bims-glucam Biomed News
on Glutamine cancer metabolism
Issue of 2026–02–22
twenty papers selected by
Sreeparna Banerjee, Middle East Technical University
  1. Fueling the Fire: How Glutamine Metabolism Sustains Leukemia Growth and Resistance.
  2. Glutamine metabolism tunes myeloid responses to drive resolution of inflammation during skin repair.
  3. Simvastatin Targets PKM2 to Alter Metabolic Reprogramming in Hepatic Stellate Cells and Mitigate Liver Fibrosis.
  4. Hydrostatic pressure regulates glutamine metabolism to promote bladder fibroblast activation via the Piezo1/YAP1/GLS1 axis.
  5. A novel microprotein MUCP1 promotes colorectal cancer metabolic reprogramming by regulating mitochondrial succinate transport.
  6. Hyperglutaminolysis drives senescence and aging through arginine-mTORC1 axis activation.
  7. A Glutamine-Metabolism-Intervening Nanoplatform Activates Lipophagy to Potentiate Ferroptosis and Immune Activation in Breast Cancer.
  8. Protective effect and results of glutamine and partially hydrolyzed Guar gum on rats with experimental radiation enteritis.
  9. Glutamine alleviates radiation-induced intestinal injury in rats via the mTOR/Notch1 axis.
  10. Glutamine-mediated crosstalk between M2 macrophages and tumor cells via the SLC38A5/FOXM1/CNIH4 axis promotes oral squamous cell carcinoma progression.
  11. Decoding cancer across scales with metabolomics.
  12. Intestinal stem cell damage caused by specific amino acid deprivation is linked to a potent integrated stress response triggered by the direct sensing of stem cells.
  13. Gestational low carbamoyl phosphate suppresses TET2-mediated DNA demethylation and induces congenital heart disease in offspring.
  14. Taurine is a natural suppressor of urea cycle via targeting ASL.
  15. The early metabolic cardiac targets of empagliflozin during the development of heart failure, independent of SGLT2 inhibition.
  16. Targeting Metabolic Vulnerabilities in Glioblastoma: a Framework for Multi-node Combination Therapy.
  17. Fatty acid and cysteine metabolic interplay regulate ferroptosis and highlight xCT as a selenium-chrysin target in breast carcinoma.
  18. Spectroscopic characterization of chiral substances: proline and glutamine.
  19. Imidacloprid Transformation Products Exhibit Stronger Developmental Neurotoxicity than the Parent Compound in Zebrafish (Danio rerio) via the Glutamate Signaling Pathway.
  20. COVID-19 Impact on Lipid Profile and Metabolome in Patients with Type 2 Diabetes Mellitus: Mini-Review.
  1. BioMed (Basel). 2026 Mar;pii: 7. [Epub ahead of print]6(1):
    Fueling the Fire: How Glutamine Metabolism Sustains Leukemia Growth and Resistance.
    Giovannino Silvestri.
      Glutamine metabolism has emerged as one of the most critical bioenergetic and biosynthetic programs sustaining leukemic cell growth, survival, stemness and therapeutic resistance. In both acute and chronic leukemias, including acute myeloid leukemia (AML) and acute lymphoblastic leukemia (ALL), malignant cells display a strong dependency on extracellular glutamine to support mitochondrial respiration, anabolic biosynthesis and redox homeostasis. This dependency is reinforced by oncogenic signaling networks, post-transcriptional metabolic regulation and microenvironmental adaptation within the bone marrow niche. Therapeutic strategies targeting glutamine utilization, including glutaminase inhibition, transporter blockade and enzymatic glutamine depletion, have demonstrated robust antileukemic activity in preclinical models, and early clinical efforts have begun to explore glutamine-directed interventions in myeloid neoplasms. However, metabolic plasticity, microenvironment-derived nutrient buffering and systemic toxicity remain significant limitations to clinical translation. This review provides a detailed synthesis of the biochemical framework of glutamine metabolism in leukemia, the molecular mechanisms enforcing glutamine addiction, the downstream functional consequences on proliferation, redox balance and leukemic stem cell biology, the current landscape of therapeutic strategies and emerging directions aimed at overcoming resistance and improving clinical efficacy.
    Keywords:  FLT3-ITD; IGF2BP2; SLC1A5; acute myeloid leukemia (AML); cancer metabolism; glutaminase inhibition; glutamine addiction; glutamine metabolism; leukemia; leukemic stem cells; metabolic targeting; redox balance; therapeutic resistance
    DOI:  https://doi.org/10.3390/biomed6010007
  2. Cell Rep. 2026 Feb 18. pii: S2211-1247(26)00079-3. [Epub ahead of print]45(3): 117001
    Glutamine metabolism tunes myeloid responses to drive resolution of inflammation during skin repair.
    Yiting Xu, Maria Fernanda Forni, Abigail Benvie, Nicole Castano, Diane King, Qiushi Sun, Stephan Siebel, Van Anh Tran, Richard G Kibbey, Kathryn Miller-Jensen, Valerie Horsley.
