Blocking Lipid Synthesis Overcomes Tumor Regrowth and Metastasis after Antiangiogenic Therapy Withdrawal

Sounni, Nor Eddine; Cimino, Jonathan; Blacher, Silvia; Primac, Irina; Truong, Alice; Mazzucchelli, Gabriel; Paye, Alexandra; Calligaris, David; Debois, Delphine; Tullio, Pascal De; Mari, Bernard; Pauw, Edwin De; Noël, Agnès

doi:10.1016/j.cmet.2014.05.022

Cited by 142 publications

(123 citation statements)

References 26 publications

(33 reference statements)

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“…95,96 Given the unique role of MAGL in providing lipolytic sources of free fatty acids for the synthesis of oncogenic signaling lipids, CSCs might co-opt lipolytic enzymes such as MAGL to translate their lipogenic state of stem cells into an array of protumorigenic signals. The recent discovery that cancer adaptation to antiangiogenic treatments, which generate hypoxic and nutrient-starved tumor microenvironments that suppress cell cycle progression but enrich non-proliferating CSC, [97][98][99][100][101][102][103] involves a significant upregulation of lipid synthesis that fuels tumor regrowth and metastasis after angiogenic therapy withdrawal, 104 strongly supports the notion that key enzymes involved in lipid metabolism such as FASN could play key roles in the reprogramming of CSC cellular states.…”

Section: Metabolism and Cancer Stemness: Lessons From Ips Cellsmentioning

confidence: 80%

Metabolic control of cancer cell stemness: Lessons from iPS cells

Menendez

2015

Cell Cycle

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Section: Metabolism and Cancer Stemness: Lessons From Ips Cellsmentioning

confidence: 80%

Metabolic control of cancer cell stemness: Lessons from iPS cells

Menendez

2015

Cell Cycle

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“…In vitro, in hi bi tion of ACL and FAS can de crease can cer cell mi gra tion [196], whereas fatty acid ex po sure can pro mote mi gra tion and in va sion [197]. In vivo, FAS si lenc ing or in hi bi tion with Orli s tat was re ported to de crease tu mor re growth and metasta tic bur den fol low ing with drawal of So rafenib or Suni tinib, re lapses and metas tases be ing highly de pen dent on lipid syn the sis fol low ing an tian gio genic ther a pies [7]. In col orec tal tu mor mod els, si lenc ing FAS de creased liver metas ta sis [196].…”

Section: Metabolic Contribution To Cancer Metastasismentioning

confidence: 99%

“…This over all com plex ity re sults in the de vel op ment of dif fer ent meta bolic adap ta tions, such as meta bolic sym bio sis [5,6], re lated to a co op er a tion be tween can cer cells with dif fer ent meta bolic needs and adap ta tion to lim ited per fu sion and aci do sis [7,8]. This meta bolic het ero gene ity is also mir rored by the bi o log i cal het ero gene ity of tu mors, where cells will have di verse meta bolic re quire ments ac cord ing to the spe cific bi o log i cal ac tiv ity oc cur ring in that par tic u lar area, e.g.…”

Section: Introductionmentioning

confidence: 99%

Cancer metabolism in space and time: Beyond the Warburg effect

Danhier

Bański

Payen

et al. 2017

Biochimica et Biophysica Acta (BBA) - Bioenergetics

162

134

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Available online xxx Keywords:Can cer Me tab o lism Mi to chon dria Het ero gene ity Metas ta sis A B S T R A C T Al tered me tab o lism in can cer cells is piv otal for tu mor growth, most no tably by pro vid ing en ergy, re duc ing equiv a lents and build ing blocks while sev eral metabo lites ex ert a sig nal ing func tion pro mot ing tu mor growth and pro gres sion. A can cer tis sue can not be sim ply re duced to a bulk of pro lif er at ing cells. Tu mors are in deed com plex and dy namic struc tures where sin gle cells can het ero ge neously per form var i ous bi o log i cal ac tiv i ties with dif fer ent meta bolic re quire ments. Be cause tu mors are com posed of dif fer ent types of cells with meta bolic ac tiv i ties af fected by dif fer ent spa tial and tem po ral con texts, it is im por tant to ad dress me tab o lism tak ing into ac count cel lu lar and bi o log i cal het ero gene ity. In this re view, we de scribe this het ero gene ity also in meta bolic fluxes, thus show ing the rel a tive con tri bu tion of dif fer ent meta bolic ac tiv i ties to tu mor pro gres sion ac cord ing to the cel lu lar con text. This ar ti cle is part of a Spe cial Is sue en ti tled Res pi ra tory com plex I, edited by Giuseppe Gas parre, Ro drigue Rossig nol and Pierre Son veaux. Abbreviations: ACL, ATP cit rate lyase; AMPK, adeno sine monophos phate ki nase; ARG1, L argi nine me tab o liz ing en zyme arginase 1; BCAA, branched chain amino acid; Bcl2, B cell lym phoma 2; CAF, can cer as so ci ated fi brob last; CIC, can cer ini ti at ing cell; COX2, cy tochrome ox i dase; CSC, can cer stem cell; CREB, cyclic adeno sine monophos phate re sponse el e ment bind ing pro tein; DEC1, dif fer en tially ex pressed in chon dro cytes 1; EMT, ep ithe lial to mes enchy mal tran si tion; FAK, fo cal ad he sion ki nase; FAS, fatty acid syn thase; FBP, fruc tose 1,6 bis pho s phate; FDG PET, [ F] flu o rodeoxyglu cose positron emis sion to mog ra phy; GAPDH, glyc er alde hyde 3 phos phate de hy dro ge nase; HIF 1, hy poxia ac ti vated fac tor 1; HK2, hex ok i nase 2; HMGB1, high mo bil ity group box 1; HU VEC, hu man um bil i cal vein en dothe lial cell; IFN γ, in ter feron gamma; LDH, lac tate de hy dro ge nase; MEF, murine em bry onic fi brob last; MET, mes enchy mal to ep ithe lial tran si tion; MRI, mag netic res o nance imag ing; mTORC1, mam malian tar get of ra pamycin com plex 1; NSCLC, non small cell lung can cer; OX PHOS, ox ida tive phos pho ry la tion; PDAC, pan cre atic duc tal ade no car ci noma; PHD, pro lyl hy drox y lase; pHe, ex tra cel lu lar pH; pHi, in tra cel lu lar pH; PK, pyru vate ki nase; PPP, pen tose phos phate path way; REDD1, reg u lated in de vel op ment and DNA dam age re sponse 1; RhoA, Ras ho molog gene fam ily, mem ber A; ROS, re ac tive oxy gen species; SASP, senes cence as so ci ated se cre tory phe no type; SCO2, syn the sis of cy tochrome ox i dase 2; SGK 1, serum and glu co cor ti coid reg u lated ki nase 1 Sirt1, sir tuin 1; TAM, tu mor as so ci ated macrophage; TIGAR, TP53 in duced gly col y ...

