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RESEARCH PRODUCT
Inhibition of tumor lactate oxidation: consequences for the tumor microenvironment.
Morten BuskMichael R. HorsmanTorben SteinicheStefan WalentaSteen JakobsenWolfgang Mueller-klieserJens Overgaardsubject
Monocarboxylic Acid TransportersPasteur effectMice NudeUterine Cervical NeoplasmsImmunoenzyme Techniques03 medical and health sciencesMice0302 clinical medicineLactate oxidationFluorodeoxyglucose F18Cell Line TumorTumor MicroenvironmentPimonidazoleAnimalsRadiology Nuclear Medicine and imaging030304 developmental biologyMonocarboxylate transporter0303 health sciencesTumor microenvironmentbiologySymportersChemistryGlucose analogHematologyTumor OxygenationWarburg effectCell Hypoxia3. Good healthGlucoseOncologyCinnamatesHead and Neck NeoplasmsNitroimidazoles030220 oncology & carcinogenesisImmunologyLuminescent Measurementsbiology.proteinCancer researchCarcinoma Squamous CellLactatesLinear ModelsAutoradiographyFemaleGlycolysisOxidation-Reductiondescription
Abstract Background and purpose Tumor cells are recognized as being highly glycolytic. However, recently it was suggested that lactate produced in hypoxic tumor areas may be taken up by the monocarboxylate transporter MCT1 and oxidized in well-oxygenated tumor parts. Furthermore, it was shown that inhibition of lactate oxidation using the MCT1 inhibitor α-cyano-hydroxycinnamate (CHC) can radio-sensitize tumors possibly by forcing a switch from lactate oxidization to glycolysis in oxygenated cells, which in turn improves tumor oxygenation and indirectly kills radio-resistant hypoxic tumor cells from glucose starvation. Material and methods To provide direct evidence for the existence of a targetable energetic symbiosis, mice bearing SiHa or FaDu dd tumors were treated with CHC for different time periods. One hour prior to sacrifice, mice were administered with the glucose analog fluorodeoxyglucose (FDG) and the hypoxia-marker pimonidazole. Tumor cryosections were analyzed for regional glucose retention (FDG autoradiograms), hypoxia (pimonidazole retention) and glucose and lactate levels (bioluminescence imaging). Results Treatment did not influence metabolite concentrations, necrosis or extent of hypoxia, but pixel-by-pixel analysis comparing FDG retention and hypoxia (a measure of the apparent in vivo Pasteur effect) showed that CHC treatment caused a transient reduction in the Pasteur effect in FaDu dd 1.5h following CHC administration whereas a reduction was only observed in SiHa following repeated treatments. Conclusions In summary, our data show that CHC is able to influence the intratumoral distribution of glucose use between hypoxic and non-hypoxic tumor areas. That is in accordance with a functional tumor lactate-shuttle, but the absence of any detectable changes in hypoxic extent and tissue metabolites was unexpected and warrants further investigation.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2011-01-01 | Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology |