Intracellular Glutamine Research Articles

The Role of Dicer Phosphorylation in Gemcitabine Resistance of Pancreatic Cancer.

Dicer, a cytoplasmic type III RNase, is essential for the maturation of microRNAs (miRNAs) and is implicated in cancer progression and chemoresistance. Our previous research demonstrated that phosphorylation of Dicer at S1016 alters miRNA maturation and glutamine metabolism, contributing to gemcitabine (GEM) resistance in pancreatic ductal adenocarcinoma (PDAC). In this study, we focused on the role of Dicer phosphorylation at S1728/S1852 in GEM-resistant PDAC cells. Using shRNA to knock down Dicer in GEM-resistant PANC-1 (PANC-1 GR) cells, we examined cell viability through MTT and clonogenic assays. We also expressed phosphomimetic Dicer 2E (S1728E/S1852E) and phosphomutant Dicer 2A (S1728A/S1852A) to evaluate their effects on GEM resistance and metabolism. Our results show that phosphorylation at S1728/S1852 promotes GEM resistance by reprogramming glutamine metabolism. Specifically, phosphomimetic Dicer 2E increased intracellular glutamine, driving pyrimidine synthesis and raising dCTP levels, which compete with gemcitabine's metabolites. This metabolic shift enhanced drug resistance. In contrast, phosphomutant Dicer 2A reduced GEM resistance. These findings highlight the importance of Dicer phosphorylation in regulating metabolism and drug sensitivity, offering insights into potential therapeutic strategies for overcoming GEM resistance in pancreatic cancer.

Macropinocytosis mediates resistance to loss of glutamine transport in triple-negative breast cancer.

Triple-negative breast cancer (TNBC) metabolism and cell growth uniquely rely on glutamine uptake by the transporter ASCT2. Despite previous data reporting cell growth inhibition after ASCT2 knockdown, we here show that ASCT2 CRISPR knockout is tolerated by TNBC cell lines. Despite the loss of a glutamine transporter and low rate of glutamine uptake, intracellular glutamine steady-state levels were increased in ASCT2 knockout compared to control cells. Proteomics analysis revealed upregulation of macropinocytosis, reduction in glutamine efflux and increased glutamine synthesis in ASCT2 knockout cells. Deletion of ASCT2 in the TNBC cell line HCC1806 induced a strong increase in macropinocytosis across five ASCT2 knockout clones, compared to a modest increase in ASCT2 knockdown. In contrast, ASCT2 knockout impaired cell proliferation in the non-macropinocytic HCC1569 breast cancer cells. These data identify macropinocytosis as a critical secondary glutamine acquisition pathway in TNBC and a novel resistance mechanism to strategies targeting glutamine uptake alone. Despite this adaptation, TNBC cells continue to rely on glutamine metabolism for their growth, providing a rationale for targeting of more downstream glutamine metabolism components.

Orientia tsutsugamushi infection reduces host gluconeogenic but not glycolytic substrates.

Orientia tsutsugamushi a causal agent of scrub typhus, is an obligate intracellular bacterium that, akin to other rickettsiae, is dependent on host cell-derived nutrients for survival and thus pathogenesis. Based on limited experimental evidence and genome-based in silico predictions, O. tsutsugamushi is hypothesized to parasitize host central carbon metabolism (CCM). Here, we (re-)evaluated O. tsutsugamushi dependency on host cell CCM as initiated by glucose and glutamine. Orientia infection had no effect on host glucose and glutamine consumption or lactate accumulation, indicating no change in overall flux through CCM. However, host cell mitochondrial activity and ATP levels were reduced during infection and correspond with lower intracellular glutamine and glutamate pools. To further probe the essentiality of host CCM in O. tsutsugamushi proliferation, we developed a minimal medium for host cell cultivation and paired it with chemical inhibitors to restrict the intermediates and processes related to glucose and glutamine metabolism. These conditions failed to negatively impact O. tsutsugamushi intracellular growth, suggesting the bacterium is adept at scavenging from host CCM. Accordingly, untargeted metabolomics was utilized to evaluate minor changes in host CCM metabolic intermediates across O. tsutsugamushi infection and revealed that pathogen proliferation corresponds with reductions in critical CCM building blocks, including amino acids and TCA cycle intermediates, as well as increases in lipid catabolism. This study directly correlates O. tsutsugamushi proliferation to alterations in host CCM and identifies metabolic intermediates that are likely critical for pathogen fitness.IMPORTANCEObligate intracellular bacterial pathogens have evolved strategies to reside and proliferate within the eukaryotic intracellular environment. At the crux of this parasitism is the balance between host and pathogen metabolic requirements. The physiological basis driving O. tsutsugamushi dependency on its mammalian host remains undefined. By evaluating alterations in host metabolism during O. tsutsugamushi proliferation, we discovered that bacterial growth is independent of the host's nutritional environment but appears dependent on host gluconeogenic substrates, including amino acids. Given that O. tsutsugamushi replication is essential for its virulence, this study provides experimental evidence for the first time in the post-genomic era of metabolic intermediates potentially parasitized by a scrub typhus agent.

