bims-glucam Biomed News
on Glutamine cancer metabolism
Issue of 2024‒08‒25
thirteen papers selected by
Sreeparna Banerjee, Middle East Technical University
  1. Prediction of Prognosis and Immunotherapy Response of Gastric Cancer Based on Glutamine Metabolism-Related Genes.
  2. YTHDF1 regulates GID8-mediated glutamine metabolism to promote colorectal cancer progression in a m6A-dependent manner.
  3. Aerobic glycolysis but not GLS1-dependent glutamine metabolism is critical for anti-tumor immunity and response to checkpoint inhibition.
  4. CB-839 Induces Reversible Dormancy in Lung Tumor-cells.
  5. The critical role of glutamine and fatty acids in the metabolic reprogramming of anoikis-resistant melanoma cells.
  6. Differential effect of asparagine and glutamine removal on three adenocarcinoma cell lines.
  7. A mini-review-cancer energy reprogramming on drug resistance and immune response.
  8. Cervical mucus can be used for metabolite screening in cervical cancer.
  9. Cancer tissue of origin constrains the growth and metabolism of metastases.
  10. Connecting the dots: investigating the link between environmental, genetic, and epigenetic influences in metabolomic alterations in oral squamous cell carcinoma.
  11. Discovery of the 1-naphthylamine biodegradation pathway reveals a broad-substrate-spectrum enzyme catalyzing 1-naphthylamine glutamylation.
  12. Oxidative Phosphorylation and Fatty Acid Oxidation in Slow-Aging Mice.
  13. Multi-Enzyme Mimetic MoCu Dual-Atom Nanozyme Triggering Oxidative Stress Cascade Amplification for High-Efficiency Synergistic Cancer Therapy.
  1. Curr Med Chem. 2024 Aug 20.
    Prediction of Prognosis and Immunotherapy Response of Gastric Cancer Based on Glutamine Metabolism-Related Genes.
    Saisai Gong, Sheng Yang, Tianyi Zhang, Jie Li, Xin Wan, Yifei Fang, Tong Liu, Chengyun Li, Yun Zhou, Geyu Liang.
      BACKGROUND: Reprogramming of glutamine metabolism in Gastric Cancer (GC) can significantly affect the tumor immune microenvironment and immunotherapy. This study examines the role of glutamine metabolism in the microenvironment and prognosis of gastric cancer.METHODS: We obtained gene expression data and clinical information of patients from the TCGA database. The patients were divided into two metabolic subtypes based on consistent clustering. A prognostic risk model containing three glutamine metabolism-related genes (GMRGs) was developed using Lasso-Cox. It was validated by the GEO validation cohort. Additionally, the immune microenvironment composition of the highand low-risk groups was assessed using ESTIMATE, CIBERSORT, and ssGSEA. Drug sensitivity analysis was conducted using the "oncoPredict" R package.
    RESULTS: We outlined the distinct clinical characteristics of two subtypes and developed a prognostic risk model. The high-risk group has a poorer prognosis due to an increased expression of immune checkpoints and immunosuppressive cellular infiltration. Our analysis, which included Cox risk regression, ROC curves, and nomogram, demonstrated that this risk model is an independent prognostic factor. The TIDE score was higher in the high-risk group than in the low-risk group. Additionally, the high-risk group did not respond well to chemotherapeutic drug treatment.
    CONCLUSION: This study shows that modelling glutamine metabolism is a good predictor of prognosis and immunotherapy efficacy in gastric cancer. Thus, we can better understand the role of glutamine metabolism in the development of cancer and use these insights to develop more targeted and effective treatments.
    Keywords:  Gastric cancer; glutamine metabolism; immunotherapy; prognostic model; targeted drug.; tumor microenvironment
    DOI:  https://doi.org/10.2174/0109298673297812240811182813
  2. Cancer Lett. 2024 Aug 14. pii: S0304-3835(24)00581-0. [Epub ahead of print] 217186
    YTHDF1 regulates GID8-mediated glutamine metabolism to promote colorectal cancer progression in a m6A-dependent manner.
    Yicun Han, Yunzhou Pu, Xiaodie Liu, Zhiyi Liu, Yongqi Chen, Lei Tang, Jing Zhou, Qing Song, Qing Ji.