      Tissue repair requires inflammation resolution, but the molecular mechanisms involved in vivo are not fully understood. Here, we show that glutamine metabolism suppresses neutrophil recruitment to abrogate inflammation and drive skin wound repair. Integrated metabolomic and transcriptional profiling identified glutamine metabolism as enriched in macrophages during resolution. Dietary depletion studies and conditional deletion of glutaminase, the enzyme essential for glutamine metabolism, in mouse myeloid cells revealed that macrophages suppress neutrophil recruitment genes during tissue resolution to promote repair. We also found that these genes are upregulated in macrophages in patients with diabetes. Mechanistically, our data reveal that glutamine metabolism in macrophages induces suppressive chromatin remodeling of neutrophil recruitment genes, including Ccl ligands, during resolution of inflammation. These findings highlight the ability of specific metabolites to control cellular communication during tissue repair, with glutamine specifically to suppress neutrophil recruitment to advance inflammation resolution.
    Keywords:  CP: immunology; CP: metabolism; glutamine; immunology; inflammation; macrophages; metabolism; neutrophils; resolution; skin; tissue repair; wound healing
    DOI:  https://doi.org/10.1016/j.celrep.2026.117001
  3. FASEB J. 2026 Feb 28. 40(4): e71500
    Simvastatin Targets PKM2 to Alter Metabolic Reprogramming in Hepatic Stellate Cells and Mitigate Liver Fibrosis.
    Ruoru Zhou, Ziqiang Xia, Xiangting Zhang, Xiao Wu, Kanglei Ying, Hong Pan, Huiya Ying, Jun Xu, Yuan Zeng, Weimin Cai, Yixiao Wang, Dandan Zhu, Lei Miao, Fujun Yu.
      Hepatic stellate cell (HSC) activation plays a crucial role in liver fibrosis progression, with glycolysis and glutaminolysis serving as key components of metabolic reprogramming to sustain HSC activation. Simvastatin (SV) has been shown to ameliorate liver fibrosis; however, its underlying mechanisms remain unclear. This study aimed to explore the protective effects of SV on liver fibrosis with a focus on metabolic regulation. A carbon tetrachloride (CCl4)-induced liver fibrosis model was established in mice, and SV was administered via gavage. LX-2 cells were used for in vitro mechanistic studies. Our findings demonstrated that SV effectively suppressed aerobic glycolysis and glutaminolysis in activated HSCs. Mechanistically, SV inhibited the PKM2/STAT3/c-MYC pathway by targeting PKM2, leading to reduced c-MYC expression. This downregulation of c-MYC decreased ASCT2 expression, a key transporter in glutamine metabolism, thereby impairing glutamine utilization. These results provide new insights into the metabolic regulatory mechanisms of SV in liver fibrosis and lay the foundation for further exploration of its therapeutic potential in liver disease.
    Keywords:  glutaminolysis; glycolysis; hepatic stellate cells; liver fibrosis; simvastatin
    DOI:  https://doi.org/10.1096/fj.202503580R
  4. J Transl Med. 2026 Feb 19.
    Hydrostatic pressure regulates glutamine metabolism to promote bladder fibroblast activation via the Piezo1/YAP1/GLS1 axis.
    Kang Li, Pengyu Wei, Zhipeng Li, Wenbo Kuang, Mengyang Zhang, Changcheng Luo, Kai Cui, Dongxu Lin, Zhong Chen.
      
    Keywords:  Bladder outlet obstruction; Fibrosis; GLS1; Glutamine metabolism; Hydrostatic pressure; Piezo1; YAP1
    DOI:  https://doi.org/10.1186/s12967-026-07855-2
  5. Neoplasia. 2026 Feb 14. pii: S1476-5586(26)00016-3. [Epub ahead of print]73 101287
    A novel microprotein MUCP1 promotes colorectal cancer metabolic reprogramming by regulating mitochondrial succinate transport.
    Junjie Nie, Xinwei Liu, Mu Xu, Xinliang Gu, Shangshang Hu, Huiling Sun, Linpeng Zhou, Tao Xu, Yuqin Pan, Shukui Wang.
       BACKGROUND: Metabolic reprogramming is a hallmark of colorectal cancer (CRC), yet the molecular regulators that orchestrate this process remain incompletely understood. Although many long non-coding RNAs (lncRNAs) possess protein-coding potential, their translational products and metabolic functions have been largely overlooked. Here, we identify MUCP1, a microprotein encoded by the lncRNA MUC20-OT1, as a critical regulator of mitochondrial metabolism and epigenetic remodeling in CRC.
    METHODS: Multi-omics data were integrated to identify MUC20-OT1 as a candidate lncRNA encoding a functional microprotein. Fusion reporter plasmids, mass spectrometry, and immunoblotting were used to validate MUCP1 translation and mitochondrial localization. Functional assays, metabolomic profiling, 13C5-glutamine isotope tracing, subcellular succinate quantification, CUT&Tag, and xenograft models were performed to investigate the role of MUCP1 in facilitating mitochondrial succinate export and maintaining glutamine metabolism homeostasis.
    RESULTS: The microprotein MUCP1, encoded by the lncRNA MUC20-OT1, serves as an auxiliary regulator of SLC25A10-mediated mitochondrial succinate transport. MUCP1 is upregulated during CRC progression and localizes in the mitochondrial outer membrane, where it facilitates the balance of mitochondrial succinate metabolism. Elevated extramitochondrial succinate subsequently enhances H3K4me3 histone modifications, promoting the transcription of enzymes involved in glutamine metabolism and sustaining the high metabolic demands of CRC cells.
    CONCLUSIONS: This study identifies MUCP1 as a novel lncRNA-encoded microprotein that maintains metabolic homeostasis in CRC by coupling mitochondrial succinate transport to histone methylation. MUCP1 might be a promising metabolic vulnerability and therapeutic target in CRC.
