF1, indicated by the increased HSF1 trimer formation, and promoted HSF1 protein synthesis. HSF1 bound to LDH-A promoter and the downregulation of HSF1 reduced the expression of LDH-A and subsequently decreased cancer cell glycolysis and growth. Moreover, the glycolysis inhibitors, 2-deoxyglucose and oxamate, selectively inhibited the growth of ErbB2-overexpressing cells. Taken together, this study shows that in human breast cancer cells, ErbB2 promotes glycolysis at least partially through the HSF1-mediated upregulation of LDH-A. This pathway may have a major role in regulating glucose metabolism in breast cancer cells. These novel findings have important implications for the design of new approaches to target ErbB2-overexpressing breast cancers.