TY - JOUR
T1 - Mitochondrial oxidative stress in cancer-associated fibroblasts drives lactate production, promoting breast cancer tumor growth
T2 - Understanding the aging and cancer connection
AU - Balliet, Renee M.
AU - Capparelli, Claudia
AU - Guido, Carmela
AU - Pestell, Timothy G.
AU - Martinez-Outschoorn, Ubaldo E.
AU - Lin, Zhao
AU - Whitaker-Menezes, Diana
AU - Chiavarina, Barbara
AU - Pestell, Richard G.
AU - Howell, Anthony
AU - Sotgia, Federica
AU - Lisanti, Michael P.
N1 - Funding Information:
staining for CD31 was performed on frozen tumor sections using F.S. and her laboratory were supported by grants from the Breast a 3-step biotin-streptavidin-horseradish peroxidase method. Cancer Alliance (BCA) and the American Cancer Society (ACS). Frozen tissue sections (6 μm) were fixed in 2% paraformalde-U.E.M. was supported by a Young Investigator Award from the hyde in PBS for 10 min and washed with PBS. After blocking Margaret Q. Landenberger Research Foundation. M.P.L. was with 10% rabbit serum, the sections were incubated overnight supported by grants from the NIH/NCI (R01-CA-080250; at 4°C with rat anti-mouse CD31 antibody (BS Biosciences) at R01-CA-098779; R01-CA-120876; R01-AR-055660) and the a dilution of 1:200, followed by biotinylated rabbit anti-rat IgG Susan G. Komen Breast Cancer Foundation. R.G.P. was supported (1:200) antibody and streptavidin-HRP. Immuno-reactivity was by grants from the NIH/NCI (R01-CA-70896, R01-CA-75503, revealed with 3,3'-diaminobenzidine. For quantitation of vessels, R01-CA-86072 and R01-CA-107382) and the Dr. Ralph and CD31-positive vessels were enumerated in 8 fields within the cen-Marian C. Falk Medical Research Trust. The Kimmel Cancer tral area of each tumor using a 20x objective lens and an ocular Center was supported by the NIH/NCI Cancer Center Core grid (0.25 mm2 per field). TÜhe total numbers of vessel per unit grant P30-CA-56036 (to R.G.P.). Funds were also contributed area was calculated using Image J. -BOEFTby t#he MJPargTaretD QJ. FLanOdenDbeFrger Research Foundation (to Mitochondrial activity staining in MDA/fibroblast co- M.P.L.). This project is funded, in part, under a grant with the cultures. Fibroblasts (hTERT; sh-TFAM vs. sh-Ctrl cells) and Pennsylvania Department of Health (to M.P.L. and F.S.). The epithelial cancer cells [MDA-MB-231-G%FP(P+)] weOre pPlateUd onEto JTDeUpaSrtmJeCnt sVpeciUficFally disclaims responsibility for any analyses, glass coverslips in 12-well plates. After 3 days in DMEM with interpretations or conclusions. This work was also supported, in 10% NuSerum, the co-cultures were stained for mitochondrial part, by a Centre grant in Manchester from Breakthrough Breast activity, as previously described in references 55 and 60. Briefly, Cancer in the UK (to A.H.) and an Advanced ERC Grant from MitoTracker Orange (CMTMRos M7510, Invitrogen, Inc.) was the European Research Council.
