The mechanism underlying the effects of the cell surface ATP synthase on the regulation of intracellular acidification during acidosis

The F1F0 ATP synthase has recently become the focus of anti‐cancer research. It was once thought that ATP synthases were located strictly on the inner mitochondrial membrane; however, in 1994, it was found that some ATP synthases localized to the cell surface. The cell surface ATP synthases are invo...

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Published inJournal of cellular biochemistry Vol. 114; no. 7; pp. 1695 - 1703
Main Authors Wang, Wen-juan, Shi, Xiao-xing, Liu, Yi-wen, He, Yi-qing, Wang, Ying-zhi, Yang, Cui-xia, Gao, Feng
Format Journal Article
LanguageEnglish
Published Hoboken Wiley Subscription Services, Inc., A Wiley Company 01.07.2013
Wiley Subscription Services, Inc
Subjects
Acidification
Acidosis - enzymology
Acidosis - metabolism
Adenosine Triphosphatases - metabolism
Animals
APOPTOSIS
Apoptosis - physiology
ATP
Blotting, Western
Cell Line
Cell Proliferation
CELL SURFACE ATP SYNTHASE
CHO Cells
Cricetinae
Cricetulus
Fluorescent Antibody Technique
Hep G2 Cells
Humans
Hydrogen-Ion Concentration
Hypertension
Inhibitors
INTRACELLULAR ACIDIFICATION
Microscopy, Confocal
PC12 Cells
PROLIFERATION
Rats
TUMOR
Online AccessGet full text
ISSN0730-2312
1097-4644
1097-4644
DOI10.1002/jcb.24511

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Abstract The F1F0 ATP synthase has recently become the focus of anti‐cancer research. It was once thought that ATP synthases were located strictly on the inner mitochondrial membrane; however, in 1994, it was found that some ATP synthases localized to the cell surface. The cell surface ATP synthases are involved in angiogenesis, lipoprotein metabolism, innate immunity, hypertension, the regulation of food intake, and other processes. Inhibitors of this synthase have been reported to be cytotoxic and to induce intracellular acidification. However, the mechanisms by which these effects are mediated and the molecular pathways that are involved remain unclear. In this study, we aimed to determine whether the inhibition of cell proliferation and the induction of cell apoptosis that are induced by inhibitors of the cell surface ATP synthase are associated with intracellular acidification and to investigate the mechanism that underlines the effects of this inhibition, particularly in an acidic tumor environment. We demonstrated that intracellular acidification contributes to the cell proliferation inhibition that is mediated by cell surface ATP synthase inhibitors, but not to the induction of apoptosis. Intracellular acidification is only one of the mechanisms of ecto‐ATP synthase‐targeted antitumor drugs. We propose that intracellular acidification in combination with the inhibition of cell surface ATP generation induce cell apoptosis after cell surface ATP synthase blocked by its inhibitors. A better understanding of the mechanisms activated by ecto‐ATP synthase‐targeted cancer therapies may facilitate the development of potent anti‐tumor therapies, which target this enzyme and do not exhibit clinical limitations. J. Cell. Biochem. 114: 1695–1703, 2013. © 2013 Wiley Periodicals, Inc.