    Keywords:  Glutamine metabolism; H3K4me3; MUCP1; SLC25A10; Succinate
    DOI:  https://doi.org/10.1016/j.neo.2026.101287
  6. Signal Transduct Target Ther. 2026 Feb 19. 11(1): 64
    Hyperglutaminolysis drives senescence and aging through arginine-mTORC1 axis activation.
    Honghan Chen, Ning Huang, Weitong Xu, Yu Yang, Fangfang Wang, Hui Gong, Jiao Zhou, Haoran Tai, Tingting Zhao, Jian Zhang, Ying Li, Ge Liang, Minghai Tang, Jie Li, Ming Yang, Jin Liu, Xiaoli Huang, Hengyi Xiao.
      The catabolism of glutamine is essential for living organisms, so that its first step, driven by glutaminase 1 (GLS1), generally referred to as glutaminolysis, plays important roles in physiological metabolism. However, the status and impact of glutaminolysis in pathological contexts such as aging and age-related diseases remain elusive. In this study, through metabolomics analysis and different aging models, we verified the hyperactivation status of glutaminolysis in senescent cells and aged Drosophila and mice, which we term "hyperglutaminolysis". We further confirmed the aging-promoting role of this hyperglutaminolysis by addition and removal intervention experiments. Intriguingly, a novel signaling axis connecting to senescence-associated persistent mTORC1 activation was found. This pathway begins with glutaminase-catalyzed production of ammonium and glutamate, which drives arginine biosynthesis and is subsequently sensed by CASTOR1, leading to persistent mTORC1 activation. The regulatory roles of two key enzymes within this cascade, GLS1 and argininosuccinate lyase (ASL), were specifically investigated and verified by cellular and in vivo experiments, including those using stress-promoted and naturally aged animals, combined with GLS1 and ASL knockdown, and multiple rounds of metabolite analysis. In conclusion, our work positions dysregulated glutaminolysis as a key driver of aging and delineates a previously unrecognized molecular cascade that directly links glutaminolysis, arginine biosynthesis, and mTORC1 activation. These findings significantly expand our understanding of the relationship between glutamine catabolism and aging and are valuable for identifying novel intervention targets aimed at mitigating aging-related processes.
    DOI:  https://doi.org/10.1038/s41392-026-02576-w
  7. Adv Healthc Mater. 2026 Feb 20. e70969
    A Glutamine-Metabolism-Intervening Nanoplatform Activates Lipophagy to Potentiate Ferroptosis and Immune Activation in Breast Cancer.
    Jiayue Ding, Jingchao Liu, Liheng Liang, Weilin Wang, Yingchao Li, Chuanxiu Zhu, Jiayao Wen, Zhijing He, Jin Li, Yu Zhang, Guangxi Zhai, Xiaoye Yang.
      Aberrant glutamine (Gln) metabolism in tumor cells contributes to ferroptosis resistance and immunosuppression, challenging ferroptotic therapy. Our preliminary bioinformatic data uncovered that elevated expression of SLC1A5, a critical Gln transporter, confers poor prognosis in breast cancer, underscoring its potential as a therapeutic target for metabolic regulation. Encouraged by this, this work proposes to enhance ferroptosis of breast cancer by inhibiting SLC1A5. As a proof-of-concept, we develop a nanoplatform for ferroptosis named MICLM, which is obtained by encapsulating chlorin e6 (Ce6, a photosensitizer) and IMD-0354 (an SLC1A5 inhibitor) into metal-organic framework (NH2-MIL-101(Fe)), followed by surface coating for tumor-targeting. Experimental data reveal that Ce6-based photodynamic therapy synergizes with iron-mediated Fenton reaction, potently driving lipid peroxides (LPOs) accumulation and triggering ferroptosis of 4T1 cells. Meanwhile, IMD-0354-mediated Gln metabolic intervention is proven to inhibit glutathione (GSH) synthesis and activate lipophagy, thereby increasing free fatty acids (FFA) levels as an essential "fuel" for lipid peroxidation and overcoming a key limitation in ferroptosis efficacy. Additionally, Gln metabolism inhibition attenuates immunosuppressive M2 macrophage polarization, ultimately boosting antitumor immunity. Thus, MICLM effectively induces ferroptosis and remodels the tumor immune microenvironment via amino acid metabolic intervention, offering a promising strategy for ferroptosis-based therapy.
    Keywords:  antitumor immune; ferroptosis; glutamine metabolism intervention; lipophagy; metal‐organic framework
    DOI:  https://doi.org/10.1002/adhm.70969
  8. Radiat Environ Biophys. 2026 Feb 18.
    Protective effect and results of glutamine and partially hydrolyzed Guar gum on rats with experimental radiation enteritis.
    Erdi Aydın, Levent Bolat, Murat Aba, Burak Yavuz, Özlem Görüroğlu Öztürk, Kıvılcım Eren Erdoğan, Fundagül Andiç, Ahmet Rencüzoğulları, İsmail Cem Eray.