Glutamate is a key nutrient for Porphyromonas gingivalis growth and survival during intracellular autophagic life under nutritionally limited conditions.

This study reveals that P. gingivalis heavily depends on preferential utilization of Glutamate (Glu) for autophagic vacuolar growth and survival in human GECs. Several novel observations are made to support this: (i) GdhA of P. gingivalis is highly enriched in these vacuoles, (ii) P. gingivalis induces a large conversion of intracellular glutamine to Glu, (iii) size of vacuoles are significantly increased in the presence of Glu-Glu in P. gingivalis wild-type strain infection which is opposite in a Δ gdhA strain, (iv) P. gingivalis uptakes 14 C-Glu and preferentially utilizes Glu-Glu dipeptide, (v) similarly, wild-type strain shows growth increase in a nutritionally reduced bacterial culture media, and (vi) finally, Glu-Glu supplementation increases bacterial cell-volume of P. gingivalis wild-type but not Δ gdhA strain, an indicator of higher metabolism and growth. Taken together, this study highlights the pathophysiological importance of Glu for P. gingivalis growth-rate, biomass induction and survival in nutritionally limited host subcellular environments.

PoRVA G9P[23] and G5P[7] infections differentially promote PEDV replication by reprogramming glutamine metabolism.

PoRVA and PEDV coinfections are extremely common in clinical practice. Although coinfections of PoRVA and PEDV are known to result in increased mortality, the underlying mechanism remains unknown. Here, we found that PoRVA infection promoted PEDV infection in vivo and in vitro and that PoRVA G9P[23] (RVA-HNNY strain) enhanced PEDV replication more significantly than did PoRVA G5P[7] (RVA-SXXA strain). Metabolomic analysis revealed that RVA-HNNY more efficiently induced an increase in the intracellular glutamine content in porcine small intestinal epithelial cells than did RVA-SXXA, which more markedly promoted ATP production to facilitate PEDV replication, whereas glutamine deprivation abrogated the effect of PoRVA infection on promoting PEDV replication. Further studies showed that PoRVA infection promoted glutamine uptake by upregulating the expression of the glutamine transporter protein SLC1A5. In SLC1A5 knockout cells, PoRVA infection neither elevated intracellular glutamine nor promoted PEDV replication. During PoRVA infection, the activity and protein expression levels of glutamine catabolism-related enzymes (GLS1 and GLUD1) were also significantly increased promoting ATP production through glutamine anaplerosis into the TCA cycle. Consistent with that, siRNAs or inhibitors of GLS1 and GLUD1 significantly inhibited the promotion of PEDV replication by PoRVA. Notably, RVA-HNNY infection more markedly promoted SLC1A5, GLS1 and GLUD1 expression to more significantly increase the uptake and catabolism of glutamine than RVA-SXXA infection. Collectively, our findings illuminate a novel mechanism by which PoRVA infection promotes PEDV infection and reveal that the modulation of glutamine uptake is key for the different efficiencies of PoRVA G9P[23] and PoRVA G5P[7] in promoting PEDV replication.

METTL3-mediated m6A methylation of SLC38A1 stimulates cervical cancer growth

The objective of this study was to better characterize the role of the glutamine transporter SLC38A1 in cervical cancer and explore the underlying mechanisms. Data from public databases and clinical cervical cancer tissue samples were used to assess the expression of SLC38A1 and its prognostic significance. Immunohistochemical staining, qRT-PCR, and Western blotting were used to evaluate the expression of relevant genes and proteins. Cell viability, cell cycle, apoptosis, and intracellular glutamine content were measured using CCK-8, flow cytometry, and biochemical assays. Additionally, the RNA immunoprecipitation (RIP) assay was used to examine the impact of METTL3/IGF2BP3 on the m6A modification of the SLC38A1 3′UTR. Both cervical cancer specimens and cells showed significantly increased expression of SLC38A1 and its expression correlated with an unfavorable prognosis. Knockdown of SLC38A1 inhibited cell viability and cell cycle progression, induced apoptosis, and suppressed tumor growth in vivo. Glutaminase-1 inhibitor CB-839 reversed the effects of SLC38A1 overexpression. METTL3 promoted m6A modification of SLC38A1 and enhanced its mRNA stability through IGF2BP3 recruitment. Moreover, METTL3 silencing inhibited cell viability, cell cycle progression, intracellular glutamine content, and induced apoptosis, but these effects were reversed by SLC38A1 overexpression. In conclusion, METTL3-mediated m6A methylation of SLC38A1 stimulates cervical cancer progression. SLC38A1 inhibition is a potential therapeutic strategy for cervical cancer.