AbstractList The F1F0 ATP synthase has recently become the focus of anti-cancer research. It was once thought that ATP synthases were located strictly on the inner mitochondrial membrane; however, in 1994, it was found that some ATP synthases localized to the cell surface. The cell surface ATP synthases are involved in angiogenesis, lipoprotein metabolism, innate immunity, hypertension, the regulation of food intake, and other processes. Inhibitors of this synthase have been reported to be cytotoxic and to induce intracellular acidification. However, the mechanisms by which these effects are mediated and the molecular pathways that are involved remain unclear. In this study, we aimed to determine whether the inhibition of cell proliferation and the induction of cell apoptosis that are induced by inhibitors of the cell surface ATP synthase are associated with intracellular acidification and to investigate the mechanism that underlines the effects of this inhibition, particularly in an acidic tumor environment. We demonstrated that intracellular acidification contributes to the cell proliferation inhibition that is mediated by cell surface ATP synthase inhibitors, but not to the induction of apoptosis. Intracellular acidification is only one of the mechanisms of ecto-ATP synthase-targeted antitumor drugs. We propose that intracellular acidification in combination with the inhibition of cell surface ATP generation induce cell apoptosis after cell surface ATP synthase blocked by its inhibitors. A better understanding of the mechanisms activated by ecto-ATP synthase-targeted cancer therapies may facilitate the development of potent anti-tumor therapies, which target this enzyme and do not exhibit clinical limitations.The F1F0 ATP synthase has recently become the focus of anti-cancer research. It was once thought that ATP synthases were located strictly on the inner mitochondrial membrane; however, in 1994, it was found that some ATP synthases localized to the cell surface. The cell surface ATP synthases are involved in angiogenesis, lipoprotein metabolism, innate immunity, hypertension, the regulation of food intake, and other processes. Inhibitors of this synthase have been reported to be cytotoxic and to induce intracellular acidification. However, the mechanisms by which these effects are mediated and the molecular pathways that are involved remain unclear. In this study, we aimed to determine whether the inhibition of cell proliferation and the induction of cell apoptosis that are induced by inhibitors of the cell surface ATP synthase are associated with intracellular acidification and to investigate the mechanism that underlines the effects of this inhibition, particularly in an acidic tumor environment. We demonstrated that intracellular acidification contributes to the cell proliferation inhibition that is mediated by cell surface ATP synthase inhibitors, but not to the induction of apoptosis. Intracellular acidification is only one of the mechanisms of ecto-ATP synthase-targeted antitumor drugs. We propose that intracellular acidification in combination with the inhibition of cell surface ATP generation induce cell apoptosis after cell surface ATP synthase blocked by its inhibitors. A better understanding of the mechanisms activated by ecto-ATP synthase-targeted cancer therapies may facilitate the development of potent anti-tumor therapies, which target this enzyme and do not exhibit clinical limitations.
The F1F0 ATP synthase has recently become the focus of anti‐cancer research. It was once thought that ATP synthases were located strictly on the inner mitochondrial membrane; however, in 1994, it was found that some ATP synthases localized to the cell surface. The cell surface ATP synthases are involved in angiogenesis, lipoprotein metabolism, innate immunity, hypertension, the regulation of food intake, and other processes. Inhibitors of this synthase have been reported to be cytotoxic and to induce intracellular acidification. However, the mechanisms by which these effects are mediated and the molecular pathways that are involved remain unclear. In this study, we aimed to determine whether the inhibition of cell proliferation and the induction of cell apoptosis that are induced by inhibitors of the cell surface ATP synthase are associated with intracellular acidification and to investigate the mechanism that underlines the effects of this inhibition, particularly in an acidic tumor environment. We demonstrated that intracellular acidification contributes to the cell proliferation inhibition that is mediated by cell surface ATP synthase inhibitors, but not to the induction of apoptosis. Intracellular acidification is only one of the mechanisms of ecto‐ATP synthase‐targeted antitumor drugs. We propose that intracellular acidification in combination with the inhibition of cell surface ATP generation induce cell apoptosis after cell surface ATP synthase blocked by its inhibitors. A better understanding of the mechanisms activated by ecto‐ATP synthase‐targeted cancer therapies may facilitate the development of potent anti‐tumor therapies, which target this enzyme and do not exhibit clinical limitations. J. Cell. Biochem. 114: 1695–1703, 2013. © 2013 Wiley Periodicals, Inc.
The F1F0 ATP synthase has recently become the focus of anti-cancer research. It was once thought that ATP synthases were located strictly on the inner mitochondrial membrane; however, in 1994, it was found that some ATP synthases localized to the cell surface. The cell surface ATP synthases are involved in angiogenesis, lipoprotein metabolism, innate immunity, hypertension, the regulation of food intake, and other processes. Inhibitors of this synthase have been reported to be cytotoxic and to induce intracellular acidification. However, the mechanisms by which these effects are mediated and the molecular pathways that are involved remain unclear. In this study, we aimed to determine whether the inhibition of cell proliferation and the induction of cell apoptosis that are induced by inhibitors of the cell surface ATP synthase are associated with intracellular acidification and to investigate the mechanism that underlines the effects of this inhibition, particularly in an acidic tumor environment. We demonstrated that intracellular acidification contributes to the cell proliferation inhibition that is mediated by cell surface ATP synthase inhibitors, but not to the induction of apoptosis. Intracellular acidification is only one of the mechanisms of ecto-ATP synthase-targeted antitumor drugs. We propose that intracellular acidification in combination with the inhibition of cell surface ATP generation induce cell apoptosis after cell surface ATP synthase blocked by its inhibitors. A better understanding of the mechanisms activated by ecto-ATP synthase-targeted cancer therapies may facilitate the development of potent anti-tumor therapies, which target this enzyme and do not exhibit clinical limitations.
