Glycolysis

About: Glycolysis is a research topic. Over the lifetime, 10593 publications have been published within this topic receiving 507460 citations. The topic is also known as: GO:0006096 & glycolysis.

Double role for pyruvate kinase type M2 in the expansion of phosphometabolite pools found in tumor cells.

Abstract: As a common characteristic of tumor cells, as well as of normal proliferating cells in the G1-phase of cell cycle, one finds constitutive high levels of all the glycolytic metabolites arising between glucose 6-phosphate and phosphoenolpyruvate. Thus, it is that the phosphometabolites fructose 1,6-bisphosphate, ribose 5-P, P-ribose-PP, NAD, GTP, CTO, UTP, UDP-glucose, glycerol 3-P, glycerol phosphocholine and glycerol phosphoethanolamine are useful in the 31P-nuclear magnetic resonance (NMR) detection of solid tumors in animals and man. This expansion of phosphometabolites is achieved during tumor formation as a result of reductions in levels of enzymes degrading phosphometabolites, owing to the decline in the glycerol 3-P hydrogen shuttle, and as a consequence of alterations in the glycolytic isoenzyme equipment. Tumor cells typically express a particular isoenzyme of pyruvate kinase called type M2 (K) at high levels. This isoenzyme is subject to a complex regulation by amino acids, by fructose 1,6-bisphosphate, and by hormonal- and oncogene-dependent phosphorylation. Pyruvate kinase type M2 is a substrate for the oncogene encoded PP60v-src-tyrosine kinase. A drastic decrease in the affinity for its substrate phosphoenolpyruvate found after transformation by the src-oncogene can be explained as a consequence of the phosphorylation of pyruvate kinase in serine and tyrosine. These phosphorylations induce the breakdown of tetrameric pyruvate kinase to the trimeric and dimeric forms. Unlike the tetrameric form, the dimeric form as a low affinity for phosphoenolpyruvate. Partial inactivation of pyruvate kinase and enolase on the one hand, and a hyperactivation of hexokinase and phosphofructokinase on the other hand, lead to an expansion of all metabolites. Only when these metabolites attain high levels, thereby assuring a sufficient supply of metabolites for RNA, DNA, lipid, and complex carbohydrate synthesis, can cell proliferation proceed. This accumulation of metabolites in the G1-phase cells has been termed a "metabolic budget system" because it senses not only the actual nutrient levels, but also the supply over a period of time. Monoclonal antibodies specific for the dimeric form of pyruvate kinase type M2 can be used for the immunohistological detection of tumor cells. The amount of the dimeric form in tumor cells closely correlates with the degree of malignancy and can be used for a nonspecific detection of tumors based on assays performed with patient's plasma.

Pyruvate Dehydrogenase Kinase 1 Participates in Macrophage Polarization via Regulating Glucose Metabolism

Abstract: The M1 and M2 polarized phenotypes dictate distinctive roles for macrophages as they participate in inflammatory disorders. There has been growing interest in the role of cellular metabolism in macrophage polarization. However, it is currently unclear whether different aspects of a specific metabolic program coordinately regulate this cellular process. In this study, we found that pyruvate dehydrogenase kinase 1 (PDK1), a key regulatory enzyme in glucose metabolism, plays an important role in the differential activation of macrophages. Knockdown of PDK1 diminished M1, whereas it enhanced M2 activation of macrophages. Mechanistically, PDK1 knockdown led to diminished aerobic glycolysis in M1 macrophages, which likely accounts for the attenuated inflammatory response in these cells. Furthermore, we found that mitochondrial respiration is enhanced during and required by the early activation of M2 macrophages. Suppression of glucose oxidation, but not that of fatty acids, inhibits this process. Consistent with its inhibitory role in early M2 activation, knockdown of PDK1 enhanced mitochondrial respiration in macrophages. Our data suggest that two arms of the glucose metabolism synergistically regulate the differential activation of macrophages. Our findings also highlight the central role of PDK1 in this event via controlling glycolysis and glucose oxidation.

Upregulation of lactate dehydrogenase A by ErbB2 through heat shock factor 1 promotes breast cancer cell glycolysis and growth

Abstract: 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.

Expression of transketolase TKTL1 predicts colon and urothelial cancer patient survival: Warburg effect reinterpreted.

Abstract: Tumours ferment glucose to lactate even in the presence of oxygen (aerobic glycolysis; Warburg effect). The pentose phosphate pathway (PPP) allows glucose conversion to ribose for nucleic acid synthesis and glucose degradation to lactate. The nonoxidative part of the PPP is controlled by transketolase enzyme reactions. We have detected upregulation of a mutated transketolase transcript (TKTL1) in human malignancies, whereas transketolase (TKT) and transketolase-like-2 (TKTL2) transcripts were not upregulated. Strong TKTL1 protein expression was correlated to invasive colon and urothelial tumours and to poor patients outcome. TKTL1 encodes a transketolase with unusual enzymatic properties, which are likely to be caused by the internal deletion of conserved residues. We propose that TKTL1 upregulation in tumours leads to enhanced, oxygen-independent glucose usage and a lactate-based matrix degradation. As inhibition of transketolase enzyme reactions suppresses tumour growth and metastasis, TKTL1 could be the relevant target for novel anti-transketolase cancer therapies. We suggest an individualised cancer therapy based on the determination of metabolic changes in tumours that might enable the targeted inhibition of invasion and metastasis.