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Literature DB >> 22987151

The real face of HIF1α in the tumor process.

Matthias Kappler¹, Helge Taubert, Johannes Schubert, Dirk Vordermark, Alexander W Eckert.

Abstract

It is well known that the hypoxia-inducible factor 1 α (HIF1α) is detectable as adaptive metabolic response to hypoxia. However, HIF1/HIF1α is detectable even under normoxic conditions, if the metabolism is altered, e.g., high proliferation index. Importantly, both hypoxic metabolism and the Warburg effect have in common a decrease of the intracellular pH value. In our interpretation, HIF1α is not directly accumulated by hypoxia, but by a process which occurs always under hypoxic conditions, a decrease of the intracellular pH value because of metabolic imbalances. We assume that HIF1α is a sensitive controller of the intracellular pH value independently of the oxygen concentration. Moreover, HIF1α has its major role in activating genes to eliminate toxic metabolic waste products (e.g., NH3/NH4+) generated by the tumor-specific metabolism called glutaminolysis, which occur during hypoxia, or the Warburg effect. For that reason, HIF1α appears as a potential target for tumor therapy to disturb the pH balance and to inhibit the elimination of toxic metabolic waste products in the tumor cells.

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Year: 2012 PMID： 22987151 PMCID： PMC3507488 DOI： 10.4161/cc.21854

Source DB: PubMed Journal: Cell Cycle ISSN： 1551-4005 Impact factor: 4.534

43 in total

1. On respiratory impairment in cancer cells.

Authors: O WARBURG
Journal: Science Date: 1956-08-10 Impact factor: 47.728

Review 2. Hypoxia in cancer: significance and impact on clinical outcome.

Authors: Peter Vaupel; Arnulf Mayer
Journal: Cancer Metastasis Rev Date: 2007-06 Impact factor: 9.264

3. HIF1-alpha functions as a tumor promoter in cancer associated fibroblasts, and as a tumor suppressor in breast cancer cells: Autophagy drives compartment-specific oncogenesis.

Authors: Barbara Chiavarina; Diana Whitaker-Menezes; Gemma Migneco; Ubaldo E Martinez-Outschoorn; Stephanos Pavlides; Anthony Howell; Herbert B Tanowitz; Mathew C Casimiro; Chenguang Wang; Richard G Pestell; Philip Grieshaber; Jaime Caro; Federica Sotgia; Michael P Lisanti
Journal: Cell Cycle Date: 2010-09-04 Impact factor: 4.534

4. Nitrogen anabolism underlies the importance of glutaminolysis in proliferating cells.

Authors: Meng Meng; Shuyang Chen; Taotao Lao; Dongming Liang; Nianli Sang
Journal: Cell Cycle Date: 2010-10-25 Impact factor: 4.534

5. The purpose of the HIF-1/PHD feedback loop: to limit mTOR-induced HIF-1α.

Authors: Zoya N Demidenko; Mikhail V Blagosklonny
Journal: Cell Cycle Date: 2011-05-15 Impact factor: 4.534

6. Gene regulation in response to graded hypoxia: the non-redundant roles of the oxygen sensors PHD and FIH in the HIF pathway.

Authors: Frédéric Dayan; Marc Monticelli; Jacques Pouysségur; Elisabeth Pécou
Journal: J Theor Biol Date: 2009-03-17 Impact factor: 2.691

Review 7. Rethinking the Warburg effect with Myc micromanaging glutamine metabolism.

Authors: Chi V Dang
Journal: Cancer Res Date: 2010-01-19 Impact factor: 12.701

8. Endogenous hypoxia markers: case not proven!

Authors: Arnulf Mayer; Michael Höckel; Peter Vaupel
Journal: Adv Exp Med Biol Date: 2008 Impact factor: 2.622

9. STAT3, HIF-1, glucose addiction and Warburg effect.

Authors: James E Darnell
Journal: Aging (Albany NY) Date: 2010-12 Impact factor: 5.682

10. Pyruvate kinase M2 regulates glucose metabolism by functioning as a coactivator for hypoxia-inducible factor 1 in cancer cells.

Authors: Weibo Luo; Gregg L Semenza
Journal: Oncotarget Date: 2011-07

19 in total

Review 1. Mechanisms of regulation of PFKFB expression in pancreatic and gastric cancer cells.

Authors: Oleksandr H Minchenko; Katsuya Tsuchihara; Dmytro O Minchenko; Andreas Bikfalvi; Hiroyasu Esumi
Journal: World J Gastroenterol Date: 2014-10-14 Impact factor: 5.742

2. Normoxic accumulation of HIF1α is associated with glutaminolysis.

Authors: Matthias Kappler; Ulrike Pabst; Swetlana Rot; Helge Taubert; Henri Wichmann; Johannes Schubert; Matthias Bache; Claus Weinholdt; Uta-Dorothee Immel; Ivo Grosse; Dirk Vordermark; Alexander W Eckert
Journal: Clin Oral Investig Date: 2016-03-09 Impact factor: 3.573

Review 3. The cancer stem cell niche: cross talk between cancer stem cells and their microenvironment.

Authors: Jun Ye; Dang Wu; Pin Wu; Zhigang Chen; Jian Huang
Journal: Tumour Biol Date: 2014-01-14

4. SOCS3 blocks HIF-1α expression to inhibit proliferation and angiogenesis of human small cell lung cancer by downregulating activation of Akt, but not STAT3.

Authors: Jun Wan; Yun Che; Ningning Kang; Wei Wu
Journal: Mol Med Rep Date: 2015-02-17 Impact factor: 2.952

5. Mitochondrial dysfunction promotes breast cancer cell migration and invasion through HIF1α accumulation via increased production of reactive oxygen species.

Authors: Jia Ma; Qing Zhang; Sulian Chen; Binbin Fang; Qingling Yang; Changjie Chen; Lucio Miele; Fazlul H Sarkar; Jun Xia; Zhiwei Wang
Journal: PLoS One Date: 2013-07-29 Impact factor: 3.240

6. Clinical and prognostic significance of HIF-1α overexpression in oral squamous cell carcinoma: a meta-analysis.

Authors: Jianhua Zhou; Shengyun Huang; Lili Wang; Xiao Yuan; Quanjiang Dong; Dongsheng Zhang; Xuxia Wang
Journal: World J Surg Oncol Date: 2017-05-18 Impact factor: 2.754

7. Microenvironment mediated alterations to metabolic pathways confer increased chemo-resistance in CD133+ tumor initiating cells.

Authors: Alice Nomura; Patricia Dauer; Vineet Gupta; Olivia McGinn; Nivedita Arora; Kaustav Majumdar; Charles Uhlrich; Joseph Dalluge; Vikas Dudeja; Ashok Saluja; Sulagna Banerjee
Journal: Oncotarget Date: 2016-08-30