Anaerobic respiration sustains mitochondrial membrane potential in a prolyl hydroxylase pathway-activated cancer cell line in a hypoxic microenvironment
To elucidate how tumor cells produce energy in oxygen-depleted microenvironments, we studied the possibility of mitochondrial electron transport without oxygen. We produced well-controlled oxygen gradients (ΔO2) in monolayer-cultured cells. We then visualized oxygen levels and mitochondrial membrane...
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| Veröffentlicht in: | American Journal of Physiology: Cell Physiology 2014-02, Vol.306 (4), p.C334-C342 |
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| creator | Takahashi, Eiji Sato, Michihiko |
| description | To elucidate how tumor cells produce energy in oxygen-depleted microenvironments, we studied the possibility of mitochondrial electron transport without oxygen. We produced well-controlled oxygen gradients (ΔO2) in monolayer-cultured cells. We then visualized oxygen levels and mitochondrial membrane potential (ΔΦm) in individual cells by using the red shift of green fluorescent protein (GFP) fluorescence and a cationic fluorescent dye, respectively. In this two-dimensional tissue model, ΔΦm was abolished in cells >500 μm from the oxygen source [the anoxic front (AF)], indicating limitations in diffusional oxygen delivery. This result perfectly matched GFP-determined ΔO2. In cells pretreated with dimethyloxaloylglycine (DMOG), a prolyl hydroxylase domain-containing protein (PHD) inhibitor, the AF was expanded to 1,500-2,000 μm from the source. In these cells, tissue ΔO2 was substantially decreased, indicating that PHD pathway activation suppressed mitochondrial respiration. The expansion of the AF and the reduction of ΔO2 were much more prominent in a cancer cell line (Hep3B) than in the equivalent fibroblast-like cell line (COS-7). Hence, the results indicate that PHD pathway-activated cells can sustain ΔΦm, despite significantly decreased electron flux to complex IV. Complex II inhibition abolished the effect of DMOG in expanding the AF, although tissue ΔO2 remained shallow. Separate experiments demonstrated that complex II plays a substantial role in sustaining ΔΦm in DMOG-pretreated Hep3B cells with complex III inhibition. From these results, we conclude that PHD pathway activation can sustain ΔΦm in an otherwise anoxic microenvironment by decreasing tissue ΔO2 while activating oxygen-independent electron transport in mitochondria. |
| doi_str_mv | 10.1152/ajpcell.00255.2013 |
| format | Article |
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We produced well-controlled oxygen gradients (ΔO2) in monolayer-cultured cells. We then visualized oxygen levels and mitochondrial membrane potential (ΔΦm) in individual cells by using the red shift of green fluorescent protein (GFP) fluorescence and a cationic fluorescent dye, respectively. In this two-dimensional tissue model, ΔΦm was abolished in cells >500 μm from the oxygen source [the anoxic front (AF)], indicating limitations in diffusional oxygen delivery. This result perfectly matched GFP-determined ΔO2. In cells pretreated with dimethyloxaloylglycine (DMOG), a prolyl hydroxylase domain-containing protein (PHD) inhibitor, the AF was expanded to 1,500-2,000 μm from the source. In these cells, tissue ΔO2 was substantially decreased, indicating that PHD pathway activation suppressed mitochondrial respiration. The expansion of the AF and the reduction of ΔO2 were much more prominent in a cancer cell line (Hep3B) than in the equivalent fibroblast-like cell line (COS-7). Hence, the results indicate that PHD pathway-activated cells can sustain ΔΦm, despite significantly decreased electron flux to complex IV. Complex II inhibition abolished the effect of DMOG in expanding the AF, although tissue ΔO2 remained shallow. Separate experiments demonstrated that complex II plays a substantial role in sustaining ΔΦm in DMOG-pretreated Hep3B cells with complex III inhibition. From these results, we conclude that PHD pathway activation can sustain ΔΦm in an otherwise anoxic microenvironment by decreasing tissue ΔO2 while activating oxygen-independent electron transport in mitochondria.