      The aim of our study is to evaluate the effects of glutamine, partially hydrolyzed guar gum and combined glutamine and partially hydrolyzed guar gum form in rats with experimental radiation enteritis by histopathological, immunohistochemical and biochemical measurements. 64 Wistar albino rats with an average weight of 220-280 g were used in the study. 1st group only took water, 2nd group only took glutamine, 3rd group only took partially hydrolyzed guar gum, 4th group took partially hydrolyzed guar gum with glutamine, 5th group took only radiotherapy, 6th group took radiotherapy with glutamine, 7th group took radiotherapy with partially hydrolyzed guar gum and 8th group took radiotherapy, glutamine and guar gum. Partially hydrolyzed guar gum was given with radiotherapy, and glutamine and guar gum were given together with radiotherapy in the 8th group. All rats were weighed on the first, seventh and tenth days. On the tenth day, the rats were sacrificed and their clinical status, biochemical, histopathological and immunohistochemical parameters in the terminal ileum were evaluated. Differences between groups were compared statistically. All groups were compared in terms of crypt length, villus height, crypt abscess, congestion, intraepithelial lymphoid infiltration, stool consistency, myeloperoxidase, malondialdehyde, caspase-3% and tumor necrosis factor alpha mean, and statistical significance was observed (p < 0.05). Weight% difference in rats was statistically significant between groups (p < 0.05). Interleukin-10 values were not statistically significant between groups (p > 0.05). In paired comparisons, there was a statistically significant difference between the control group and the group with radiation enteritis in terms of biochemical, histopathological, immunohistochemical and clinical parameters (p < 0.05). There was no statistically significant difference between the 5th group and 6th group, 7th group and 8th groups in terms of biochemical, histopathological, immunohistochemical and clinical parameters (p > 0,05). The result suggest that glutamine, partially hydrolyzed guar gum and combination therapy may not have a protective effect on radiation enteritis.
    Keywords:  Glutamine; Partially hydrolyzed guar gum; Radiation enteritis
    DOI:  https://doi.org/10.1007/s00411-026-01201-2
  9. Front Oncol. 2026 ;16 1735401
    Glutamine alleviates radiation-induced intestinal injury in rats via the mTOR/Notch1 axis.
    Heng Lu, Xiangmin Ni, Xinyu Liang, Qian Bai, Haoyu Li, Mengran Shi, Yulong Jia, Jian Wang.
       Introduction: Radiotherapy remains a principal modality for managing malignant pelvic tumors; nevertheless, it frequently induces radiation-associated intestinal injury (RIII), a debilitating complication that compromises intestinal barrier integrity. Glutamine (Gln) functions as an essential nutrient for maintaining and repairing the intestinal mucosa, yet its specific role in RIII and the mechanisms involved have not been clearly defined.
    Methods: In this study, we explored the protective potential and molecular mechanisms of Gln against RIII by employing both a localized abdominal irradiation rat model and irradiated HT-29 cell cultures.
    Results: Gln administration markedly mitigated intestinal shortening and mucosal injury, reduced the expression of pro-inflammatory cytokines, and restored the number of goblet cells (GCs). Furthermore, Gln treatment enhanced intestinal Lgr5 and Klf4 expression, suggesting protection of intestinal stem cells (ISCs) and facilitation of GC differentiation. Mechanistically, Gln activated the mTOR pathway and its downstream effectors S6K1 and 4E-BP1, while suppressing the radiation-induced overactivation of Notch1. Pharmacologic interventions using rapamycin and Jagged-1 further validated that Gln modulates the mTOR/Notch1 signaling cascade, leading to increased MUC2 expression and improved mucosal integrity.
    Discussion: Collectively, these results demonstrate that Gln confers robust protection against RIII by regulating the mTOR/Notch1 axis, alleviating Notch1 overactivation, and promoting GC differentiation. These findings provide valuable mechanistic insight and experimental support for Gln as a potential therapeutic agent to prevent or mitigate radiation-induced intestinal injury.
    Keywords:  MUC2; glutamine; goblet cells; mTOR/Notch1 axis; radiation-induced intestinal injury
    DOI:  https://doi.org/10.3389/fonc.2026.1735401
  10. J Transl Med. 2026 Feb 19.
    Glutamine-mediated crosstalk between M2 macrophages and tumor cells via the SLC38A5/FOXM1/CNIH4 axis promotes oral squamous cell carcinoma progression.
    Yuanhang Liu, Jie Guo, Hui Xu, Xiaoxue Xu, Xinxin Jin, Yahong Zhang, Yongle Qiu.
      
    Keywords:  CNIH4; Glutamine; M2 macrophages; Metabolite-mediated cell-cell communication; Oral squamous cell carcinoma; SLC38A5
    DOI:  https://doi.org/10.1186/s12967-026-07875-y
  11. Nat Rev Cancer. 2026 Feb 20.
    Decoding cancer across scales with metabolomics.
    Joe L Rowles, Gary J Patti.
      It is well established that malignant cells alter their metabolism to support proliferation, but the nutrients required to meet the anabolic demands of different cancers located at various anatomical sites throughout the body remain largely unknown. Moreover, the extent to which nutrients are supplied by neighbouring stromal cells or distant tissues, possibly due to metabolic reprogramming, is poorly understood. Metabolomics provides a unique biochemical approach to address these gaps in our knowledge, but cancer studies require careful consideration because it is challenging to identify appropriately matched control samples for comparison. Here, we detail a collection of metabolomics workflows designed to interrogate cancer across three discrete scales. First, we describe experiments to define the nutrient demands of cancer cells themselves. Second, we focus on identifying metabolic relationships between neighbouring cells in the tumour microenvironment. Finally, we highlight strategies to explore the metabolic crosstalk between cancer cells and distant tissues in the tumour macroenvironment. The approaches outlined span cells in culture, animal models and human specimens from patients with cancer. Special emphasis is dedicated to the application of emerging technologies and computational pipelines in the field of mass spectrometry that enable global profiling of metabolites and lipids.
