Project description:Glucose transporters are the first and rate-limiting step for cellular glucose usage, which is often exacerbated in tumour cells enabling their growth and proliferation. Although inhibiting glucose metabolism in lung tumours could become an efficient treatment strategy, whether and which glucose transporter(s) should be targeted remains unclear because of their possible functional redundancy, and because other nutrients or transporter-independent metabolic processes including autophagy and macropinocytosis can fuel tumour cell growth in certain contexts. Here we show that glucose transporter Glut1 gene deletion in tumour cells does not impact tumour initiation and only slightly delays progression in a genetically-engineered mouse model of lung adenocarcinoma. Using 13C-glucose tracing with correlated nanoscale secondary ion mass spectrometry (NanoSIMS) and electron microscopy, we report the presence of multiple lamellar body-like organelles produced by tumour cells. Glucose-derived biomass accumulates in these organelles, and this accumulation is decreased in Glut1-deficient tumour cells. Ex vivo, tumour cell glycolysis is impaired in absence of Glut1 except in case of strong expression of another glucose transporter, Glut3. We show that Glut3 is dispensable for Glut1 wild-type tumour development. In contrast, their combined deletion diminishes tumour growth and prevents the appearance of big lesions. Our results demonstrate the requirement for two glucose transporters in lung adenocarcinoma; dual blockade could reach therapeutic responses not achieved by individual targeting. 

Project description:Glucose transporters are the first and rate-limiting step for cellular glucose usage, which is often exacerbated in tumour cells enabling their growth and proliferation. Although inhibiting glucose metabolism in lung tumours could become an efficient treatment strategy, whether and which glucose transporter(s) should be targeted remains unclear because of their possible functional redundancy, and because other nutrients or transporter-independent metabolic processes including autophagy and macropinocytosis can fuel tumour cell growth in certain contexts. Here we show that glucose transporter Glut1 gene deletion in tumour cells does not impact tumour initiation and only slightly delays progression in a genetically-engineered mouse model of lung adenocarcinoma. Using 13C-glucose tracing with correlated nanoscale secondary ion mass spectrometry (NanoSIMS) and electron microscopy, we report the presence of multiple lamellar body-like organelles produced by tumour cells. Glucose-derived biomass accumulates in these organelles, and this accumulation is decreased in Glut1-deficient tumour cells. Ex vivo, tumour cell glycolysis is impaired in absence of Glut1 except in case of strong expression of another glucose transporter, Glut3. We show that Glut3 is dispensable for Glut1 wild-type tumour development. In contrast, their combined deletion diminishes tumour growth and prevents the appearance of big lesions. Our results demonstrate the requirement for two glucose transporters in lung adenocarcinoma; dual blockade could reach therapeutic responses not achieved by individual targeting.

Project description:Glucose transporters are the first and rate-limiting step for cellular glucose usage, which is often exacerbated in tumour cells enabling their growth and proliferation. Although inhibiting glucose metabolism in lung tumours could become an efficient treatment strategy, whether and which glucose transporter(s) should be targeted remains unclear because of their possible functional redundancy, and because other nutrients or transporter-independent metabolic processes including autophagy and macropinocytosis can fuel tumour cell growth in certain contexts. Here we show that glucose transporter Glut1 gene deletion in tumour cells does not impact tumour initiation and only slightly delays progression in a genetically-engineered mouse model of lung adenocarcinoma. Using 13C-glucose tracing with correlated nanoscale secondary ion mass spectrometry (NanoSIMS) and electron microscopy, we report the presence of multiple lamellar body-like organelles produced by tumour cells. Glucose-derived biomass accumulates in these organelles, and this accumulation is decreased in Glut1-deficient tumour cells. Ex vivo, tumour cell glycolysis is impaired in absence of Glut1 except in case of strong expression of another glucose transporter, Glut3. We show that Glut3 is dispensable for Glut1 wild-type tumour development. In contrast, their combined deletion diminishes tumour growth and prevents the appearance of big lesions. Our results demonstrate the requirement for two glucose transporters in lung adenocarcinoma; dual blockade could reach therapeutic responses not achieved by individual targeting.

Project description:Glucose transporters are the first and rate-limiting step for cellular glucose usage, which is often exacerbated in tumour cells enabling their growth and proliferation. Although inhibiting glucose metabolism in lung tumours could become an efficient treatment strategy, whether and which glucose transporter(s) should be targeted remains unclear because of their possible functional redundancy, and because other nutrients or transporter-independent metabolic processes including autophagy and macropinocytosis can fuel tumour cell growth in certain contexts. Here we show that glucose transporter Glut1 gene deletion in tumour cells does not impact tumour initiation and only slightly delays progression in a genetically-engineered mouse model of lung adenocarcinoma. Using 13C-glucose tracing with correlated nanoscale secondary ion mass spectrometry (NanoSIMS) and electron microscopy, we report the presence of multiple lamellar body-like organelles produced by tumour cells. Glucose-derived biomass accumulates in these organelles, and this accumulation is decreased in Glut1-deficient tumour cells. Ex vivo, tumour cell glycolysis is impaired in absence of Glut1 except in case of strong expression of another glucose transporter, Glut3. We show that Glut3 is dispensable for Glut1 wild-type tumour development. In contrast, their combined deletion diminishes tumour growth and prevents the appearance of big lesions. Our results demonstrate the requirement for two glucose transporters in lung adenocarcinoma; dual blockade could reach therapeutic responses not achieved by individual targeting.