PY - 2011/12/1
Y1 - 2011/12/1
N2 - Increasing chronological age is the most significant risk factor for cancer. Recently, we proposed a new paradigm for understanding the role of the aging and the tumor microenvironment in cancer onset. In this model, cancer cells induce oxidative stress in adjacent stromal fibroblasts. This, in turn, causes several changes in the phenotype of the fibroblast including mitochondrial dysfunction, hydrogen peroxide production and aerobic glycolysis, resulting in high levels of L-lactate production. L-lactate is then transferred from these glycolytic fibroblasts to adjacent epithelial cancer cells and used as "fuel" for oxidative mitochondrial metabolism. Here, we created a new pre-clinical model system to directly test this hypothesis experimentally. To synthetically generate glycolytic fibroblasts, we genetically-induced mitochondrial dysfunction by knocking down TFAM using an sh-RNA approach. TFAM is mitochondrial transcription factor A, which is important in functionally maintaining the mitochondrial respiratory chain. Interestingly, TFAM-deficient fibroblasts showed evidence of mitochondrial dysfunction and oxidative stress, with the loss of certain mitochondrial respiratory chain components, and the over-production of hydrogen peroxide and L-lactate. Thus, TFAM-deficient fibroblasts underwent metabolic reprogramming towards aerobic glycolysis. Most importantly, TFAM-deficient fibroblasts significantly promoted tumor growth, as assayed using a human breast cancer (MDA-MB-231) xenograft model. These increases in glycolytic fibroblast driven tumor growth were independent of tumor angiogenesis. Mechanistically, TFAM-deficient fibroblasts increased the mitochondrial activity of adjacent epithelial cancer cells in a co-culture system, as seen using MitoTracker. Finally, TFAM-deficient fibroblasts also showed a loss of caveolin-1 (Cav-1), a known breast cancer stromal biomarker. Loss of stromal fibroblast Cav-1 is associated with early tumor recurrence, metastasis and treatment failure, resulting in poor clinical outcome in breast cancer patients. Thus, this new experimental model system, employing glycolytic fibroblasts, may be highly clinically relevant. These studies also have implications for understanding the role of hydrogen peroxide production in oxidative damage and "host cell aging," in providing a permissive metabolic microenvironment for promoting and sustaining tumor growth.
AB - Increasing chronological age is the most significant risk factor for cancer. Recently, we proposed a new paradigm for understanding the role of the aging and the tumor microenvironment in cancer onset. In this model, cancer cells induce oxidative stress in adjacent stromal fibroblasts. This, in turn, causes several changes in the phenotype of the fibroblast including mitochondrial dysfunction, hydrogen peroxide production and aerobic glycolysis, resulting in high levels of L-lactate production. L-lactate is then transferred from these glycolytic fibroblasts to adjacent epithelial cancer cells and used as "fuel" for oxidative mitochondrial metabolism. Here, we created a new pre-clinical model system to directly test this hypothesis experimentally. To synthetically generate glycolytic fibroblasts, we genetically-induced mitochondrial dysfunction by knocking down TFAM using an sh-RNA approach. TFAM is mitochondrial transcription factor A, which is important in functionally maintaining the mitochondrial respiratory chain. Interestingly, TFAM-deficient fibroblasts showed evidence of mitochondrial dysfunction and oxidative stress, with the loss of certain mitochondrial respiratory chain components, and the over-production of hydrogen peroxide and L-lactate. Thus, TFAM-deficient fibroblasts underwent metabolic reprogramming towards aerobic glycolysis. Most importantly, TFAM-deficient fibroblasts significantly promoted tumor growth, as assayed using a human breast cancer (MDA-MB-231) xenograft model. These increases in glycolytic fibroblast driven tumor growth were independent of tumor angiogenesis. Mechanistically, TFAM-deficient fibroblasts increased the mitochondrial activity of adjacent epithelial cancer cells in a co-culture system, as seen using MitoTracker. Finally, TFAM-deficient fibroblasts also showed a loss of caveolin-1 (Cav-1), a known breast cancer stromal biomarker. Loss of stromal fibroblast Cav-1 is associated with early tumor recurrence, metastasis and treatment failure, resulting in poor clinical outcome in breast cancer patients. Thus, this new experimental model system, employing glycolytic fibroblasts, may be highly clinically relevant. These studies also have implications for understanding the role of hydrogen peroxide production in oxidative damage and "host cell aging," in providing a permissive metabolic microenvironment for promoting and sustaining tumor growth.
KW - Aerobic glycolysis
KW - Aging
KW - Cancer associated fibroblasts
KW - Cancer metabolism
KW - Caveolin-1
KW - Electron transport
KW - Hydrogen peroxide
KW - Lactate
KW - Mitochondria
KW - Oxidative phosphorylation (OXPHOS)
KW - Respiratory chain
KW - Reverse Warburg effect
KW - TFAM
UR - http://www.scopus.com/inward/record.url?scp=82855170859&partnerID=8YFLogxK
U2 - 10.4161/cc.10.23.18254
DO - 10.4161/cc.10.23.18254
M3 - Article
C2 - 22129993
AN - SCOPUS:82855170859
SN - 1538-4101
VL - 10
SP - 4065
EP - 4073
JO - Cell Cycle
JF - Cell Cycle
IS - 23
ER -