Gefitinib Induces Apoptosis in NSCLC Cells by Promoting Glutaminolysis and Inhibiting the MEK/ERK Signaling Pathway.

Over 80% of lung cancer cases constitute non-small cell lung cancer (NSCLC), making it the most prevalent type of lung cancer globally and the leading cause of cancer-related deaths. The treatment of NSCLC patients with gefitinib has demonstrated promising initial efficacy. However, the underlying mechanism remains unclear. This study aims to investigate how gefitinib affects the mitogen-activated protein kinase kinase (MEK)/extracellular regulated protein kinases (ERK) signaling pathway-mediated growth and death of NSCLC cells. In this study, the NSCLC cell line A549 was cultured in vitro and divided into a control group and a gefitinib group. The viability of the A549 cells was assessed using the methylthiazolyldiphenyl-tetrazolium bromide (MTT) assay. Flow cytometry was employed to detect apoptosis in A549 cells, and the expression of glutamate dehydrogenase (GDH1) mRNA in these cells was determined using real-time quantitative PCR (RT-PCR). Western blotting was utilized to evaluate the protein expression levels of key components in the MEK/ERK signaling pathway, including phospho-MEK1/2, MEK1/2, phospho-ERK1/2, and ERK1/2. Additionally, intracellular glutamine content in A549 cells was measured using a colorimetric method. In contrast to the control group, the proliferation of A549 cells, the transcription level of glutamate dehydrogenase (GDH1), the intracellular glutamine content, and the protein expression levels of phospho-MEK1/2 and phospho-ERK1/2 were significantly lower in the gefitinib group. Moreover, apoptosis markedly increased. Gefitinib expedites apoptosis and diminishes proliferation in the NSCLC cell line A549 by downregulating the epidermal growth factor receptor (EGFR)/MEK/ERK signaling pathway. This effect is accomplished by fostering the expression of GDH1 to augment glutaminolysis in A549 cells.

Temporal dynamics of stress response in Halomonas elongata to NaCl shock: physiological, metabolomic, and transcriptomic insights

BackgroundThe halophilic bacterium Halomonas elongata is an industrially important strain for ectoine production, with high value and intense research focus. While existing studies primarily delve into the adaptive mechanisms of this bacterium under fixed salt concentrations, there is a notable dearth of attention regarding its response to fluctuating saline environments. Consequently, the stress response of H. elongata to salt shock remains inadequately understood.ResultsThis study investigated the stress response mechanism of H. elongata when exposed to NaCl shock at short- and long-time scales. Results showed that NaCl shock induced two major stresses, namely osmotic stress and oxidative stress. In response to the former, within the cell’s tolerable range (1–8% NaCl shock), H. elongata urgently balanced the surging osmotic pressure by uptaking sodium and potassium ions and augmenting intracellular amino acid pools, particularly glutamate and glutamine. However, ectoine content started to increase until 20 min post-shock, rapidly becoming the dominant osmoprotectant, and reaching the maximum productivity (1450 ± 99 mg/L/h). Transcriptomic data also confirmed the delayed response in ectoine biosynthesis, and we speculate that this might be attributed to an intracellular energy crisis caused by NaCl shock. In response to oxidative stress, transcription factor cysB was significantly upregulated, positively regulating the sulfur metabolism and cysteine biosynthesis. Furthermore, the upregulation of the crucial peroxidase gene (HELO_RS18165) and the simultaneous enhancement of peroxidase (POD) and catalase (CAT) activities collectively constitute the antioxidant defense in H. elongata following shock. When exceeding the tolerance threshold of H. elongata (1–13% NaCl shock), the sustained compromised energy status, resulting from the pronounced inhibition of the respiratory chain and ATP synthase, may be a crucial factor leading to the stagnation of both cell growth and ectoine biosynthesis.ConclusionsThis study conducted a comprehensive analysis of H. elongata’s stress response to NaCl shock at multiple scales. It extends the understanding of stress response of halophilic bacteria to NaCl shock and provides promising theoretical insights to guide future improvements in optimizing industrial ectoine production.

