The function of p53 as a tumour suppressor has been attributed to its ability to promote cell death or permanently inhibit cell proliferation. However, in recent years, it has become clear that p53 can also contribute to cell survival. p53 regulates various metabolic pathways, helping to balance glycolysis and oxidative phosphorylation, limiting the production of reactive oxygen species, and contributing to the ability of cells to adapt to and survive mild metabolic stresses. Although these activities may be integrated into the tumour suppressive functions of p53, deregulation of some elements of the p53-induced response might also provide tumours with a survival advantage.
Previous work has shown that some cancer cells are highly dependent on serine/glycine uptake for proliferation. Although serine and glycine can be interconverted and either might be used for nucleotide synthesis and one-carbon metabolism, we show that exogenous glycine cannot replace serine to support cancer cell proliferation. Cancer cells selectively consumed exogenous serine, which was converted to intracellular glycine and one-carbon units for building nucleotides. Restriction of exogenous glycine or depletion of the glycine cleavage system did not impede proliferation. In the absence of serine, uptake of exogenous glycine was unable to support nucleotide synthesis. Indeed, higher concentrations of glycine inhibited proliferation. Under these conditions, glycine was converted to serine, a reaction that would deplete the one-carbon pool. Providing one-carbon units by adding formate rescued nucleotide synthesis and growth of glycine-fed cells. We conclude that nucleotide synthesis and cancer cell proliferation are supported by serine--rather than glycine--consumption.
Maddocks, O. D. K. et al. (2017) Modulating the therapeutic response of tumours to dietary serine and glycine starvation. Nature, 544(7650), pp. 372-376.There may be differences between this version and the published version. You are advised to consult the publisher's version if you wish to cite from it.http://eprints.gla.ac.uk/140432/ AbstractThe non-essential amino acids serine and glycine are used in multiple anabolic processes that support cancer cell growth and proliferation (reviewed in ref. 1). While some cancer cells upregulate de novo serine synthesis 2,3,4 , many others rely on exogenous serine for optimal growth 5,6,7 . Restriction of dietary serine and glycine can reduce tumour growth in xenograft and allograft models 7,8 . Here we show that this observation translates into more clinically relevant autochthonous tumours in genetically engineered mouse models of intestinal cancer (driven by Apc inactivation) or lymphoma (driven by Myc activation). The increased survival following dietary restriction of serine and glycine in these models was further improved by antagonizing the anti-oxidant response. Disruption of mitochondrial oxidative phosphorylation (using biguanides) led to a complex response that could improve or impede the anti-tumour effect of serine and glycine starvation. Notably, Krasdriven mouse models of pancreatic and intestinal cancers were less responsive to depletion of serine and glycine, reflecting an ability of activated Kras to increase the expression of enzymes that are part of the serine synthesis pathway and thus promote de novo serine synthesis.To assess the effect of dietary serine and glycine (SG) restriction in autochthonous tumour models, we used genetically engineered mouse models (GEMMs) of lymphoma (Eμ-Myc) and intestinal tumours (defective Apc). Eμ-Myc mice develop pre-neoplastic lesions within 28-42 days after birth 9 , and adenoma initiation is evident days after birth in Apc Min/+ mice 10 . Accordingly, Apc Min/+ mice carried high tumour numbers at 80 days, which subsequently increased in size but not number (Extended Data Fig. 1a). Transferring mice from normal chow diet to experimental diets 60-80 days after birth showed that an SG-free diet significantly extended survival in these models carrying pre-malignant lesions (Fig. 1a, b), with a slightly lower tumour burden in Apc Min/+ mice on the SG-free diet at clinical end point (Extended Data Fig. 1a). The diet reproducibly decreased serum SG from around 150 μM to 65 μM (Fig. 1c-e), while showing minimal or inconsistent impact on other amino acids, glucose and lactate (Fig. 1c, d and Extended Data Figs 1b, 2a, b), These results were further validated using an inducible intestinal tumour model (Lgr5-creER;Apc fl/fl ); transferring mice to the SG-free diet a week after induction. Again, the experimental diet caused a significant increase in survival compared to control diet (containing purified amino acids) or normal chow (containing whole protein as a source of amino acids) (Fig. 1f). (c, control, n = 14; control,...
SummaryCrosstalk between cellular metabolism and the epigenome regulates epigenetic and metabolic homeostasis and normal cell behavior. Changes in cancer cell metabolism can directly impact epigenetic regulation and promote transformation. Here we analyzed the contribution of methionine and serine metabolism to methylation of DNA and RNA. Serine can contribute to this pathway by providing one-carbon units to regenerate methionine from homocysteine. While we observed this contribution under methionine-depleted conditions, unexpectedly, we found that serine supported the methionine cycle in the presence and absence of methionine through de novo ATP synthesis. Serine starvation increased the methionine/S-adenosyl methionine ratio, decreasing the transfer of methyl groups to DNA and RNA. While serine starvation dramatically decreased ATP levels, this was accompanied by lower AMP and did not activate AMPK. This work highlights the difference between ATP turnover and new ATP synthesis and defines a vital function of nucleotide synthesis beyond making nucleic acids.
Serine catabolism results in formate efflux that exceeds anabolic demands for purine synthesis.
SummaryCancer cells reprogram their metabolism, altering both uptake and utilization of extracellular nutrients. We individually depleted amino acid nutrients from isogenic cells expressing commonly activated oncogenes to identify correspondences between nutrient supply and viability. In HME (human mammary epithelial) cells, deprivation of cystine led to increased cell death in cells expressing an activated epidermal growth factor receptor (EGFR) mutant. Cell death occurred via synchronous ferroptosis, with generation of reactive oxygen species (ROS). Hydrogen peroxide promoted cell death, as both catalase and inhibition of NADPH oxidase 4 (NOX4) blocked ferroptosis. Blockade of EGFR or mitogen-activated protein kinase (MAPK) signaling similarly protected cells from ferroptosis, whereas treatment of xenografts derived from EGFR mutant non-small-cell lung cancer (NSCLC) with a cystine-depleting enzyme inhibited tumor growth in mice. Collectively, our results identify a potentially exploitable sensitization of some EGFR/MAPK-driven tumors to ferroptosis following cystine depletion.
SummaryNumerous mechanisms to support cells under conditions of transient nutrient starvation have been described. Several functions of the tumor-suppressor protein p53 can contribute to the adaptation of cells to metabolic stress and help cancer cell survival under nutrient-limiting conditions. We show here that p53 promotes the expression of SLC1A3, an aspartate/glutamate transporter that allows the utilization of aspartate to support cells in the absence of extracellular glutamine. Under glutamine deprivation, SLC1A3 expression maintains electron transport chain and tricarboxylic acid cycle activity, promoting de novo glutamate, glutamine, and nucleotide synthesis to rescue cell viability. Tumor cells with high levels of SLC1A3 expression are resistant to glutamine starvation, and SLC1A3 depletion retards the growth of these cells in vitro and in vivo, suggesting a therapeutic potential for SLC1A3 inhibition.
Highlights d ROS regulation by TIGAR supports premalignant pancreas tumor development d Increased ROS following TIGAR or Nrf2 loss enhance metastasis d ROS reduce DUSP6 expression to activate ERK and increase invasion and migration d TIGAR and ROS levels are dynamically regulated throughout tumor progression
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