    DOI:  https://doi.org/10.1038/s41568-026-00908-0
  12. Biochem Biophys Res Commun. 2026 Feb 11. pii: S0006-291X(26)00218-4. [Epub ahead of print]807 153454
    Intestinal stem cell damage caused by specific amino acid deprivation is linked to a potent integrated stress response triggered by the direct sensing of stem cells.
    Ayumi Kozai, Takumi Satoh, Yoshiko Sugita-Konishi, Makoto Shimizu, Ken Iwatsuki, Miki Tadaishi, Kazuo Kobayashi-Hattori.
      Amino acid deprivation, particularly deficiencies in methionine (Met) or glutamine (Gln), disrupts intestinal stem cells (ISCs), causes growth suppression, and induces cell death. We previously found that among the branched-chain amino acid (BCAA), leucine and isoleucine deprivation maintain ISC survival, whereas valine (Val) deprivation induces ISC impairment, which is characterized by suppressed proliferation and increased cell death; however, the mechanisms underlying these divergent cell fates remain largely unclear. We here focused on the integrated stress response (ISR) as a regulator of cell fate under amino acid deprivation using mouse intestinal organoids and ISCs isolated from organoids. Deprivation of each BCAA uniformly suppressed global translation, whereas only Val deprivation induced activation through phosphorylation of eukaryotic initiation factor 2 alpha (eIF2α) and a persistent increase in the mRNA expressions of activating transcription factor 4, C/EBP homologous protein, and growth arrest and DNA damage-inducible 34, indicating a potent and sustained ISR. Analysis using ISCs isolated by cell sorting revealed that only Val deprivation markedly increased p-eIF2α levels and reduced organoid formation. Furthermore, Met and Gln deprivation resulted in similar responses to Val deprivation in organoids and isolated ISCs. Taken together, these results suggest that Val, Met, and Gln deprivation induce a potent ISR through direct sensing by ISCs, with the response associated with stem cell damage.
    Keywords:  Amino acids; Glutamine; Integrated stress response; Intestinal stem cells; Methionine; Organoids; Valine
    DOI:  https://doi.org/10.1016/j.bbrc.2026.153454
  13. J Adv Res. 2026 Feb 16. pii: S2090-1232(26)00153-0. [Epub ahead of print]
    Gestational low carbamoyl phosphate suppresses TET2-mediated DNA demethylation and induces congenital heart disease in offspring.
    Hao-Ran Geng, Yu-Ling Chen, Lei Huang, Yu-Fan Ke, Fei Ma, He Huang, Fei Li, Jian-Yuan Zhao, Rui Zhao, Yan Shi.
       INTRODUCTION: Congenital heart disease (CHD) is the most common birth defect worldwide, with over half of cases lacking a defined etiology. Maternal metabolic dysregulation has been implicated in CHD risk, but the specific metabolites and mechanisms involved in embryonic heart development remain poorly understood. Carbamoyl phosphate (CP), a key urea cycle intermediate, has not previously been linked to cardiac morphogenesis.
    OBJECTIVES: This study aimed to identify maternal metabolites associated with offspring CHD risk and to elucidate the role of CP in regulating cardiac development.
    METHODS: Untargeted metabolomic profiling was performed on early-pregnancy serum from 98 mothers of CHD offspring and 50 age-matched controls. Functional validation was performed using two pregnant mouse models: pharmacological inhibition of glutamine metabolism via BPTES and Cps1 heterozygous knockout (Cps1+/-). Rescue experiments were performed with the CPS1 activator N-carbamylglutamate (NCG). Epigenetic mechanisms were investigated by assessing TET2 carbamylation, DNA hydroxymethylation, and cardiogenic gene expression in embryonic hearts.
    RESULTS: Maternal serum CP levels were significantly reduced in CHD cases and negatively correlated with upstream nutrient levels. In mice, both BPTES treatment and maternal Cps1 knockdown increased CHD incidence in offspring. Conversely, NCG supplementation reduced CHD risk in Cps1+/- pregnant mouse. Mechanistically, CP depletion impaired TET2 lysine carbamylation at residues K1339 and K1509, decreasing its DNA demethylation activity without affecting protein expression. This resulted in reduced global 5hmC levels and aberrant expression of cardiogenic genes in embryonic hearts.
    CONCLUSION: Maternal CP deficiency increases offspring CHD risk by disrupting TET2-mediated DNA demethylation through impaired lysine carbamylation. These findings highlight maternal CP and TET2 carbamylation as potential metabolic-epigenetic targets for CHD prevention.
    Keywords:  Congenital heart disease; Lysine carbamylation; Maternal metabolism; Metabolomics
    DOI:  https://doi.org/10.1016/j.jare.2026.02.021
  14. Cell Death Discov. 2026 Feb 18. 12(1): 99
    Taurine is a natural suppressor of urea cycle via targeting ASL.
    Keqiang Rao, Ke Zheng, Yunfan Sun, Jing He.