The F1F0 ATP synthase has recently become the focus of anti-cancer research. It was once thought that ATP synthases were located strictly on the inner mitochondrial membrane; however, in 1994, it was found that some ATP synthases localized to the cell surface. The cell surface ATP synthases are involved in angiogenesis, lipoprotein metabolism, innate immunity, hypertension, the regulation of food intake, and other processes. Inhibitors of this synthase have been reported to be cytotoxic and to induce intracellular acidification. However, the mechanisms by which these effects are mediated and the molecular pathways that are involved remain unclear. In this study, we aimed to determine whether the inhibition of cell proliferation and the induction of cell apoptosis that are induced by inhibitors of the cell surface ATP synthase are associated with intracellular acidification and to investigate the mechanism that underlines the effects of this inhibition, particularly in an acidic tumor environment. We demonstrated that intracellular acidification contributes to the cell proliferation inhibition that is mediated by cell surface ATP synthase inhibitors, but not to the induction of apoptosis. Intracellular acidification is only one of the mechanisms of ecto-ATP synthase-targeted antitumor drugs. We propose that intracellular acidification in combination with the inhibition of cell surface ATP generation induce cell apoptosis after cell surface ATP synthase blocked by its inhibitors. A better understanding of the mechanisms activated by ecto-ATP synthase-targeted cancer therapies may facilitate the development of potent anti-tumor therapies, which target this enzyme and do not exhibit clinical limitations. J. Cell. Biochem. 114: 1695-1703, 2013. © 2013 Wiley Periodicals, Inc. [PUBLICATION ABSTRACT]
Author Wang, Wen-juan
Shi, Xiao-xing
He, Yi-qing
Wang, Ying-zhi
Yang, Cui-xia
Gao, Feng
Liu, Yi-wen
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  fullname: Gao, Feng
  email: gao3507@126.com
  organization: Department of Laboratory Medicine, Shanghai Sixth People's Hospital of Shanghai, Shanghai JiaoTong University School of Medicine, Shanghai 200233, PR China
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Zanke BW, Lee C, Arab S, Tannock IF. 1998. Death of tumor cells after intracellular acidification is dependent on stress-activated protein kinases (SAPK/JNK) pathway activation and cannot be inhibited by Bcl-2 expression or interleukin 1β-converting enzyme inhibition. Cancer Res 58:2801-2808.
Adachi S, Shimizu M, Shirakami Y, Yamauchi J, Natsume H, Matsushima-Nishiwaki R, To S, Weinstein IB, Moriwaki H, Kozawa O. 2009. (−)-Epigallocatechin gallate downregulates EGF receptor via phosphorylation at Ser1046/1047 by p38 MAPK in colon cancer cells. Carcinogenesis 30:1544-1552.
Chi SL, Wahl ML, Mowery YM, Shan S, Mukhopadhyay S, Hilderbrand SC, Kenan DJ, Lipes BD, Johnson CE, Marusich MF, Capaldi RA, Dewhirst MW, Pizzo SV. 2007. Angiostatin-like activity of a monoclonal antibody to the catalytic subunit of F1F0 ATP synthase. Cancer Res 67:4716-4724.
Chi SL, Pizzo SV. 2006. Angiostatin is directly cytotoxic to tumor cells at low extracellular pH: A mechanism dependent on cell surface-associated ATP synthase. Cancer Res 66:875-882.
Dong H, Fillingame RH. 2010. Chemical reactivities of cysteine substitutions in subunit a of ATP synthase define residues gating H+ transport from each side of the membrane. J Biol Chem 285:39811-39818.
Pongracz J, Deacon EM, Johnson GD, Burnett D, Lord JM. 1996. Doppa induces cell death but not differentiation of U937 cells: Evidence for the involvement of PKC-βl in the regulation of apoptosis. Leukemia Res 20:319-326.
Takahashi S, Shinya T, Sugiyama A. 2010. Angiostatin inhibition of vascular endothelial growth factor-stimulated nitric oxide production in endothelial cells. J Pharmacol Sci 112:432-437.
Mowery Y, Pizzo S. 2008. Targeting cell surface F1F0 ATP synthase in cancer therapy. Cancer Biol Ther 7:1836-1838.
Zhang X, Gao F, Yu L, Peng Y, Liu H, Liu J, Yin M, Ni J. 2008. Dual functions of a monoclonal antibody against cell surface F1F0 ATP synthase on both HUVEC and tumor cells. Acta Pharmacol Sin 29:942-950.