Project description:Tumor cells have an increased need for amino acids. Mammalian cells cannot synthesize essential amino acids; they must obtain these amino acids via specific transporters. Glutamine, though a non-essential amino acid, is critical for tumor cells (glutamine addiction). Entry of amino acids into tumor cells is enhanced by upregulation of specific transporters. If the transporters that are specifically induced in tumor cells are identified, blockade of the induced transporters would constitute a logical strategy for cancer treatment. The transporter SLC6A14 is unique and transports all essential amino acids as well as glutamine and is expressed only at low levels in normal tissues, but induced in colon cancer and in ER+ breast cancer. We have now established the potential of this transporter as a drug target for breast cancer treatment using genetic and pharmacologic approaches. We then examined the progression of breast cancer in Polyoma middle T antigen (Py-MT) Tg mouse on Slc6a14+/+ and Slc6a14-/- background using microarray analysis. We have used three Affy-chips for each tumor sample (Group 1: WT/PyMT; Group 2: Slc6a14-KO/PyMT). Three biological replicates were used for each group.

Project description:Tumor cells have an increased need for amino acids. Mammalian cells cannot synthesize essential amino acids; they must obtain these amino acids via specific transporters. Glutamine, though a non-essential amino acid, is critical for tumor cells (glutamine addiction). Entry of amino acids into tumor cells is enhanced by upregulation of specific transporters. If the transporters that are specifically induced in tumor cells are identified, blockade of the induced transporters would constitute a logical strategy for cancer treatment. The transporter SLC6A14 is unique and transports all essential amino acids as well as glutamine and is expressed only at low levels in normal tissues, but induced in colon cancer and in ER+ breast cancer. We have now established the potential of this transporter as a drug target for breast cancer treatment using genetic and pharmacologic approaches. We then examined the progression of breast cancer in Polyoma middle T antigen (Py-MT) Tg mouse on Slc6a14+/+ and Slc6a14-/- background using microarray analysis.

Project description:Treating Saccharomyces cerevisiae cells with myriocin reduces the intracellular free pool of most amino acids. We find that transcriptional changes within the first 6 hours of drug treatment seem to have little impact on free pool changes. Rather the changes are driven early by post-translational events including impaired amino acid transporter activity, due to a reduced rate of sphingolipid biosynthesis, and an increased rate of endocytosis of at least some amino acid transporters, particularly the major methionine transporter Mup1.

Project description:In humans, skeletal muscles comprise nearly 40% of total body mass, which is maintained throughout adulthood by a balance of muscle protein synthesis and breakdown. Cellular amino acid (AA) levels are critical for these processes, and mammalian cells contain transporter proteins that import AAs to maintain homeostasis. Until recently, the control of transporter regulation has largely been studied at the transcriptional and post-translational levels; however, our recent work demonstrates that the RNA-binding protein YBX3 is critical to intracellular sustain AA in human cells. Here we report that YBX3 post-transcriptionally controls the levels of specific AA transporter messenger (m)RNAs in skeletal muscle cells, which impacts the intracellular levels transported by these proteins. Further, we find that reduction of YBX3 protein reduces proliferation during skeletal muscle differentiation, and that YBX3 expression increases substantially during skeletal muscle differentiation, which is independent to changes in itsmRNA levels. Taken together, our findings suggest that YBX3 regulates AA transport in skeletal muscle cells and that its expression is critical to maintain skeletal muscle cell proliferation during differentiation.

Project description:The placenta is critical for mammalian embryonic development because the embryo’s supply of nutrients, including amino acids, depends solely on mother-to-embryo transport through the placenta. However, the molecular mechanisms underlying this amino acid supply are poorly understood. In this study, we focused on the system A amino acid transporters, Slc38a1/SNAT1, Slc38a2/SNAT2, and Slc38a4/SNAT4, which carry neutral, short-side-chain amino acids, to determine their involvement in placental or embryonic development. A triple-target CRISPR screen identified Slc38a4/SNAT4 as the critical amino acid transporter for placental development in mice. We established mouse lines from the CRISPR founders with large deletions in Slc38a4 and found that, consistent with the imprinted paternal expression of Slc38a4/SNAT4 in ther placenta, paternal knockout (KO), but not maternal KO, of Slc38a4/SNAT4 caused placental hypoplasia associated with reduced fetal weight. Immunostaining revealed that SNAT4 was widely expressed in differentiating cytotrophoblasts and maturing trophoblasts at the maternal–fetal interface. A blood metabolome analysis revealed that amino acid concentrations were globally reduced in Slc38a4/SNAT4 mutant embryos. These results indicated that, in mice, SNAT4-mediated amino acid transport plays a major role in both placental and embryonic development. Given that expression of Slc38a4 in placentas is conserved in other species, our Slc38a4/SNAT4 mutant mice could be a promising model for the analysis of placental defects leading to intrauterine growth restriction in mammals.

Project description:Comparative transcriptome analysis revealed that higher expressions of several metal transporter genes (ABC transporters, K+ transporters/channels, yellow stripe-like proteins, Zinc regulated transporter/iron-regulated transporter-like proteins, etc.) are involved in root uptake and translocation capacity in HCW