      Hepatocellular carcinoma (HCC) has become the leading cause of global cancer-related mortality, which raises the demand for optimized therapeutic routes. The semi-essential micronutrient taurine has been gradually identified as a pivotal player linked to various diseases. Nevertheless, the metabolic impacts of taurine on hepatocellular carcinoma remain elusive. Here, we report that taurine is a negative regulator of urea cycle, thereby exerting a suppressive effect on growth of HCC tumors. Mechanistically, argininosuccinate lyase (ASL) is uncovered as the main target of taurine in repressing urea cycle of HCC cell lines. Furthermore, Fos proto-oncogene (FOS) functions as the transcription factor of ASL, which is significantly reduced upon taurine treatment. Physiologically, FOS-ASL axis is required for metabolic effects of taurine and contributes to growth of HCC tumors. Expression of ASL correlates with the inhibitory effect of taurine. Ultimately, synergistic blockade of glutaminolysis and urea cycle indicates that taurine is sufficient to substantially enhance the efficacy of the glutaminase GLS1 inhibitor in management of hepatocellular carcinoma. Collectively, these findings not only illustrate the metabolic mechanism of taurine in controlling growth of HCC tumors, but also create a promising route for utilization of taurine in clinic.
    DOI:  https://doi.org/10.1038/s41420-026-02959-6
  15. Metabolism. 2026 Feb 16. pii: S0026-0495(26)00078-8. [Epub ahead of print]178 156568
    The early metabolic cardiac targets of empagliflozin during the development of heart failure, independent of SGLT2 inhibition.
    Sha Chen, Xin Hu, Qian Wang, Diane Bakker, Inge van der Made, Anna M Tebbens, Yingyin Guan, Myrto Lykidou, Femke K J van Goor, Markus W Hollmann, Nina C Weber, Michel van Weeghel, Bauke V Schomakers, Michael P Pieper, Ruben Coronel, Esther E Creemers, Coert J Zuurbier.
       BACKGROUND & PURPOSE: Cardiac metabolic changes are known early drivers of heart failure (HF). Recent preclinical research showed that protection against HF by sodium glucose transporter 2 inhibitors (SGLT2i) is independent of SGLT2 inhibition. Here, we unravel the SGLT2-independent metabolic effects of SGLT2i during early HF, to shed light on the early cardiac metabolic mechanisms through which SGLT2i may confer protection against HF.
    METHODS: Short-term HF was induced through transverse aortic constriction (TAC) and deoxycorticosterone (DOCA) administration in WT and SGLT2 KO mice, in the presence or absence of Empagliflozin (EMPA). Ten days post-surgery, following in vivo echocardiography, hearts were Langendorff-perfused. The SGLT2-independent metabolic effects of EMPA were determined by: 1) performing stable isotope tracer analysis for 13C-glucose to asses relative glucose contribution to metabolic pathways via fluxomics (13C-glucose perfusion), 2) quantifying metabolic intermediates using metabolomics (LC/MS), 3) evaluating metabolic regulators through Western blot analysis, and 4) analyzing gene expression of metabolic pathways via RNA sequencing.
    RESULTS: Independent of SGLT2 (i.e., being present in both genotypes), TAC/DOCA resulted in in vivo HF (systolic and diastolic dysfunction) that was prevented by EMPA. The early SGLT2-independent cardiac metabolic properties showed: 1) HF hearts used relatively less glucose for energy production through glycolysis and TCA cycle, with more glucose being diverted toward synthesis of glutamine. In contrast, EMPA enhanced glucose labeling of the distal part of glycolysis without affecting relative glucose contribution to acetyl CoA or TCA intermediates, 2) HF led to increased metabolic intermediates (malate, aspartate, 2-hydroxyglutarate) that are known to drive pathology, whereas EMPA reduced pathology-causing metabolic intermediates (malate, glucose-6-P), together with increased lactate release and ATP content, 3) EMPA increased the metabolic regulator SIRT3 and the insulin-sensitive glucose transporter (GLUT4) without affecting AMPK, and 4) HF decreased fatty acid metabolism gene expression, whereas EMPA increased multiple mitochondrial metabolic pathways (TCA cycle, branched-chained amino acid, fatty acid, mitochondrial respiratory chain complexes), possibly through increased ERRα signaling.
    CONCLUSION: The early, SGLT2-independent, metabolic mechanism marking HF protection by SGLT2i entail 1) decreases in metabolic intermediates that drive hypertrophy (G6P, malate), 2) boosting glycolysis (GLUT4, distal part glycolysis, lactate release) without shifting glucose/fatty acid oxidation ratio, and 3) activating ERRα/SIRT3 pathway associated with increased gene expression of mitochondrial energy pathways and improved cardiac ATP levels.
    Keywords:  Branched-chain amino acids; Empagliflozin; GLUT4; Glucose-6-phosphate; Heart failure; Malate; SGLT2; SIRTUIN3
    DOI:  https://doi.org/10.1016/j.metabol.2026.156568
  16. Curr Oncol Rep. 2026 Feb 20. pii: 19. [Epub ahead of print]28(1):
    Targeting Metabolic Vulnerabilities in Glioblastoma: a Framework for Multi-node Combination Therapy.
    Vishal Gokani, Anuhya Kotta, Venkata Repaka, Sukanya Rauniyar, Evan K Noch.
       PURPOSE OF REVIEW: While glioblastoma (GBM) exhibits a poor prognosis despite standard therapy, targeted metabolic therapy is promising as adjuvant therapy. The purpose of this review is to delineate the rationale behind metabolic therapy, the bypass mechanisms conferring resistance to each therapy, and potential synergistic combination strategies.
