Hexokinase 2 is a Key Mediator of Aerobic Glycolysis Promoting Tumour Growth in Glioblastoma Multiforme

Wolf, Amparo

23 February 2011

Proliferating tissues, including embryonic and tumour tissues, preferentially employ aerobic glycolysis to support cell growth. This reliance on glycolysis even in the presence of oxygen, referred to as the “Warburg Effect”, may confer a proliferative, survival and invasive advantage and be exploited therapeutically. In this thesis, we demonstrate that the glycolytic enzyme Hexokinase 2 (HK2) is crucial for the “Warburg Effect” in human Glioblastoma Multiforme (GBM), the most common and therapeutically resistant malignant brain tumour. In contrast to normal brain and low-grade gliomas, GBMs exhibited a marked increase in HK2 expression, but not HK1, particularly in perinecrotic, hypoxic regions and its expression predicted poor overall survival of GBM patients. Stable loss of HK2 in GBM cells restored oxidative phosphorylation (OXPHOS)-mediated glucose metabolism, with increased oxygen consumption and decreased lactic acid production, an effect not seen with loss of glycolytic enzymes HK1 or PKM2. Furthermore, HK2 depletion resulted in decreased proliferation in vitro and in vivo and increased sensitivity to apoptotic inducers such as radiation and chemotherapy, both common adjuvant therapies of GBMs. Intracranial xenografts of GBM cells with reduced HK2 demonstrated significantly increased survival with decreased proliferation and angiogenesis yet enhanced invasiveness. In contrast, exogenous HK2 expression in GBM cells promoted proliferation, therapeutic resistance and intracranial growth. This was dependent partly on the PI3K/AKT dependent translocation of HK2 to the mitochondrial membrane. Stable loss of glycolytic enzymes HK2, HK1 and PKM2 reduced GBM proliferation but differentially altered the PI3K/AKT/mTOR and AMPK signaling pathways, the extent to which may influence whether a cell preferentially undergoes autophagy or apoptosis as the primary mode of cell death. Collectively, targeting enzymes employed by the tumour to modulate its energy metabolism, such as HK2 in GBMs, may favourably alter its therapeutic sensitivity to radiation and both classical and novel chemotherapeutic agents.

Glioblastoma Multiforme

aerobic glycolysis

Hexokinase 2

0307

Hexokinase 2 is a Key Mediator of Aerobic Glycolysis Promoting Tumour Growth in Glioblastoma Multiforme

Wolf, Amparo

23 February 2011

Proliferating tissues, including embryonic and tumour tissues, preferentially employ aerobic glycolysis to support cell growth. This reliance on glycolysis even in the presence of oxygen, referred to as the “Warburg Effect”, may confer a proliferative, survival and invasive advantage and be exploited therapeutically. In this thesis, we demonstrate that the glycolytic enzyme Hexokinase 2 (HK2) is crucial for the “Warburg Effect” in human Glioblastoma Multiforme (GBM), the most common and therapeutically resistant malignant brain tumour. In contrast to normal brain and low-grade gliomas, GBMs exhibited a marked increase in HK2 expression, but not HK1, particularly in perinecrotic, hypoxic regions and its expression predicted poor overall survival of GBM patients. Stable loss of HK2 in GBM cells restored oxidative phosphorylation (OXPHOS)-mediated glucose metabolism, with increased oxygen consumption and decreased lactic acid production, an effect not seen with loss of glycolytic enzymes HK1 or PKM2. Furthermore, HK2 depletion resulted in decreased proliferation in vitro and in vivo and increased sensitivity to apoptotic inducers such as radiation and chemotherapy, both common adjuvant therapies of GBMs. Intracranial xenografts of GBM cells with reduced HK2 demonstrated significantly increased survival with decreased proliferation and angiogenesis yet enhanced invasiveness. In contrast, exogenous HK2 expression in GBM cells promoted proliferation, therapeutic resistance and intracranial growth. This was dependent partly on the PI3K/AKT dependent translocation of HK2 to the mitochondrial membrane. Stable loss of glycolytic enzymes HK2, HK1 and PKM2 reduced GBM proliferation but differentially altered the PI3K/AKT/mTOR and AMPK signaling pathways, the extent to which may influence whether a cell preferentially undergoes autophagy or apoptosis as the primary mode of cell death. Collectively, targeting enzymes employed by the tumour to modulate its energy metabolism, such as HK2 in GBMs, may favourably alter its therapeutic sensitivity to radiation and both classical and novel chemotherapeutic agents.