Effects of Neuromuscular Electrical Stimulation in Combination with Glutamine Administration on Skeletal Muscle Atrophy in Colon-26 Tumor-Bearing Mice

The depressed protein synthetic response, a phenomenon termed anabolic resistance, has been shown to be involved in muscle wasting induced by cancer cachexia. Moreover, a positive relationship between the protein synthetic rate and intracellular glutamine (GLN) concentration has been found in skeletal muscles. This study investigated the effects of neuromuscular electrical stimulation (ES) and GLN administration on muscle wasting and GLN metabolism in colon-26 (C-26) tumor-bearing mice. CD2F1 mice were divided into 8 groups: control (CNT), CNT+ES, CNT+GLN, CNT+ES+GLN, C-26, C-26+ES, C-26+GLN, C-26+ES+GLN. Cancer cachexia was induced by subcutaneous injection of C-26 cells and developed for four weeks. ES was performed on the left plantar flexor muscles every other day, and GLN (1 g/kg) was administered daily intraperitoneally starting one day after the C-26 injection. Tumor-free body mass and fast-twitch gastrocnemius (Gas) muscle weight were lower in the C-26 group than in the CNT group (-19% and -17%, respectively). Neither ES training nor GLN administration, alone or in combination, ameliorated the loss of Gas muscle weight in the C-26 mice. However, ES training in combination with GLN administration inhibited the increased expression of GLN synthetase (GS) in the C-26 muscles. Thus, it is likely that GLN plays a critical role in muscle protein metabolism and, therefore, can be targeted as a tentative treatment of cancer cachexia.

Gefitinib Induces Apoptosis of Gastric Cancer Cells by Promoting Glutaminolysis Through the MEK/ERK Signaling Pathway

We aimed to investigate the effect of gefitinib on the proliferation and apoptosis of gastric cancer (GC) cells through the MEK/ERK signaling pathway. The GC cell line NCI-N87 was cultured in vitro and divided into a control group and a gefitinib group. Cell viability for NCI-N87 was determined using the MTT test. The amount of apoptosis in NCI-N87 cells was measured using flow cytometry. Real-time quantitative PCR was used to measure GDH1 mRNA expression in NCI-N87 cells. P-MEK1/2, MEK1/2, P-ERK1/2, and ERK1/2 protein expression levels in NCI-N87 cells were determined using Western blotting. An assay kit for measuring glutamine was used to determine the intracellular glutamine concentration of NCI-N87 cells. The proliferative activity of NCI-N87 cells was significantly inhibited in the gefitinib group compared to the control group, along with the transcription level of GDH1, intracellular glutamine content, intracellular glutamine content reduction, and p-MEK1/2 and p-ERK1/2 protein expression levels. Gefitinib inhibits proliferation and promotes apoptosis in the GC cell line NCI-N87 by downregulating the EGFR/MEK/ERK signaling pathway. Mechanistically, it is achieved by promoting the expression of GDH1 to promote glutaminolysis in NCI-N87 cells.

Canagliflozin reduces chemoresistance in hepatocellular carcinoma through PKM2-c-Myc complex-mediated glutamine starvation

Cisplatin (CPT) is one of the standard treatments for hepatocellular carcinoma (HCC). However, its use is limits as a monotherapy due to drug resistance, and the underlying mechanism remains unclear. To solve this problem, we tried using canagliflozin (CANA), a clinical drug for diabetes, to reduce chemoresistance to CPT, and the result showed that CANA could vigorously inhibit cell proliferation and migration independent of the original target SGLT2. Mechanistically, CANA reduced aerobic glycolysis in HCC by targeting PKM2. The downregulated PKM2 directly bound to the transcription factor c-Myc in the cytoplasm to form a complex, which upregulated the level of phosphorylated c-Myc Thr58 and promoted the ubiquitination and degradation of c-Myc. Decreased c-Myc reduced the expression of GLS1, a key enzyme in glutamine metabolism, leading to impaired glutamine utilization. Finally, intracellular glutamine starvation induced ferroptosis and sensitized HCC to CPT. In conclusion, our study showed that CANA re-sensitized HCC to CPT by inducing ferroptosis through dual effects on glycolysis and glutamine metabolism. This is a novel mechanism to increase chemosensitivity, which may provide compatible chemotherapy drugs for HCC.

Activated protein C modulates T-cell metabolism and epigenetic FOXP3 induction via α-ketoglutarate.

A direct regulation of adaptive immunity by the coagulation protease activated protein C (aPC) has recently been established. Preincubation of T cells with aPC for 1 hour before transplantation increases FOXP3+ regulatory T cells (Tregs) and reduces acute graft-versus-host disease (aGVHD) in mice, but the underlying mechanism remains unknown. Because cellular metabolism modulates epigenetic gene regulation and plasticity in T cells, we hypothesized that aPC promotes FOXP3+ expression by altering T-cell metabolism. To this end, T-cell differentiation was assessed invitro using mixed lymphocyte reaction or plate-bound α-CD3/CD28 stimulation, and exvivo using T cells isolated from mice with aGVHD without and with aPC preincubation, or analyses of mice with high plasma aPC levels. In stimulated CD4+CD25- cells, aPC induces FOXP3 expression while reducing expression of T helper type 1 cell markers. Increased FOXP3 expression is associated with altered epigenetic markers (reduced 5-methylcytosine and H3K27me3) and reduced Foxp3 promoter methylation and activity. These changes are linked to metabolic quiescence, decreased glucose and glutamine uptake, decreased mitochondrial metabolism (reduced tricarboxylic acid metabolites and mitochondrial membrane potential), and decreased intracellular glutamine and α-ketoglutarate levels. In mice with high aPC plasma levels, T-cell subpopulations in the thymus are not altered, reflecting normal T-cell development, whereas FOXP3 expression in splenic T cells is reduced. Glutamine and α-ketoglutarate substitution reverse aPC-mediated FOXP3+ induction and abolish aPC-mediated suppression of allogeneic T-cell stimulation. These findings show that aPC modulates cellular metabolism in T cells, reducing glutamine and α-ketoglutarate levels, which results in altered epigenetic markers, Foxp3 promoter demethylation and induction of FOXP3 expression, thus favoring a Treg-like phenotype.