    RECENT FINDINGS: Critical enzymes in glycolysis, glutaminolysis, lipid metabolism, nucleotide synthesis, and mitochondrial metabolism are promising individual targets of metabolic therapy and lead to cell death in preclinical studies. However, with metabolic monotherapy, GBM cells can rely on other isoforms or switch to alternative pathways for energy production and biosynthesis. Preclinical studies show that targeting multiple metabolic nodes with combination therapy blocks these resistance pathways and synergistically inhibits tumor growth. While metabolic monotherapies exhibit limited success, synergistic combination therapies may bypass resistance mechanisms and are more promising. Combination therapies delivered with standard of care may improve patient outcomes, and larger clinical trials are needed to establish the use of combination regimens to improve overall survival.
    Keywords:  Combination therapy; Glioblastoma; Glutaminolysis; Glycolysis; Lipid metabolism; Metabolic therapy; Mitochondrial metabolism; Nucleotide synthesis; Redox stress
    DOI:  https://doi.org/10.1007/s11912-026-01746-x
  17. J Pathol. 2026 Feb 18.
    Fatty acid and cysteine metabolic interplay regulate ferroptosis and highlight xCT as a selenium-chrysin target in breast carcinoma.
    Ana Hipólito, Bruna Abreu, Joana Gonçalves, Fernanda Silva, Carmo Martins, Laura Gouveia, Sofia A Pereira, Vasco D B Bonifácio, Saudade André, Cindy Mendes, Jacinta Serpa.
      Cancer metabolic remodeling impacts the entire network of metabolic pathways, and strategies that target various points within this system could contribute to successfully abrogating cancer cell survival. Fatty acids (FAs) are essential to cancer cells because they support membrane biosynthesis during proliferation and provide energy during metabolic stress. Fatty acid transport protein 1 (FATP1)has been shown to mediate FA uptake in breast carcinoma (BC). The light chain of cysteine/glutamate amino acid exchange transporter system Xc (xCT)is crucial for the uptake of cysteine serving as a carbon and sulfur source that contributes to redox control, bioenergetics, and biosynthesis. In this study, targeting of FA and cysteine metabolic pathways was shown to be a potential strategy for managing BC by inhibiting FATP1 and xCT with arylpiperazine 5k and selenium-chrysin (SeChry), respectively. In BC cell lines, FATP1 expression is controlled by estrogen receptor β (ER-β) and promotes the accumulation of lipid droplets (LDs), which is associated with triple-negative breast carcinoma (TNBC) cells showing increased rates of cell proliferation, two-dimensional directional cell migration, and higher chemoresistance. Expression of xCT was also associated with the TNBC molecular BC subtype. In BC specimens, an association between FATP1 and xCT expression was observed. In vitro, SeChry induced ferroptosis in BC cells by targeting xCT and cysteine reliance and ultimately inducing cell death. In xenograft BC tumors, arylpiperazine 5k abrogated the effects of SeChry encapsulated in polyurea dendrimers functionalized with folate (SeChry@PUREG4-FA2) by reducing intracellular FA and rescuing ferroptosis. In vitro, SeChry sensitized BC cells to cisplatin and may therefore serve as an alternative in combination therapy. Overall, our study confirmed FATP1 as a marker and xCT as both a marker and a target in BC, particularly in TNBC. Induction of ferroptosis by interfering with xCT function may provide an opportunity to improve BC treatment, and a therapeutic approach using SeChry@PUREG4-FA2 is a promising strategy. © 2026 The Pathological Society of Great Britain and Ireland.
    Keywords:  SeChry nanoformulation (SeChry@PUREG4‐FA2); cysteine; fatty acid transport protein 1 (FATP1); fatty acids; ferroptosis; light chain of cysteine/glutamate amino acid exchange transporter system Xc (xCT)
    DOI:  https://doi.org/10.1002/path.70027
  18. Anal Methods. 2026 Feb 16.
    Spectroscopic characterization of chiral substances: proline and glutamine.
    Huiyu Yang, Xinrui Zhang, Qifubo Geng, Yang Gao, Zhuang Peng, Bo Su, Hailin Cui, Shengbo Zhang, Cunlin Zhang, Kai Li.
      Chiral substances such as proline and glutamine have garnered increasing attention due to their distinct biological roles in different enantiomeric forms. In this study, proline and glutamine were investigated using powder X-ray diffraction (PXRD), Raman spectroscopy, and terahertz time-domain spectroscopy (THz-TDS). PXRD confirmed the crystalline structures of the samples, while Raman spectroscopy showed limited ability to distinguish between enantiomers. In contrast, THz-TDS enabled clear differentiation based on peak positions and intensities. Quantitative analysis reveals a strong linear correlation between concentration and THz response. For L-proline, the average prediction accuracy attains 96% based on peak amplitude and 98% based on peak area. Similarly, for L-glutamine, the corresponding accuracies are 96% and 92%, respectively. Notably, the most effective indicators are the peak area of L-proline at 2.08 THz (R2 = 0.99980) and the peak amplitude of L-glutamine at 1.71 THz (R2 = 0.98521). Furthermore, THz spectral characteristics consistent with those of pure samples were observed in two commercial dietary supplements. These findings demonstrate that THz spectroscopy offers a rapid and effective method for identifying chiral active ingredients in dietary supplements.