Glioblastoma Multiforme

aerobic glycolysis

Hexokinase 2

0307

Lactate and Immunosuppression in Sepsis

Nolt, Benjamin, Tu, Fei, Wang, Xiaohui, Ha, Tuanzhu, Winter, Randi, Williams, David L., Li, Chuanfu

01 February 2018

Serum lactate levels are traditionally interpreted as a marker of tissue hypoxia and often used clinically as an indicator of severity and outcome of sepsis/septic shock. Interestingly, recent studies involving the effects of tumor-derived lactate suggest that lactate itself may have an immunosuppressive effect in its local environment. This finding adds to the recent advances in immunometabolism that shed light on the importance of metabolism and metabolic intermediates in the regulation of innate immune and inflammatory responses in sepsis. In this article, we summarize recent studies, showing that the activation of immune cells requires aerobic glycolytic metabolism and that lactate produced by aerobic glycolysis may play an immunosuppressive role in sepsis.

aerobic glycolysis

immunosuppression

lactate

sepsis/septic shock

Surgery

The Role of Fatty Acid Synthase Over-expression in Human Breast Cancer

Hopperton, Kathryn

20 November 2012

Fatty acid synthase (FAS) is over-expressed in many human cancers and its activity is required for cancer cell survival. To understand why FAS is over-expressed, we compared in breast cancer cells the utilization of fatty acids synthesized endogenously by FAS to those supplied exogenously in the culture medium. We found that endogenously synthesized fatty acids are esterified to the same lipid and phospholipid classes in the same proportions as those derived exogenously and that some endogenous fatty acids are excreted. Thus, FAS over-expression in cancer does not fulfill a specific requirement for endogenously synthesized fatty acids. We next investigated whether lipogenic activity mediated by FAS was, instead, involved in the maintenance of high glycolytic activity in cancer cells. By culturing breast cancer and non-cancer cells in anoxic conditions, we increased glycolysis 2-3 fold but observed no concomitant increase in lipogenesis. More research is needed to understand why FAS is over-expressed in cancer.

fatty acid synthase

breast cancer

cancer metabolism

aerobic glycolysis

0570

0992

Structural and metabolic studies on normal and pathological bone

Dodds, R. A.

January 1985

Bone is refractory to most conventional biochemical Procedures. However because it is now possible to cut sections (e. g. lopm) of fresh, undemineralized adult bone, this tissue can be analyzed by suitably modified methods of quantitative cytochemistry. A new substrate for assaying hydroxyacyl dehydrogenase activity demonstrated that bone cells may use fatty acids as a major source of energy: detailed analysis of the activities of key enzymes indicated that the paradox of ‘aerobic glycolysis’ of bone could be explained by fatty acid oxidation satisfying the requirements of the Krebs' cycle and directing the conversion of pyruvate to lactate The influence of glucose 6-phosphate dehydrogenase (G6PD) activity in aerobic glycolysis has been considered. The inverse relationships between this activity and that of Na-K-ATPase led to the development of a new method for the latter, based on a new concept in cytochemistry ('hidden-capture' procedure). A major feature of fracture-healing is increased periosteal G6PD activity. The association with the vitamin K cycle has been investigated by feeding rats with dicoumarol which not only inhibited bone-formation but also G6PD activity. The stimulation of this activity in fracture-healing has been linked with ornithine decarboxylase (ODC) activity, for which a new method has been developed. Rats deficient in pyridoxal phosphate (cofactor for ODC) had decreased G6PD responses and also appeared to become osteoporotic. Studies on osteoporotic fractures in the human showed the presence of relatively large apatite crystals close to the fracture-site, and disorganized glycosaminoglycans (demonstrated by the new method of ‘induced birefringence’).

612

The Role of Fatty Acid Synthase Over-expression in Human Breast Cancer

Hopperton, Kathryn

20 November 2012

Fatty acid synthase (FAS) is over-expressed in many human cancers and its activity is required for cancer cell survival. To understand why FAS is over-expressed, we compared in breast cancer cells the utilization of fatty acids synthesized endogenously by FAS to those supplied exogenously in the culture medium. We found that endogenously synthesized fatty acids are esterified to the same lipid and phospholipid classes in the same proportions as those derived exogenously and that some endogenous fatty acids are excreted. Thus, FAS over-expression in cancer does not fulfill a specific requirement for endogenously synthesized fatty acids. We next investigated whether lipogenic activity mediated by FAS was, instead, involved in the maintenance of high glycolytic activity in cancer cells. By culturing breast cancer and non-cancer cells in anoxic conditions, we increased glycolysis 2-3 fold but observed no concomitant increase in lipogenesis. More research is needed to understand why FAS is over-expressed in cancer.

fatty acid synthase

breast cancer

cancer metabolism

aerobic glycolysis

0570

0992

Úloha mitochondriálního metabolismu v iniciaci a adaptaci buněk na hypoxii. / The role of mitochondrial metabolism in initiation and adaptation to hypoxic conditions.