Modeling of glycosaminoglycan biosynthesis in intervertebral disc cells

Loss of proteoglycan (PG) is a potential factor responsible for degeneration of the intervertebral disc (IVD). PG consists of a core protein with covalently attached glycosaminoglycan (GAG) chains. The objective of this study was to develop a mathematical model of GAG biosynthesis to investigate the effects of glycolytic enzymes on GAG biosynthesis of IVD cells. A new mathematical model of GAG biosynthesis was developed for IVD cells by incorporating biosynthesis of uridine diphosphate-sugars into the glycolytic pathway. This new model showed good agreement between the model predictions of intracellular ATP content and GAG biosynthesis and experimental data measured at different external glucose levels. The quantitative analyses demonstrated that GAG biosynthesis may be sensitive to the activities of hexokinase (HK) and phosphofructokinase (PFK), especially at low glucose supply, with GAG biosynthesis being significantly enhanced by a slight increase in activities of HK and PFK. This suggests that metabolic reprogramming could be a potential strategy for promoting PG biosynthesis in IVD cells. Furthermore, it was shown that GAG biosynthesis may be promoted by increasing intracellular glutamine concentration or activity of glutamine:fructose-6-phosphate amidotransferase in the hexamine pathway. This study provides a better understanding of the relationship between glycolysis and PG biosynthesis in IVD cells. The theoretical framework developed in this study is useful for studying the role of glycolysis in disc degeneration and developing new preventive and treatment strategies for degeneration of the IVD.

GCN2 kinase-mediated upregulation of ubiquitin C maintains intracellular glutamine level and tRNAGln (CUG) charging under amino acid starvation.

Each tRNA is aminoacylated (charged) with a genetic codon-specific amino acid. It remains unclear what factors are associated with tRNA charging and how tRNA charging is maintained. By using the individual tRNA acylation PCR (i-tRAP) method, we found that the charging ratio of tRNAGln (CUG) reflects cellular glutamine level. When uncharged tRNAGln (CUG) increased under amino acid starvation, the kinase GCN2, which is a key stimulator of the integrated stress response, was activated. Activation of GCN2 led to the upregulation of ubiquitin C (UBC) expression. Upregulated UBC, in turn, suppressed the further reduction of tRNAGln (CUG) charging levels. Thus, tRNA charging is sensitive to intracellular nutrient status and is an important initiator of intracellular signaling.

Transpulmonary amino acid metabolism in the sugen hypoxia model of pulmonary hypertension

Background: Pulmonary arterial hypertension (PAH) is characterized by narrowing of the pulmonary arteries, endothelial cell dysfunction, and an increased vascular cell proliferation. Increased proliferation is also accompanied by glycolytic shift, where glucose is shunted towards anaerobic respiration and production of critical macromolecules. This decreases the available glucose that can be used as a fuel in the tricarboxylic acid (TCA) cycle. To compensate for the lack of TCA cycle metabolites, there is an increase in the use of non-glucose fuels - such as amino acids and fatty acids. However, the effect of this shift on other metabolic pathways is still unknown. In this study, we investigated the levels of metabolites across the pulmonary circulation to define the metabolic shift that cells undergo during PAH. Material & Methods: We carried out metabolomic analysis on serum samples taken from the right and left ventricles (RV and LV) of rats with PAH (SU5416/Hypoxia model: SuHx) and normoxic controls. We also isolated MVECs from each group and performed both targeted and untargeted metabolomics on the cell lysates. Results: Induction of PAH resulted in increased pulmonary artery pressures and RV hypertrophy. Metabolomics of the RV serum were different in PAH versus control rats. This was driven by lower metabolite levels of several amino acids, including glutamine, phenylalanine, and valine. Normoxia- and SuHx-MVEC lysates samples were also distinct, with increased levels of lactic acid contributing significantly to the differences between animals with PAH and controls. Importantly, and in contrast to the serum, where glutamine levels were decreased, we observed increased levels of intracellular glutamine in our analysis. Similarly, intracellular levels of amino acids like phenylalanine, tyrosine and leucine were increased in these lysates. This also contrasted with the serum, where levels of these amino acids were decreased. Interestingly, LV levels of amino acids like valine, glutamine and lysine were similar in normoxic and SuHx samples. However, we did observe increased citrulline levels in SuHx LV serum samples. Comparing the LV/RV ratio in our samples revealed that increased oxidized glutathione was a major determinant of the difference between the SuHx and control groups. Conclusion: Our data suggests that decreased RV serum levels of amino acids in SuHx rats may be driven by increased consumption in the pulmonary vasculature. Given that glutamine levels in the RV are decreased, while being increased intracellularly in MVECs, we hypothesize that glutamine consumption in the lung microvasculature may be driven in part, to produce reduced glutathione. This is also supported by the oxidized glutathione gradient across the pulmonary vasculature in our experiments. These results provide the basis for a mechanistic study aimed at understanding how interrupting glutathione and/or branched-chain amino acid metabolism in MVECs contributes to PAH. NHLBI grant K08HL145132 (J.S.), NHLBI grant R01HL148112 01 (L.S), NHLBI grant R01HL151530 (K.S) This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Amino Acid Starvation-Induced Glutamine Accumulation Enhances Pneumococcal Survival.