</description><identifier>ISSN: 0363-6143</identifier><identifier>EISSN: 1522-1563</identifier><identifier>DOI: 10.1152/ajpcell.00255.2013</identifier><identifier>PMID: 24048731</identifier><identifier>CODEN: AJPCDD</identifier><language>eng</language><publisher>United States: American Physiological Society</publisher><subject>Anaerobiosis ; Animals ; Cancer ; Carcinoma, Hepatocellular - metabolism ; Cell Hypoxia ; Cell Line, Tumor ; Cell Respiration ; Cells ; Cercopithecus aethiops ; COS Cells ; Electron Transport ; Electron Transport Complex II - metabolism ; Enzyme Activation ; Enzymes ; Fluorescence ; Humans ; Liver Neoplasms - enzymology ; Luminescent Proteins - genetics ; Luminescent Proteins - metabolism ; Membrane Potential, Mitochondrial - drug effects ; Membranes ; Microscopy, Fluorescence ; Mitochondria, Liver - drug effects ; Mitochondria, Liver - metabolism ; Oxygen ; Oxygen - metabolism ; Prolyl Hydroxylases - metabolism ; Prolyl-Hydroxylase Inhibitors - pharmacology ; Red shift ; Transfection ; Tumor Microenvironment ; Tumors</subject><ispartof>American Journal of Physiology: Cell Physiology, 2014-02, Vol.306 (4), p.C334-C342</ispartof><rights>Copyright American Physiological Society Feb 15, 2014</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c397t-5d75d0658f9118bc14e4a0f056210a55b3f96c09373adcc02dbe2a33e48611da3</citedby><cites>FETCH-LOGICAL-c397t-5d75d0658f9118bc14e4a0f056210a55b3f96c09373adcc02dbe2a33e48611da3</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,780,784,3039,27924,27925</link.rule.ids><backlink>$$Uhttps://www.ncbi.nlm.nih.gov/pubmed/24048731$$D View this record in MEDLINE/PubMed$$Hfree_for_read</backlink></links><search><creatorcontrib>Takahashi, Eiji</creatorcontrib><creatorcontrib>Sato, Michihiko</creatorcontrib><title>Anaerobic respiration sustains mitochondrial membrane potential in a prolyl hydroxylase pathway-activated cancer cell line in a hypoxic microenvironment</title><title>American Journal of Physiology: Cell Physiology</title><addtitle>Am J Physiol Cell Physiol</addtitle><description>To elucidate how tumor cells produce energy in oxygen-depleted microenvironments, we studied the possibility of mitochondrial electron transport without oxygen. We produced well-controlled oxygen gradients (ΔO2) in monolayer-cultured cells. We then visualized oxygen levels and mitochondrial membrane potential (ΔΦm) in individual cells by using the red shift of green fluorescent protein (GFP) fluorescence and a cationic fluorescent dye, respectively. In this two-dimensional tissue model, ΔΦm was abolished in cells >500 μm from the oxygen source [the anoxic front (AF)], indicating limitations in diffusional oxygen delivery. This result perfectly matched GFP-determined ΔO2. In cells pretreated with dimethyloxaloylglycine (DMOG), a prolyl hydroxylase domain-containing protein (PHD) inhibitor, the AF was expanded to 1,500-2,000 μm from the source. In these cells, tissue ΔO2 was substantially decreased, indicating that PHD pathway activation suppressed mitochondrial respiration. The expansion of the AF and the reduction of ΔO2 were much more prominent in a cancer cell line (Hep3B) than in the equivalent fibroblast-like cell line (COS-7). Hence, the results indicate that PHD pathway-activated cells can sustain ΔΦm, despite significantly decreased electron flux to complex IV. Complex II inhibition abolished the effect of DMOG in expanding the AF, although tissue ΔO2 remained shallow. Separate experiments demonstrated that complex II plays a substantial role in sustaining ΔΦm in DMOG-pretreated Hep3B cells with complex III inhibition. From these results, we conclude that PHD pathway activation can sustain ΔΦm in an otherwise anoxic microenvironment by decreasing tissue ΔO2 while activating oxygen-independent electron transport in mitochondria.