    DOI:  https://doi.org/10.1039/d5ay02127h
  19. Environ Sci Technol. 2026 Feb 18.
    Imidacloprid Transformation Products Exhibit Stronger Developmental Neurotoxicity than the Parent Compound in Zebrafish (Danio rerio) via the Glutamate Signaling Pathway.
    Jin-Ge Zhang, Wen-Jun Shi, Zhou Cao, Zhi-Jie Lu, Na Xin, Dongdong Ma, Yun-Ze Meng, Qian-Qian Zhang, Guang-Guo Ying.
      Imidacloprid (IMI) and its transformation products (TPs; DNIMI, IMIOL, DNIMIOL, and 5OHIMI) are ubiquitous in aquatic ecosystems, yet their ecotoxicological impacts remain poorly characterized. Here, we investigated the developmental neurotoxicity of IMI and its TPs. Zebrafish were exposed to IMI, DNIMI, IMIOL, DNIMIOL, and 5OHIMI (0.005-500 μg/L) for 120 h postfertilization (hpf). DNIMI and IMIOL showed greater developmental and behavioral toxicity than IMI and other TPs and were therefore selected (0.05-500 μg/L) for further toxicokinetic and recovery investigations. Although IMI, IMIOL, and DNIMI accumulated to comparable levels by 72 hpf, DNIMI and IMIOL were cleared substantially more slowly than IMI, which resulted in higher internal residues after the depuration period. Consistent with their prolonged internal exposure, zebrafish exposed to DNIMI and IMIOL exhibited sustained hypoactivity postdepuration, accompanied by significantly reduced glutamate (GLU) levels and alternated transcription of GLU-related genes. The partial least-squares discriminant analysis (PLS-DA) identified GLU as a pivotal role (variable importance projection scores ≥1, p < 0.05). DNIMI and IMIOL downregulated genes involved in GLU synthesis and metabolism, concurrently decreasing glutamate decarboxylase and glutaminase levels while increasing glutamine synthetase levels. Exogenous GLU coexposure alleviated the locomotor activity, neurotransmitter alternations, and transcriptional perturbations, confirming disrupted GLU signaling contributes to the neurotoxicity of DNIMI and IMIOL. Overall, IMI-TPs induced stronger developmental neurotoxicity than IMI in zebrafish via GLU pathway disruption, highlighting their enhanced neurotoxic risks in aquatic environments.
    Keywords:  glutamate pathway; imidacloprid; neurotoxicity; transformation products
    DOI:  https://doi.org/10.1021/acs.est.6c00401
  20. Curr Diabetes Rev. 2026 Feb 13.
    COVID-19 Impact on Lipid Profile and Metabolome in Patients with Type 2 Diabetes Mellitus: Mini-Review.
    Karolina Pawłuszkiewicz, Anita Maria Faltus, Gabriela Augustynowicz, Zofia Bielenin, Agnieszka Bronowicka-Szydełko, Katarzyna Madziarska, Emil Paluch, Barbara Porębska, Joanna Kluz.
       AIM: This review aims to explore the pathophysiological mechanisms by which SARS-- CoV-2 affects lipid metabolism and the metabolome in patients with Type 2 Diabetes Mellitus (T2DM). It compares these alterations with those observed in non-diabetic individuals and proposes strategies to mitigate potential long-term metabolic complications.
    METHODS: A narrative review was conducted using PubMed, Scopus, and Google Scholar to identify studies published between 2004 and 2025 concerning adult T2DM patients during or after COVID-19 infection. The analysis focused on lipid profiles, including total cholesterol, high-density lipoprotein (HDL), low-density lipoprotein (LDL), and triglycerides, along with hemoglobin A1C levels and COVID-19 severity. Search terms included: (Post-COVID-19) AND (Diabetes Mellitus Type 2), ((Post-COVID-19) AND (Diabetes Mellitus Type 2)) AND (Lipid Profile), ((- COVID-19) AND (Lipid Profile)) AND (Diabetes Mellitus Type 2), (Post-COVID-19) AND (Lipid Metabolism), (COVID-19) AND (Lipid Metabolism), (Post-COVID-19) AND (Metabolome), (COVID-19) AND (Metabolome).
    RESULTS: Post-COVID-19, patients with T2DM exhibit persistent disturbances in lipid metabolism and broader metabolic pathways. SARS-CoV-2 infection amplifies metabolic dysregulation, leading to decreased levels of total cholesterol, HDL, and LDL, while triglyceride levels remain variable. Mechanistically, the virus disrupts lipid homeostasis by upregulating genes such as CD36 and peroxisome proliferator-activated receptor gamma (PPAR-γ) and by altering amino acid metabolism, particularly within the tryptophan-kynurenine and glutamine pathways. Enhanced oxidative stress and lipid peroxidation contribute to systemic inflammation and endothelial dysfunction. Furthermore, glycemic control worsens due to increased insulin resistance and pancreatic interactions involving angiotensin-converting enzyme 2 (ACE2).
    CONCLUSION: COVID-19 significantly alters lipid metabolism and the metabolomic profile in individuals with T2DM. Longitudinal studies are warranted to clarify the duration and clinical impact of these changes and to develop personalized therapeutic strategies for this high-risk population.
    Keywords:  COVID-19; T2DM2 patients.; diabetes mellitus; insulin resistance; lipid metabolism; metabolome; type 2
    DOI:  https://doi.org/10.2174/0115733998404775251202121401
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