Bacteria are known to cope with amino acid starvation by the stringent response signaling system, which is mediated by the accumulation of the (p)ppGpp alarmones when uncharged tRNAs stall at the ribosomal A site. While a number of metabolic processes have been shown to be regulatory targets of the stringent response in many bacteria, the global impact of amino acid starvation on bacterial metabolism remains obscure. This work reports the metabolomic profiling of the human pathogen Streptococcus pneumoniae under methionine starvation. Methionine limitation led to the massive overhaul of the pneumococcal metabolome. In particular, methionine-starved pneumococci showed a massive accumulation of many metabolites such as glutamine, glutamic acid, lactate, and cyclic AMP (cAMP). In the meantime, methionine-starved pneumococci showed a lower intracellular pH and prolonged survival. Isotope tracing revealed that pneumococci depend predominantly on amino acid uptake to replenish intracellular glutamine but cannot convert glutamine to methionine. Further genetic and biochemical analyses strongly suggested that glutamine is involved in the formation of a "prosurvival" metabolic state by maintaining an appropriate intracellular pH, which is accomplished by the enzymatic release of ammonia from glutamine. Methionine starvation-induced intracellular pH reduction and glutamine accumulation also occurred to various extents under the limitation of other amino acids. These findings have uncovered a new metabolic mechanism of bacterial adaptation to amino acid limitation and perhaps other stresses, which may be used as a potential therapeutic target for infection control. IMPORTANCE Bacteria are known to cope with amino acid starvation by halting growth and prolonging survival via the stringent response signaling system. Previous investigations have allowed us to understand how the stringent response regulates many aspects of macromolecule synthesis and catabolism, but how amino acid starvation promotes bacterial survival at the metabolic level remains largely unclear. This paper reports our systematic profiling of the methionine starvation-induced metabolome in S. pneumoniae. To the best of our knowledge, this represents the first reported bacterial metabolome under amino acid starvation. These data have revealed that the significant accumulation of glutamine and lactate enables S. pneumoniae to form a "prosurvival" metabolic state with a lower intracellular pH, which inhibits bacterial growth for prolonged survival. Our findings have provided insightful information on the metabolic mechanisms of pneumococcal adaptation to nutrient limitation during the colonization of the human upper airway.

Abstract 3972: Novel renal cell carcinoma therapy targeting glutaminolysis

Abstract Objective: Metabolic reprogramming of cancer cells contributes to tumor development and provides a target for cancer therapy ASCT2 is a glutamine transporter on the plasma membrane. Glutamine is converted into the cell to glutamate by glutaminase (GLS) and utilized by the TCA cycle. This glutaminolysis has been implicated in tumor progression in various malignancies, including renal cell carcinoma. In the present study, we investigated whether the unique strategy that effectively targets glutamine addiction would be effective as a treatment for RCC. Methods: Tumor tissue (T) and normal renal tissue (N) from surgical specimens of 66 patients with RCC were collected, and metabolomic analysis using liquid chromatography-mass spectrometry (LC/MS) to calculate the T/N ratio of Gln and Glu, respectively, were performed. In addition, immunohistological (IHC) staining of paraffin-embedded sections of 106 metastatic RCC cases was used to compare GLS and ASCT2 expression in tumor and normal tissue. In vitro, cell viability of the human RCC cell lines 786-O and 769-P was assessed by WST-8 assays. The protein expression was detected by Western blotting. Intracellular concentrations of glutamine and glutamate were analyzed using LC/MS. V9302 was used as the specific ASCT2 inhibitor, and CB839 as the specific GLS inhibitor. As the xenograft model in vivo, athymic nude mice were injected subcutaneously with 786-O cells and given various doses of V9302 and CB839 intraperitoneally. Results: LC/MS assays using surgical specimens showed a notable increase in glutamine concentration in tumor tissue. IHC assays confirmed high expression of ASCT2 in tumor tissue, and patients with high expression of ASCT2 had a poorer prognosis than those with low expression. Treatment of V9302 with 786-O and 769-P resulted in a limited decrease in cell viability. LC/MS analysis confirmed that V9302 treatment reduced glutathione metabolites. V9302 administration was shown to increase intracellular glutamine levels, presumably by compensatory mechanisms, whereas the combination of V9302 and CB839 significantly decreased glutamine levels in 786-O cells. Western blot analysis showed that the expression levels of ASCT2 and GLS1 decreased after the combination therapy. The xenograft study confirmed that the combination of V9302 and CB839 significantly inhibited 786-O tumor growth compared with controls within three weeks after treatment (p <0.001). Conclusion: It has been shown that ASCT2 expression is a marker of poor prognosis in RCC and that suppression of ASCT2 has an antitumor effect by affecting glutathione metabolism. On the other hand, the administration of V9302 raised the issue that a compensatory mechanism increases intracellular glutamine levels. Our results suggest that a novel combination strategy using CB839 in addition to V9302 could overcome the tolerance for the monotherapy and effectively target glutamine addiction in RCC. Citation Format: Yoshinari Muto, Akihito Takeuchi, Kenji Zennami, Eiji Sugihara, Ryoichi Shiroki, Hideyuki Saya, Makoto Sumitomo. Novel renal cell carcinoma therapy targeting glutaminolysis. [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 3972.

MP04-11 TARGETING GLUTAMINE ADDICTION WITH POTENT DRUG COMBINATION THERAPY FOR RENAL CELL CARCINOMA

You have accessJournal of UrologyCME1 Apr 2023MP04-11 TARGETING GLUTAMINE ADDICTION WITH POTENT DRUG COMBINATION THERAPY FOR RENAL CELL CARCINOMA Yoshinari Muto, Akihito Takeuchi, Kenji Zennami, Eiji Sugihara, Ryoichi Shiroki, Hideyuki Saya, and Makoto Sumitomo Yoshinari MutoYoshinari Muto More articles by this author , Akihito TakeuchiAkihito Takeuchi More articles by this author , Kenji ZennamiKenji Zennami More articles by this author , Eiji SugiharaEiji Sugihara More articles by this author , Ryoichi ShirokiRyoichi Shiroki More articles by this author , Hideyuki SayaHideyuki Saya More articles by this author , and Makoto SumitomoMakoto Sumitomo More articles by this author View All Author Informationhttps://doi.org/10.1097/JU.0000000000003215.11AboutPDF ToolsAdd to favoritesDownload CitationsTrack CitationsPermissionsReprints ShareFacebookLinked InTwitterEmail Abstract INTRODUCTION AND OBJECTIVE: The glutamine-dependent nature of cancer cells could be used as a new strategy for treating cancers that do not have drug-driver genes, such as renal cell carcinoma (RCC). We recently reported that Alanine-serine-cysteine transporter 2 (ASCT2) is associated with metastatic progression and survival in RCC. However, the administration of V9302, a specific inhibitor of ASCT2, raised the issue that intracellular glutamine levels are increased by a compensatory mechanism (presented at 2021 AUA annual meeting). In the present study, we investigated whether the combination strategy that effectively targets glutamine addiction would be effective as a treatment for RCC. METHODS: The human RCC cell lines, 786-O and 769-P were used. The protein expression was detected by Western blotting. Cell viability was assessed using WST-8 assay. Intracellular concentrations of glutamine and glutamate were analyzed using liquid chromatography-mass spectrometry (LC/MS). V9302 was used as the specific ASCT2 inhibitor and CB839 as the specific GLS inhibitor. As the xenograft model in vivo, athymic nude mice were injected subcutaneously with 786-O cells and given various doses of V9302 and CB839 intraperitoneally. RESULTS: LC/MS assays showed that intracellular glutamine levels in the RCC cell line increased after 48 hours of treatment with V9302 alone, but that glutamine levels were significantly reduced by the combination of V9302 and CB839. Western blot analysis showed that the expression levels of ASCT2 and GLS1 were both decreased after the combination therapy. The tumor xenograft study confirmed that the combination of V9302 (30 mg/kg, intraperitoneal injection) and CB839 (20 mg/kg, intraperitoneal injection) significantly inhibited 786-O tumor growth compared with controls within 3 weeks after treatment (p<0.001). CONCLUSIONS: Our results suggest that V9302 monotherapy is insufficient for the treatment of RCC but that a novel combination strategy using CB839 in addition to V9302 could overcome the tolerance for the monotherapy and effectively target glutamine addiction in RCC. Source of Funding: None © 2023 by American Urological Association Education and Research, Inc.FiguresReferencesRelatedDetails Volume 209Issue Supplement 4April 2023Page: e37 Advertisement Copyright & Permissions© 2023 by American Urological Association Education and Research, Inc.MetricsAuthor Information Yoshinari Muto More articles by this author Akihito Takeuchi More articles by this author Kenji Zennami More articles by this author Eiji Sugihara More articles by this author Ryoichi Shiroki More articles by this author Hideyuki Saya More articles by this author Makoto Sumitomo More articles by this author Expand All Advertisement PDF downloadLoading ...

