Project description:The TP53 tumor suppressor is frequently altered in lethal, castration-resistant prostate cancer (CRPC). However, to date there are no effective treatments that specifically target TP53 alterations. Using transcriptomic and metabolomic analyses, we show here that TP53-altered prostate cancer (PCa) exhibits an increased dependency on asparagine and overexpresses asparagine synthetase (ASNS, the enzyme catalyzing the synthesis of asparagine). Mechanistically, loss/mutation of TP53 transcriptionally activate ASNS expression, directly as well as via ATF4, driving de novo asparagine biosynthesis to support CRPC growth. TP53-altered CRPC cells are sensitive to asparagine restriction by knockdown of ASNS and L-asparaginase treatment to deplete the intracellular and extracellular sources of asparagine respectively. This effect was rescued by asparagine addition. Notably, pharmacological inhibition of intracellular asparagine biosynthesis using a glutaminase (GLS) inhibitor and depletion of extracellular asparagine with L-asparaginase significantly reduced asparagine production and effectively impaired CRPC growth. This study highlights the significance of ASNS-mediated metabolic adaptation as a synthetic vulnerability in CRPC with TP53 alterations, providing a rationale for co-targeting intracellular and extracellular asparagine production to treat these lethal prostate cancers.

Project description:The TP53 tumor suppressor is frequently altered in lethal, castration-resistant prostate cancer (CRPC). However, to date there are no effective treatments that specifically target TP53 alterations. Using transcriptomic and metabolomic analyses, we show here that TP53-altered prostate cancer (PCa) exhibits an increased dependency on asparagine and overexpresses asparagine synthetase (ASNS, the enzyme catalyzing the synthesis of asparagine). Mechanistically, loss/mutation of TP53 transcriptionally activate ASNS expression, directly as well as via ATF4, driving de novo asparagine biosynthesis to support CRPC growth. TP53-altered CRPC cells are sensitive to asparagine restriction by knockdown of ASNS and L-asparaginase treatment to deplete the intracellular and extracellular sources of asparagine respectively. This effect was rescued by asparagine addition. Notably, pharmacological inhibition of intracellular asparagine biosynthesis using a glutaminase (GLS) inhibitor and depletion of extracellular asparagine with L-asparaginase significantly reduced asparagine production and effectively impaired CRPC growth. This study highlights the significance of ASNS-mediated metabolic adaptation as a synthetic vulnerability in CRPC with TP53 alterations, providing a rationale for co-targeting intracellular and extracellular asparagine production to treat these lethal prostate cancers.

Project description:Glutamine is a key nutrient for tumor cells that supports nucleotide and amino acid biosynthesis, replenishes the TCA cycle intermediates and contributes to redox metabolism. We identified oncogenic KRAS as a critical regulator of the response to glutamine deprivation in NSCLC. Full activation of the ATF4 stress response pathway is dependent on expression of NRF2 downstream of oncogenic KRAS in NSCLC. Through this mechanism, KRAS alters amino acid uptake and metabolism and sustains mTORC1 signaling during nutrient stress. Furthermore, we identified regulation of asparagine synthetase (ASNS) as a key effect of oncogenic KRAS signaling via ATF4 during glutamine deprivation, and a potential therapeutic target in KRAS mutant NSCLC.

Project description:Glutamine is a key nutrient for tumor cells that supports nucleotide and amino acid biosynthesis, replenishes the TCA cycle intermediates and contributes to redox metabolism. We identified oncogenic KRAS as a critical regulator of the response to glutamine deprivation in NSCLC. Full activation of the ATF4 stress response pathway is dependent on expression of NRF2 downstream of oncogenic KRAS in NSCLC. Through this mechanism, KRAS alters amino acid uptake and metabolism and sustains mTORC1 signaling during nutrient stress. Furthermore, we identified regulation of asparagine synthetase (ASNS) as a key effect of oncogenic KRAS signaling via ATF4 during glutamine deprivation, and a potential therapeutic target in KRAS mutant NSCLC.

Project description:Glutamine is a key nutrient for tumor cells that supports nucleotide and amino acid biosynthesis, replenishes the TCA cycle intermediates and contributes to redox metabolism. We identified oncogenic KRAS as a critical regulator of the response to glutamine deprivation in NSCLC. Full activation of the ATF4 stress response pathway is dependent on expression of NRF2 downstream of oncogenic KRAS in NSCLC. Through this mechanism, KRAS alters amino acid uptake and metabolism and sustains mTORC1 signaling during nutrient stress. Furthermore, we identified regulation of asparagine synthetase (ASNS) as a key effect of oncogenic KRAS signaling via ATF4 during glutamine deprivation, and a potential therapeutic target in KRAS mutant NSCLC.