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“…Sounni et al [19] found an increased lipid synthesis under these conditions, which, when blocked pharmacologically, inhibited the regrowth. This again strengthens the suggestion that inhibition of lipogenesis may be a way to tumor reduction.…”

Section: Introductionmentioning

confidence: 95%

Metabolism: A New Frontier in Cancer Research

Rodrigues¹

2017

JCPCR

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Submit Manuscript | http://medcraveonline.com development and can be used by the pharmaceutical industry to generate novel drugs. This is validated by the approval of Agas and Celgene's enasidenib by the FDA. This drug modulates the metabolism and is used as a medication against acute myelogenous leukemia. Enasidenib is an inhibitor of the mutated isocitrate dehydrogenase (IDH2), one of the main enzymes of the citric acid cycle (also known as Krebs cycle), a central pathway which converts molecules coming from all 3 main catabolic pathways into intermediate metabolites that finally fuel the respiratory chain, the main energy providing process in cells. IDH enzymes usually metabolize isocitrate into α-ketoglutarate, a crucial step in the citric cycle. When mutated in some cancers, this enzyme starts producing 2-hydroxyglutarate, a metabolite that causes cell differentiation defects and impairs histone demethylation [3]. While this approval highlights the promising role of anticancer drugs modulating metabolism, researchers have struggled to find other therapeutically useful targets in metabolic pathways. Tumor MetabolismCell metabolism as well as cancer development and growth is complex. The intermodulation between metabolic pathways and the plasticity of these routes, plus the capacity of tumor cells to adapt are factors that slow down the advances in their understanding. Factors such as poor oxygenation, acidity and deprivation of nutrients, which normally cause cell death, are rapidly converted into promoters by tumor cells [4,5].The reprogramming of the glucose metabolism is a good example for this flexibility. Tumor cells typically exhibit a high uptake of glucose and are mainly metabolizing anaerobically. For many years, the explanation for that was attributed to the lack of oxygen, once the proliferation rate of tumor exceeds the angiogenesis. However, Otto Warburg (1927) verified that even in the presence of oxygen, tumor cells prefer to metabolize glucose into lactic acid. This process is known as anaerobic glycolysis and has been extensively studied throughout the years, but is still poorly understood [6,7]. Recent studies demonstrated that tumor cells prefer the anaerobic metabolism because it more efficiently produces energy and basic metabolites for protein biosynthesis as compared to aerobic metabolism [8,9]. These findings were confirmed in a study showing that one of the main molecule that control glycolysis and the anaerobic metabolism, the glucosetransporter (GLUT), was up regulated in breast tumor cell lines [10].To corroborate the complexity of cancer metabolism, it has been shown recently that some tumors also use the mitochondrial oxidative phosphorylations [11,12]. Growing evidence of the importance of the glucose metabolism for tumor development and the need of new therapeutic targets, lead to the application of drugs inhibiting the glycolytic pathway as potential approach. Metformin for example, a drug already widely used in diabetes treatment, decreases glucose consumption and, conseque...

show abstract

Blocking Lipid Synthesis Overcomes Tumor Regrowth and Metastasis after Antiangiogenic Therapy Withdrawal

Cited by 142 publications

References 26 publications

Metabolic control of cancer cell stemness: Lessons from iPS cells

Metabolic control of cancer cell stemness: Lessons from iPS cells

Cancer metabolism in space and time: Beyond the Warburg effect

Metabolism: A New Frontier in Cancer Research

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