Stromal-epithelial metabolic coupling in cancer: integrating autophagy and metabolism in the tumor microenvironment.

Cancer cells do not exist as pure homogeneous populations in vivo. Instead they are embedded in "cancer cell nests" that are surrounded by stromal cells, especially cancer associated fibroblasts. Thus, it is not unreasonable to suspect that stromal fibroblasts could influence the metabolism of adjacent cancer cells, and visa versa. In accordance with this idea, we have recently proposed that the Warburg effect in cancer cells may be due to culturing cancer cells by themselves, out of their normal stromal context or tumor microenvironment. In fact, when cancer cells are co-cultured with fibroblasts, then cancer cells increase their mitochondrial mass, while fibroblasts lose their mitochondria. An in depth analysis of this phenomenon reveals that aggressive cancer cells are "parasites" that use oxidative stress as a "weapon" to extract nutrients from surrounding stromal cells. Oxidative stress in fibroblasts induces the autophagic destruction of mitochondria, by mitophagy. Then, stromal cells are forced to undergo aerobic glycolysis, and produce energy-rich nutrients (such as lactate and ketones) to "feed" cancer cells. This mechanism would allow cancer cells to seed anywhere, without blood vessels as a food source, as they could simply induce oxidative stress wherever they go, explaining how cancer cells survive during metastasis. We suggest that stromal catabolism, via autophagy and mitophagy, fuels the anabolic growth of tumor cells, promoting tumor progression and metastasis. We have previously termed this new paradigm "The Autophagic Tumor Stroma Model of Cancer Metabolism", or the "Reverse Warburg Effect". We also discuss how glutamine addiction (glutaminolysis) in cancer cells fits well with this new model, by promoting oxidative mitochondrial metabolism in aggressive cancer cells.

[1]  B. Cheson,et al.  Positron-emission tomography and assessment of cancer therapy. , 2006, The New England journal of medicine.

[2]  M. Colombo,et al.  The autophagic pathway is a key component in the lysosomal dependent entry of Trypanosoma cruzi into the host cell , 2009, Autophagy.

[3]  Julien Verrax,et al.  Targeting lactate-fueled respiration selectively kills hypoxic tumor cells in mice. , 2008, The Journal of clinical investigation.

[4]  K. Vousden,et al.  Modulation of intracellular ROS levels by TIGAR controls autophagy , 2009, The EMBO journal.

[5]  F. Sotgia,et al.  Loss of stromal caveolin-1 expression predicts poor clinical outcome in triple negative and basal-like breast cancers , 2010, Cancer biology & therapy.

[6]  K. Bouchelouche,et al.  Positron emission tomography and positron emission tomography/computerized tomography of urological malignancies: an update review. , 2008, The Journal of urology.

[7]  Chenguang Wang,et al.  Oxidative stress in cancer associated fibroblasts drives tumor-stroma co-evolution , 2010, Cell cycle.

[8]  Judy Lucas,et al.  Ammonia Derived from Glutaminolysis Is a Diffusible Regulator of Autophagy , 2010, Science Signaling.

[9]  R. Motzer,et al.  Efficacy of everolimus in advanced renal cell carcinoma: a double-blind, randomised, placebo-controlled phase III trial , 2008, The Lancet.

[10]  David McDermott,et al.  Temsirolimus, interferon alfa, or both for advanced renal-cell carcinoma. , 2007, The New England journal of medicine.

[11]  J. Pinski,et al.  Diagnostic role of [F-18]-FDG positron emission tomography in restaging renal cell carcinoma. , 2003, Clinical nephrology.

[12]  P. Fortina,et al.  The reverse Warburg effect: Aerobic glycolysis in cancer associated fibroblasts and the tumor stroma , 2009, Cell cycle.

[13]  C. Colak,et al.  Malondialdehyde, glutathione, and nitric oxide levels in Toxoplasma gondii seropositive patients. , 2008, The Korean journal of parasitology.

[14]  Guido Kroemer,et al.  Ammonia: A Diffusible Factor Released by Proliferating Cells That Induces Autophagy , 2010, Science Signaling.

[15]  P. Fortina,et al.  Loss of stromal caveolin-1 leads to oxidative stress, mimics hypoxia and drives inflammation in the tumor microenvironment, conferring the “reverse Warburg effect”: A transcriptional informatics analysis with validation , 2010, Cell cycle.

[16]  B. Andrade,et al.  Plasma Superoxide Dismutase-1 as a Surrogate Marker of Vivax Malaria Severity , 2010, PLoS neglected tropical diseases.

[17]  D. Green,et al.  p53 and Metabolism: Inside the TIGAR , 2006, Cell.

[18]  O. Warburg On the origin of cancer cells. , 1956, Science.

[19]  S. Côrte‐Real,et al.  Plasmodium falciparum: erythrocytic stages die by autophagic-like cell death under drug pressure. , 2008, Experimental parasitology.

[20]  Jie Zhou,et al.  Autophagy in cancer associated fibroblasts promotes tumor cell survival , 2010, Cell cycle.