Deletion of the tyrosine phosphatase Shp2 in cervical cancer cells promotes reprogramming of glutamine metabolism.

Shp2 is a nonreceptor protein tyrosine phosphatase that is overexpressed in cervical cancer. However, the role of Shp2 in the regulation of cervical cancer metabolism and tumorigenesis is unclear. EGFR signaling pathways are commonly dysregulated in cervical cancer. We showed that Shp2 knockout in cervical cancer cells decreased EGFR expression and downregulated downstream RAS-ERK activation. Although AKT was activated in Shp2 knockout cells, inhibition of AKT activation could not make cells more sensitive to death. Shp2 depletion inhibited cervical cancer cell proliferation and reduced tumor growth in a xenograft mouse model. 1 H NMR spectroscopic analysis showed that glutamine, glutamate, succinate, creatine, glutathione, and UDP-GlcNAc were significantly changed in Shp2 knockout cells. The intracellular glutamine level was higher in Shp2 knockout cells than in control cells. Further analysis demonstrated that Shp2 knockout promoted glutaminolysis and glutathione production by up-regulating the glutamine metabolism-related genes such as glutaminase (GLS). However, inhibition of GLS did not always make cells sensitive to death, which was dependent on glucose concentration. The level of oxidative phosphorylation was significantly increased, accompanied by an increased generation of reactive oxygen species in Shp2 knockout cells. Shp2 deficiency increased c-Myc and c-Jun expression, which may be related to the upregulation of glutamine metabolism. These findings suggested that Shp2 regulates cervical cancer proliferation, glutamine metabolism, and tumorigenicity.

A systematic evaluation of quenching and extraction procedures for quantitative metabolome profiling of HeLa carcinoma cell under 2D and 3D cell culture conditions.

Metabolic reprogramming has been coined as a hallmark of cancer, accompanied by which the alterations in metabolite levels have profound effects on gene expression, cellular differentiation, and the tumor environment. Yet a systematic evaluation of quenching and extraction procedures for quantitative metabolome profiling of tumor cells is currently lacking. To achieve this, this study is aimed at establishing an unbiased and leakage-free metabolome preparation protocol for HeLa carcinoma cell. We evaluated 12 combinations of quenching and extraction methods from three quenchers (liquid nitrogen, -40°C 50% methanol, 0.5°C normal saline) and four extractants (-80°C 80% methanol, 0.5°C methanol/chloroform/water [1:1:1 v/v/v], 0.5°C 50% acetonitrile, 75°C 70% ethanol) for global metabolite profiling of adherent HeLa carcinoma cells. Based on the isotope dilution mass spectrometry (IDMS) method, gas/liquid chromatography in tandem with mass spectrometry was used to quantitatively determine 43 metabolites including sugar phosphates, organic acids, amino acids (AAs), adenosine nucleotides, and coenzymes involved in central carbon metabolism. The results showed that the total amount of the intracellular metabolites in cell extracts obtained using different sample preparation procedures with the IDMS method ranged from 21.51 to 295.33nmol per million cells. Among 12 combinations, cells that washed twice with phosphate buffered saline (PBS), quenched with liquid nitrogen, and then extracted with 50% acetonitrile were found to be the most optimal method to acquire intracellular metabolites with high efficiency of metabolic arrest and minimal loss during sample preparation. In addition, the same conclusion was drawn as these 12 combinations were applied to obtain quantitative metabolome data from three-dimensional (3D) tumor spheroids. Furthermore, a case study was carried out to evaluate the effect of doxorubicin (DOX) on both adherent cells and 3D tumor spheroids using quantitative metabolite profiling. Pathway enrichment analysis using targeted metabolomics data showed that DOX exposure would significantly affect AA metabolism-related pathways, which might be related to the mitigation of redox stress. Strikingly, our data suggested that compared to two-dimensional (2D) cells the increased intracellular glutamine level in 3D cells benefited replenishing the tricarboxylic acid (TCA) cycle when the glycolysis was limited after dosing with DOX. Taken together, this study provides a well-established quenching and extraction protocol for quantitative metabolome profiling of HeLa carcinoma cell under 2D and 3D cell culture conditions. Based on this, quantitative time-resolved metabolite data can serve to the generation of hypotheses on metabolic reprogramming to reveal its important role in tumor development and treatment.