Project description:Asparagine synthetase (ASNS) is a gene on the long arm of chromosome 7 that is copy number amplified in the majority of glioblastomas. ASNS copy number amplification is associated with a significantly decreased survival. Using patient-derived glioma stem cells (GSCs), we showed significant metabolic alterations occur in gliomas when perturbing the expression of asparagine synthetase, which is not merely restricted to amino acid homeostasis. ASNS-high GSCs maintained a slower basal metabolic profile yet readily shifted to a greatly increased capacity for glycolysis and oxidative phosphorylation when needed. This led ASNS-high cells to a greater ability to proliferate and spread into brain tissue. Finally, we demonstrate that these changes confer resistance to cellular stress, notably oxidative stress, through adaptive redox homeostasis which led to radiation resistance. Furthermore, ASNS overexpression led to modifications of the one-carbon metabolism to promote a more antioxidant tumor environment revealing a metabolic vulnerability that may be therapeutically exploited.

Project description:Germinal centre (GC) B cells proliferate at some of the highest rates of any mammalian cell. Yet the metabolic processes which enable this are poorly understood. We performed integrated metabolomic and transcriptomic profiling of GC B cells, and found that asparagine metabolism is highly upregulated. Asparagine is conditionally essential to B cells, and its synthetic enzyme, asparagine synthetase (ASNS) is markedly upregulated following their activation, through the integrated stress response sensor general control non-derepressible 2 (GCN2). When Asns is deleted, B cell survival in low asparagine conditions is severely impaired. Using stable isotope tracing, we found that metabolic adaptation to the absence of asparagine requires ASNS, and that the synthesis of nucleotides is particularly sensitive to asparagine deprivation. Conditional deletion of Asns in B cells selectively impairs GC formation, associated with a reduction in RNA synthesis rates. Finally, removal of environmental asparagine by asparaginase was found to also severely compromise the GC reaction.

Project description:Asparagine deprivation by L-Asparaginase is a successful therapeutic strategy in Acute Lymphoblastic Leukemia, with resistance occurring due to upregulation of ASNS. L-Asparaginase efficacy in solid tumors is hampered by dose-related toxicities. Large scale loss of function genetic screens identified ASNS, the only human enzyme synthetizing asparagine, as a cancer dependency in several solid malignancies, including melanoma. We here evaluate the therapeutic potential of targeting ASNS in melanoma cells in-vitro and in-vivo. Using ex-vivo quantitative proteome and transcriptome profiling, we observed that concomitant ASNS deletion and asparagine deprivation elicit a compensatory mechanism allowing tumor growth. Genome wide CRISPR screens upon manipulation of aminoacid levels identifies MAPK and GCN2 as critical nodes mediating the observed resistance mechanism. Importantly MEK and GCN2 inhibitor synergize with L-Asparaginase suggesting novel potential therapeutic strategy in melanoma.

Project description:CRISPR/Cas9-based genetic screening revealed ZBTB1 as a critical mediator of the response of T-ALL cells to asparagine deprivation. ZBTB1 regulates the transcription of ASNS, a transcriptional target of ATF4. Loss of ZBTB1 results in decreased transcription and expression of ASNS. ChIP-Sequencing reveals that both ATF4 and ZBTB1 enrich in the promoter of ASNS. This dataset contains the RNA-Seq, ChIP-Seq and ATAC-Seq data on three different cell lines (WT Jurkat cells, ZBTB1 knockout Jurkat cells and ZBTB1 knockout Jurkat cells expressing ZBTB1 cDNA) in support of these findings.

Project description:Survival differences exist in colorectal cancer (CRC) patients by sex and disease stage. However, the potential molecular mechanism(s) are not well understood. Here we show that asparagine synthetase (ASNS) and G protein-coupled estrogen receptor-1 (GPER1) are critical sensors of nutrient depletion and linked to poorer outcomes for females with CRC. In a 3D spheroid model of isogenic SW48 KRAS wild-type (WT) and G12A mutant (MT) cells grown under a restricted nutrient supply, we found that glutamine depletion inhibited cell growth in both cell types, whereas ASNS and GPER1 expression were upregulated in KRAS MT versus WT. Estradiol decreased growth in KRAS WT but had no effect on MT cells. In a clinical colon cancer cohort of The Cancer Genome Atlas, both high GPER1 and ASNS expression were associated with poorer overall survival for females only in advanced stage tumors. These results suggest KRAS MT cells have mechanisms in place that respond to decreased nutrient supply, typically observed in advanced tumors, by increasing the expression of ASNS and GPER1 to drive cell growth. Furthermore, KRAS MT cells are resistant to the protective effects of estradiol under nutrient deplete conditions. The findings indicate that GPER1 and ASNS expression in the link of nutrient supply and KRAS mutations shed additional light on the mechanisms behind sex differences in metabolism and growth in CRC and have clinical implications in the precision management of KRAS MT CRC.