[21]  G. Giménez-Gallego,et al.  Effect of ammonium ions on the aerobic glycolysis in Ehrlich ascites tumor cells. , 1981, Biochimie.

[22]  C. Dang,et al.  MYC-Induced Cancer Cell Energy Metabolism and Therapeutic Opportunities , 2009, Clinical Cancer Research.

[23]  F. Sotgia,et al.  An absence of stromal caveolin-1 expression predicts early tumor recurrence and poor clinical outcome in human breast cancers. , 2009, The American journal of pathology.

[24]  A. Tsirigos,et al.  Transcriptional evidence for the "Reverse Warburg Effect" in human breast cancer tumor stroma and metastasis: Similarities with oxidative stress, inflammation, Alzheimer's disease, and "Neuron-Glia Metabolic Coupling" , 2010, Aging.

[25]  M. Parsons,et al.  3-Methyladenine blocks Toxoplasma gondii division prior to centrosome replication. , 2010, Molecular and biochemical parasitology.

[26]  A. Byars,et al.  Everolimus for subependymal giant-cell astrocytomas in tuberous sclerosis. , 2010, The New England journal of medicine.

[27]  R. Abraham,et al.  Glutaminolysis yields a metabolic by-product that stimulates autophagy , 2010, Autophagy.

[28]  F. Sotgia,et al.  Clinical and Translational Implications for the Caveolin Gene Family: Lessons from Mouse Models and Human Genetic Disorders , 2009, Laboratory Investigation.

[29]  Hua Li,et al.  Structural and Biochemical Studies of TIGAR (TP53-induced Glycolysis and Apoptosis Regulator)* , 2009, Journal of Biological Chemistry.

[30]  P. Leedman,et al.  Contribution by different fuels and metabolic pathways to the total ATP turnover of proliferating MCF-7 breast cancer cells. , 2002, The Biochemical journal.

[31]  C. Restall,et al.  Stromal cell expression of caveolin-1 predicts outcome in breast cancer. , 2009, The American journal of pathology.

[32]  C. L. Tang,et al.  False positive F-18 fluorodeoxyglucose combined PET/CT scans from suture granuloma and chronic inflammation: report of two cases and review of literature. , 2005, Annals of the Academy of Medicine, Singapore.

[33]  M. Lisanti,et al.  Caveolins, a Family of Scaffolding Proteins for Organizing “Preassembled Signaling Complexes” at the Plasma Membrane* , 1998, The Journal of Biological Chemistry.

[34]  Aristotelis Tsirigos,et al.  The autophagic tumor stroma model of cancer , 2010, Cell cycle.

[35]  H. Elsheikha,et al.  Oxidative stress and immune-suppression in Toxoplasma gondii positive blood donors: implications for safe blood transfusion. , 2009, Journal of the Egyptian Society of Parasitology.

[36]  R. Balaban,et al.  Studies on the relationship between glycolysis and (Na+ + K+)-ATPase in cultured cells. , 1984, Biochimica et biophysica acta.

[37]  M. Müller,et al.  ATP-producing and consuming processes of Ehrlich mouse ascites tumor cells in proliferating and resting phases. , 1991, Experimental cell research.

[38]  F. Sotgia,et al.  An absence of stromal caveolin-1 is associated with advanced prostate cancer, metastatic disease spread and epithelial Akt activation , 2009, Cell cycle.

[39]  P. Maity,et al.  Malarial infection develops mitochondrial pathology and mitochondrial oxidative stress to promote hepatocyte apoptosis. , 2009, Free radical biology & medicine.

[40]  Eyal Gottlieb,et al.  TIGAR, a p53-Inducible Regulator of Glycolysis and Apoptosis , 2006, Cell.

[41]  H. Rui,et al.  Stromal caveolin-1 levels predict early DCIS progression to invasive breast cancer , 2009, Cancer biology & therapy.

[42]  N. Garg,et al.  Phenyl-alpha-tert-butyl-nitrone and benzonidazole treatment controlled the mitochondrial oxidative stress and evolution of cardiomyopathy in chronic chagasic Rats. , 2010, Journal of the American College of Cardiology.

[43]  L. Brepoels,et al.  PET scanning and prognosis in Hodgkin's lymphoma , 2008, Current opinion in oncology.

[44]  J. Stockman,et al.  Everolimus for Subependymal Giant-Cell Astrocytomas in Tuberous Sclerosis , 2012 .

[45]  J. Sotelo,et al.  Adding Chloroquine to Conventional Treatment for Glioblastoma Multiforme , 2006, Annals of Internal Medicine.

[46]  P. Vaupel,et al.  Glucose uptake, lactate release, ketone body turnover, metabolic micromilieu, and pH distributions in human breast cancer xenografts in nude rats. , 1988, Cancer research.

[47]  M A Medina,et al.  Glutamine and glucose as energy substrates for Ehrlich ascites tumour cells. , 1988, Biochemistry international.

[48]  F. Sotgia,et al.  HIF1-alpha functions as a tumor promoter in cancer-associated fibroblasts, and as a tumor suppressor in breast cancer cells , 2010, Cell cycle.