Rohlenová, Terezie

January 2013

We can meet pathological hypoxia in the cases of hearth attack, ischemic stroke, but also during tumor invasion, thanks to insufficient angiogenesis. The activation of HIF- 1 factor during hypoxic conditions is crucial for the cell survival. This factor modulates energetic metabolism in favor of fast progressing glycolysis (with the contribution of glutaminolysis) which provides to cell enough ATP and "building blocks", while suppressing Krebs cycle and respiration because of shortage of oxygen. The thesis studies energetic metabolism of HepG2 cells (derived from liver carcinoma) which are cultivated in the media with various energetic substrates, i. e. glucose or galactose (always together with glutamine and pyruvate) under the hypoxic conditions (5% O2). HepG2 cells use particularly oxidative metabolism for ATP and "building blocks" production under the normoxic conditions while hypoxic environment causes metabolic shift in glycemic condition. Interestingly, cells cultured in galactose (glutamine) didn't switch the energy metabolism from oxidative to aerobic glycolysis such as cells cultivated in glucose, although HIF-1 factor was stabilized. We found that enhanced activity and integrity of mitochondria, enhanced maximal capacity and reserve capacity of respiration chain correlates with...

Regulation of Cellular Bioenergetics by Na/K-ATPase

Cui, Xiaoyu

January 2016

No description available.

Biology

Biomedical Research

Na-K-ATPase

Src

Bioenergetics

Na-K-ATPase-Src Interaction

Aerobic Glycolysis

Mitochondria Respiration

Modulation of GLO1 expression affects malignant properties of cells

Hutschenreuther, Antje, Bigl, Marina, Hemdan, Nasr Y. A., Debebe, Tewodros, Gaunitz, Frank, Birkenmeier, Gerd

25 January 2017

The energy metabolism of most tumor cells relies on aerobic glycolysis (Warburg effect) characterized by an increased glycolytic flux that is accompanied by the increased formation of the cytotoxic metabolite methylglyoxal (MGO). Consequently, the rate of detoxification of this reactive glycolytic byproduct needs to be increased in order to prevent deleterious effects to the cells. This is brought about by an increased expression of glyoxalase 1 (GLO1) that is the rate-limiting enzyme of the MGO-detoxifying glyoxalase system. Here, we overexpressed GLO1 in HEK 293 cells and silenced it in MCF-7 cells using shRNA. Tumor-related properties of wild type and transformed cells were compared and key glycolytic enzyme activities assessed. Furthermore, the cells were subjected to hypoxic conditions to analyze the impact on cell proliferation and enzyme activities. Our results demonstrate that knockdown of GLO1 in the cancer cells significantly reduced tumor-associated properties such as migration and proliferation, whereas no functional alterations where found by overexpression of GLO1 in HEK 293 cells. In contrast, hypoxia caused inhibition of cell growth of all cells except of those overexpressing GLO1. Altogether, we conclude that GLO1 on one hand is crucial to maintaining tumor characteristics of malignant cells, and, on the other hand, supports malignant transformation of cells in a hypoxic environment when overexpressed.

Glyoxalase

aerobe Glykolyse

maligne Transformation

Methylgloyoxal

glyoxalase 1

MCF-7 cells

HEK 293 cell

aerobic glycolysis

malignant transformation

methylglyoxal

ddc:601

Modulation of GLO1 expression affects malignant properties of cells

Hutschenreuther, Antje, Bigl, Marina, Hemdan, Nasr Y. A., Debebe, Tewodros, Gaunitz, Frank, Birkenmeier, Gerd

January 2016

The energy metabolism of most tumor cells relies on aerobic glycolysis (Warburg effect) characterized by an increased glycolytic flux that is accompanied by the increased formation of the cytotoxic metabolite methylglyoxal (MGO). Consequently, the rate of detoxification of this reactive glycolytic byproduct needs to be increased in order to prevent deleterious effects to the cells. This is brought about by an increased expression of glyoxalase 1 (GLO1) that is the rate-limiting enzyme of the MGO-detoxifying glyoxalase system. Here, we overexpressed GLO1 in HEK 293 cells and silenced it in MCF-7 cells using shRNA. Tumor-related properties of wild type and transformed cells were compared and key glycolytic enzyme activities assessed. Furthermore, the cells were subjected to hypoxic conditions to analyze the impact on cell proliferation and enzyme activities. Our results demonstrate that knockdown of GLO1 in the cancer cells significantly reduced tumor-associated properties such as migration and proliferation, whereas no functional alterations where found by overexpression of GLO1 in HEK 293 cells. In contrast, hypoxia caused inhibition of cell growth of all cells except of those overexpressing GLO1. Altogether, we conclude that GLO1 on one hand is crucial to maintaining tumor characteristics of malignant cells, and, on the other hand, supports malignant transformation of cells in a hypoxic environment when overexpressed.

info:eu-repo/classification/ddc/601

ddc:601