Vantourout P, Martinez LO, Fabre A, Collet X, Champagne E. 2008. Ecto-F1F0-ATPase and MHC-class I close association on cell membranes. Mol Immunol 45:485-492.
Xiao-yan Chi, Yan-jie Wang, Yue-li Hou. 2011. Effects of angiostatin on growth and apotosis of vascular endothelial cells in vitro. Lab Sci 2:040.
Wu SJ, Wu JY. 2008. Extracellular ATP-induced NO production and its dependence on membrane Ca2+ flux in Salvia miltiorrhiza hairy roots. J Exp Bot 59:4007-4016.
Kurup A, Lin CW, Murry D, Dobrolecki L, Estes D, Yiannoutsos C, Mariano L, Sidor C, Hickey R, Hanna N. 2006. Recombinant human angiostatin (rhAngiostatin) in combination with paclitaxel and carboplatin in patients with advanced non-small-cell lung cancer: A phase II study from Indiana University. Ann Oncol 17:97-103.
Lee JY, Karwatsky J, Ma L, Zha X. 2011. ABCA1 increases extracellular ATP to mediate cholesterol efflux to apoA-I. Am J Physiol Cell Physiol 301:C886-C894.
Pan J, Sun L, Tao Y, Zhou Z, Du X, Peng L, Feng X, Wang J, Li Y, Liu L, Wu S, Zhang Y, Hu S, Zhao W, Zhu X, Lou G, Ni J. 2011. ATP synthase ecto-α-subunit: A novel therapeutic target for breast cancer. J Transl Med 9:211.
Saijo K, Mecklenbräuker I, Santana A, Leitger M, Schmedt C, Tarakhovsky A. 2002. Protein kinase C β controls nuclear factor κB activation in B cells through selective regulation of the IκB kinase α. J Exp Med 195:1647-1652.
Vacirca D, Barbati C, Scazzocchio B, Masella R, Rosano G, Malorni W, Ortona E. 2011. Anti-ATP synthase autoantibodies from patients with Alzheimer's disease reduce extracellular HDL level. J Alzheimer's Dis 26:441-445.
Yang L, Mei Y, Xie Q, Han X, Zhang F, Gu L, Zhang Y, Chen Y, Li G, Gao Z. 2008. Acidification induces Bax translocation to the mitochondria and promotes ultraviolet light-induced apoptosis. Cell Mol Biol Lett 13:119-129.
Moser TL, Stack MS, Asplin I, Enghild JJ, Hojrup P, Everitt L, Hubchak S, Schnaper HW, Pizzo SV. 1999. Angiostatin binds ATP synthase on the surface of human endothelial cells. PNAS 96:2811-2816.
Hanford HA, Wong CA, Kassan H, Cundiff DL, Chandel N, Underwood S, Mitchell CA, Soff GA. 2003. Angiostatin4. 5-Mediated apoptosis of vascular endothelial cells. Cancer Res 63:4275-4280.
Lu GD, Shen HM, Chung MCM, Ong CN. 2007. Critical role of oxidative stress and sustained JNK activation in aloe-emodin-mediated apoptotic cell death in human hepatoma cells. Carcinogenesis 28:1937-1945.
Harrison SM, Frampton JE, McCall E, Boyett MR, Orchard CH. 1992. Contraction and intracellular Ca2+, Na+, and H+ during acidosis in rat ventricular myocytes. Am J Physiol Cell Physiol 262:C348-C357.
Usukura E, Suzuki T, Furuike S, Soga N, Saita E, Hisabori T, Kinosita K, Jr., Yoshida M. 2012. Torque generation and utilization in motor enzyme F0F1-ATP synthase. J Biol Chem 287:1884-1891.
Lelouvier B, Puertollano R. 2011. Mucolipin-3 regulates luminal calcium, acidification, and membrane fusion in the endosomal pathway. J Biol Chem 286:9826-9832.
Cardone MH, Roy N, Stennicke HR, Salvesen GS, Franke TF, Stanbridge E, Frisch S, Reed JC. 1998. Regulation of cell death protease caspase-9 by phosphorylation. Science 282:1318-1321.
Dass CR, Tran T, Choong PFM. 2007. Angiogenesis inhibitors and the need for anti-angiogenic therapeutics. J Dent Res 86:927-936.
Moser TL, Kenan DJ, Ashley TA, Roy JA, Goodman MD, Misra UK, Cheek DJ, Pizzo SV. 2001. Endothelial cell surface F1-FO ATP synthase is active in ATP synthesis and is inhibited by angiostatin. PNAS 98:6656-6661.