</description><subject>Anaerobiosis</subject><subject>Animals</subject><subject>Cancer</subject><subject>Carcinoma, Hepatocellular - metabolism</subject><subject>Cell Hypoxia</subject><subject>Cell Line, Tumor</subject><subject>Cell Respiration</subject><subject>Cells</subject><subject>Cercopithecus aethiops</subject><subject>COS Cells</subject><subject>Electron Transport</subject><subject>Electron Transport Complex II - metabolism</subject><subject>Enzyme Activation</subject><subject>Enzymes</subject><subject>Fluorescence</subject><subject>Humans</subject><subject>Liver Neoplasms - enzymology</subject><subject>Luminescent Proteins - genetics</subject><subject>Luminescent Proteins - metabolism</subject><subject>Membrane Potential, Mitochondrial - drug effects</subject><subject>Membranes</subject><subject>Microscopy, Fluorescence</subject><subject>Mitochondria, Liver - drug effects</subject><subject>Mitochondria, Liver - metabolism</subject><subject>Oxygen</subject><subject>Oxygen - metabolism</subject><subject>Prolyl Hydroxylases - metabolism</subject><subject>Prolyl-Hydroxylase Inhibitors - pharmacology</subject><subject>Red shift</subject><subject>Transfection</subject><subject>Tumor Microenvironment</subject><subject>Tumors</subject><issn>0363-6143</issn><issn>1522-1563</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2014</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNpdUU1v1DAUtBCIbgt_gAOyxIVLlufPbI5VVaBSJS5wjl4cR-tVYgfbKc0_4efitAsHTpaeZ-bNvCHkHYM9Y4p_wtNs7DjuAbhSew5MvCC78sErprR4SXYgtKg0k-KCXKZ0AgDJdfOaXHAJ8lALtiO_rz3aGDpnaLRpdhGzC56mJWV0PtHJ5WCOwffR4UgnO3URvaVzyNbnbeQ8RTrHMK4jPa59DI_riKkgMB9_4Vqhye4Bs-2pQW9spJtlOroi8kQ9rnN4LNsnZ2Kw_sHF4Kei_Ya8GnBM9u35vSI_Pt9-v_la3X_7cndzfV8Z0dS5Un2tetDqMDSMHTrDpJUIAyjNGaBSnRgabaARtcDeGOB9ZzkKYeVBM9ajuCIfn3VLhp-LTbmdXNo8lphhSS2TTVPOWQtVoB_-g57CEn1x1zIFTGqpAAqKP6NKnpSiHdo5ugnj2jJot97ac2_tU2_t1lshvT9LL91k-3-Uv0WJP_LomO4</recordid><startdate>20140215</startdate><enddate>20140215</enddate><creator>Takahashi, Eiji</creator><creator>Sato, Michihiko</creator><general>American Physiological Society</general><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7QP</scope><scope>7TS</scope><scope>7X8</scope></search><sort><creationdate>20140215</creationdate><title>Anaerobic respiration sustains mitochondrial membrane potential in a prolyl hydroxylase pathway-activated cancer cell line in a hypoxic microenvironment</title><author>Takahashi, Eiji ; Sato, Michihiko</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c397t-5d75d0658f9118bc14e4a0f056210a55b3f96c09373adcc02dbe2a33e48611da3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2014</creationdate><topic>Anaerobiosis</topic><topic>Animals</topic><topic>Cancer</topic><topic>Carcinoma, Hepatocellular - metabolism</topic><topic>Cell Hypoxia</topic><topic>Cell Line, Tumor</topic><topic>Cell Respiration</topic><topic>Cells</topic><topic>Cercopithecus aethiops</topic><topic>COS Cells</topic><topic>Electron Transport</topic><topic>Electron Transport Complex II - metabolism</topic><topic>Enzyme Activation</topic><topic>Enzymes</topic><topic>Fluorescence</topic><topic>Humans</topic><topic>Liver Neoplasms - enzymology</topic><topic>Luminescent Proteins - genetics</topic><topic>Luminescent Proteins - metabolism</topic><topic>Membrane Potential, Mitochondrial - drug effects</topic><topic>Membranes</topic><topic>Microscopy, Fluorescence</topic><topic>Mitochondria, Liver - drug effects</topic><topic>Mitochondria, Liver - metabolism</topic><topic>Oxygen</topic><topic>Oxygen - metabolism</topic><topic>Prolyl Hydroxylases - metabolism</topic><topic>Prolyl-Hydroxylase Inhibitors - pharmacology</topic><topic>Red shift</topic><topic>Transfection</topic><topic>Tumor Microenvironment</topic><topic>Tumors</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Takahashi, Eiji</creatorcontrib><creatorcontrib>Sato, Michihiko</creatorcontrib><collection>Medline</collection><collection>MEDLINE</collection><collection>MEDLINE (Ovid)</collection><collection>MEDLINE</collection><collection>MEDLINE</collection><collection>PubMed</collection><collection>CrossRef</collection><collection>Calcium & Calcified Tissue Abstracts</collection><collection>Physical Education Index</collection><collection>MEDLINE - Academic</collection><jtitle>American Journal of Physiology: Cell Physiology</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Takahashi, Eiji</au><au>Sato, Michihiko</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Anaerobic respiration sustains mitochondrial membrane potential in a prolyl hydroxylase pathway-activated cancer cell line in a hypoxic microenvironment</atitle><jtitle>American Journal of Physiology: Cell Physiology</jtitle><addtitle>Am J Physiol Cell Physiol</addtitle><date>2014-02-15</date><risdate>2014</risdate><volume>306</volume><issue>4</issue><spage>C334</spage><epage>C342</epage><pages>C334-C342</pages><issn>0363-6143</issn><eissn>1522-1563</eissn><coden>AJPCDD</coden><abstract>To elucidate how tumor cells produce energy in oxygen-depleted microenvironments, we studied the possibility of mitochondrial electron transport without oxygen. We produced well-controlled oxygen gradients (ΔO2) in monolayer-cultured cells. We then visualized oxygen levels and mitochondrial membrane potential (ΔΦm) in individual cells by using the red shift of green fluorescent protein (GFP) fluorescence and a cationic fluorescent dye, respectively. In this two-dimensional tissue model, ΔΦm was abolished in cells >500 μm from the oxygen source [the anoxic front (AF)], indicating limitations in diffusional oxygen delivery. This result perfectly matched GFP-determined ΔO2. In cells pretreated with dimethyloxaloylglycine (DMOG), a prolyl hydroxylase domain-containing protein (PHD) inhibitor, the AF was expanded to 1,500-2,000 μm from the source. In these cells, tissue ΔO2 was substantially decreased, indicating that PHD pathway activation suppressed mitochondrial respiration. The expansion of the AF and the reduction of ΔO2 were much more prominent in a cancer cell line (Hep3B) than in the equivalent fibroblast-like cell line (COS-7). Hence, the results indicate that PHD pathway-activated cells can sustain ΔΦm, despite significantly decreased electron flux to complex IV. Complex II inhibition abolished the effect of DMOG in expanding the AF, although tissue ΔO2 remained shallow. Separate experiments demonstrated that complex II plays a substantial role in sustaining ΔΦm in DMOG-pretreated Hep3B cells with complex III inhibition. From these results, we conclude that PHD pathway activation can sustain ΔΦm in an otherwise anoxic microenvironment by decreasing tissue ΔO2 while activating oxygen-independent electron transport in mitochondria.</abstract><cop>United States</cop><pub>American Physiological Society</pub><pmid>24048731</pmid><doi>10.1152/ajpcell.00255.2013</doi></addata></record> |
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| subjects | Anaerobiosis Animals Cancer Carcinoma, Hepatocellular - metabolism Cell Hypoxia Cell Line, Tumor Cell Respiration Cells Cercopithecus aethiops COS Cells Electron Transport Electron Transport Complex II - metabolism Enzyme Activation Enzymes Fluorescence Humans Liver Neoplasms - enzymology Luminescent Proteins - genetics Luminescent Proteins - metabolism Membrane Potential, Mitochondrial - drug effects Membranes Microscopy, Fluorescence Mitochondria, Liver - drug effects Mitochondria, Liver - metabolism Oxygen Oxygen - metabolism Prolyl Hydroxylases - metabolism Prolyl-Hydroxylase Inhibitors - pharmacology Red shift Transfection Tumor Microenvironment Tumors |
| title | Anaerobic respiration sustains mitochondrial membrane potential in a prolyl hydroxylase pathway-activated cancer cell line in a hypoxic microenvironment |
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