Shampo M, Kyle R, Steensma D. 2011. Paul D. Boyer Nobel prize for work on ATP synthase. Mayo Clin Proc 86:e51.
Laihia JK, Kallio JP, Taimen P, Kujari H, Kähäri VM, Leino L. 2010. Protodynamic intracellular acidification by cis-urocanic acid promotes apoptosis of melanoma cells in vitro and in vivo. J Invest Dermatol 130:2431-2439.
Roberts P, Der C. 2007. Targeting the Raf-MEK-ERK mitogen-activated protein kinase cascade for the treatment of cancer. Oncogene 26:3291-3310.
Terni B, Boada J, Portero-Otin M, Pamplona R, Ferrer I. 2010. Mitochondrial ATP-synthase in the entorhinal cortex is a target of oxidative stress at stages I/II of Alzheimer's disease pathology. Brain Pathol 20:222-233.
Ping P, Zhang J, Huang S, Cao X, Tang XL, Li RCX, Zheng YT, Qiu Y, Clerk A, Sugden P. 1999. PKC-dependent activation of p46/p54 JNKs during ischemic preconditioning in conscious rabbits. Am J Physiol Heart Circ Physiol 277:H1771-H1785.
Oakes SG, Martin WJ, II, Lisek CA, Powis G. 1988. Incomplete hydrolysis of the calcium indicator precursor fura-2 pentaacetoxymethyl ester (fura-2 AM) by cells. Anal Biochem 169:159-166.
Kim SW, Oleksyn DW, Rossi RM, Jordan CT, Sanz I, Chen L, Zhao J. 2008. Protein kinase C-associated kinase is required for NF-κB signaling and survival in diffuse large B-cell lymphoma cells. Blood 111:1644-1653.
Neary JT, Kang Y, Willoughby KA, Ellis EF. 2003. Activation of extracellular signal-regulated kinase by stretch-induced injury in astrocytes involves extracellular ATP and P2 purinergic receptors. J Neurosci 23:2348-2356.
Thangaraju M, Sharma K, Leber B, Andrews DW, Shen SH, Srikant CB. 1999. Regulation of acidification and apoptosis by SHP-1 and Bcl-2. J Biol Chem 274:29549-29557.
Franck P, Petitipain N, Cherlet M, Dardennes M, Maachi F, Schutz B, Poisson L, Nabet P. 1996. Measurement of intracellular pH in cultured cells by flow cytometry with BCECF-AM. J Biotechnol 46:187-195.
Chen YH, Huang YH, Wu HL, Wu MP, Chang WT, Kuo YZ, Lu KC, Wu LW. 2008. Angiostatin K1-3 induces E-selectin via AP1 and Ets1: A mediator for anti-angiogenic action of K1-3. J Thromb Haemost 6:1953-1961.
Brunet A, Bonni A, Zigmond MJ, Lin MZ, Juo P, Hu LS, Anderson MJ, Arden KC, Blenis J, Greenberg ME. 1999. Akt promotes cell survival by phosphorylating and inhibiting a Forkhead transcription factor. Cell (Cambridge, MA) 96:857-868.
Schelling JR, Jawdeh BGA. 2008. Regulation of cell surviva
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Snippet The F1F0 ATP synthase has recently become the focus of anti‐cancer research. It was once thought that ATP synthases were located strictly on the inner...
The F1F0 ATP synthase has recently become the focus of anti-cancer research. It was once thought that ATP synthases were located strictly on the inner...
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SubjectTerms Acidification
Acidosis - enzymology
Acidosis - metabolism
Adenosine Triphosphatases - metabolism
Animals
APOPTOSIS
Apoptosis - physiology
ATP
Blotting, Western
Cell Line
Cell Proliferation
CELL SURFACE ATP SYNTHASE
CHO Cells
Cricetinae
Cricetulus
Fluorescent Antibody Technique
Hep G2 Cells
Humans
Hydrogen-Ion Concentration
Hypertension
Inhibitors
INTRACELLULAR ACIDIFICATION
Microscopy, Confocal
PC12 Cells
PROLIFERATION
Rats
TUMOR
Title The mechanism underlying the effects of the cell surface ATP synthase on the regulation of intracellular acidification during acidosis
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https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fjcb.24511
https://www.ncbi.nlm.nih.gov/pubmed/23386430
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https://www.proquest.com/docview/1350895025
Volume 114
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