      Dysregulation of epigenetics is a hallmark of cancer development, and YTHDF1 stands out as a crucial epigenetic regulator with the highest DNA copy number variation among all N6-methyladenosine (m6A) regulators in colorectal cancer (CRC) patients. Here, we aimed to investigate the specific contribution of YTHDF1 overexpression to CRC progression and its consequences. Through multiple bioinformatic analysis of human cancer databases and clinical CRC samples, we identified GID8/Twa1 as a crucial downstream target of YTHDF1. YTHDF1 manipulates GID8 translation efficiency in a m6A-dependent manner, and high expression of GID8 is associated with more aggressive tumor progression and poor overall survival. Mechanistically, GID8 is intimately associated with glutamine metabolic demands by maintaining active glutamine uptake and metabolism through the regulation of excitatory amino acid transporter 1 (SLC1A3) and glutaminase (GLS), thereby facilitating the malignant progression of CRC. Inhibition of GID8 attenuated CRC proliferation and metastasis both in vitro and in vivo. In summary, we identified a previously unknown target pertaining to glutamine uptake and metabolism in tumor cells, underscoring the potential of GID8 in the treatment of CRC.
    Keywords:  GID8/Twa1; SLC1A3; YTHDF1; colorectal cancer; glutamine metabolic reprogramming
    DOI:  https://doi.org/10.1016/j.canlet.2024.217186
  3. Cell Rep. 2024 Aug 18. pii: S2211-1247(24)00982-3. [Epub ahead of print]43(8): 114632
    Aerobic glycolysis but not GLS1-dependent glutamine metabolism is critical for anti-tumor immunity and response to checkpoint inhibition.
    Patrick M Gubser, Sharanya Wijesinghe, Leonie Heyden, Sarah S Gabriel, David P de Souza, Christoph Hess, Malcolm M McConville, Daniel T Utzschneider, Axel Kallies.
      Tumor cells undergo uncontrolled proliferation driven by enhanced anabolic metabolism including glycolysis and glutaminolysis. Targeting these pathways to inhibit cancer growth is a strategy for cancer treatment. Critically, however, tumor-responsive T cells share metabolic features with cancer cells, making them susceptible to these treatments as well. Here, we assess the impact on anti-tumor T cell immunity and T cell exhaustion by genetic ablation of lactate dehydrogenase A (LDHA) and glutaminase1 (GLS1), key enzymes in aerobic glycolysis and glutaminolysis. Loss of LDHA severely impairs expansion of T cells in response to tumors and chronic infection. In contrast, T cells lacking GLS1 can compensate for impaired glutaminolysis by engaging alternative pathways, including upregulation of asparagine synthetase, and thus efficiently respond to tumor challenge and chronic infection as well as immune checkpoint blockade. Targeting GLS1-dependent glutaminolysis, but not aerobic glycolysis, may therefore be a successful strategy in cancer treatment, particularly in combination with immunotherapy.
    Keywords:  CP: Cancer; CP: Metabolism; GLS1; LDHA; Tpex
    DOI:  https://doi.org/10.1016/j.celrep.2024.114632
  4. Eur J Pharmacol. 2024 Aug 17. pii: S0014-2999(24)00601-0. [Epub ahead of print] 176912
    CB-839 Induces Reversible Dormancy in Lung Tumor-cells.
    Azemat Jamshidi-Parsian, Samir V Jenkins, Amy Tran, Anna Bragg, Rylie Davis, Connor Griffin, Eric Siegel, Ruud P M Dings, Robert J Griffin, Gunnar Boysen.
      Glutaminase inhibitors are currently being explored as potential treatments for cancer. This study aimed to elucidate the molecular mechanisms underlying the effects of CB-839 on lung tumor cell lines compared to non-tumor cell lines. Viability assays based on NADPH-dependent dehydrogenases activity, ATP energy production, or mitochondrial reductase activity were used to determine that CB-839 caused significant tumor cell specific inhibition of cellular functions. Clonogenic survival assay revealed a dose dependent reduction in clonogenic survival of various lung tumor cells presenting estimated IC50 values between 10 and 90 nM, while no effect on non-tumor cells was observed. CB-839 led to a 20% reduction in glutaminase (GLS1, a mitochondrial enzyme that catalyzes the conversion of glutamine to glutamate) activity, and a dose-dependent reduced glutamine consumption in tumor cells and had no effect on non-tumor cells. Cell cycle analysis showed the CB-839 did not lead to cell cycle arrest. Apoptosis and necrosis assays revealed an only slight increase in apoptosis in tumor cells. Furthermore, a trypan blue exclusion assay revealed about 40% growth reduction in tumor cells at 0.1-1 μM CB-839 treatment. Surprisingly, treated cells resumed normal growth when re-plated in a drug-free medium, demonstrating reversibility. In hypoxic conditions, CB-839's effect on clonogenic survival was amplified in a dose dependent manner consistent with increased role of GLS1 for energy production under hypoxic conditions. In conclusion, these results suggest CB-839 efficacy is linked to temporary and reversible reduction in glutamine utilization suggesting induction of dormancy.
    Keywords:  CB-839; GLS1 inhibitor; Glutaminase; Lung Cancer
    DOI:  https://doi.org/10.1016/j.ejphar.2024.176912
  5. Front Pharmacol. 2024 ;15 1422281
    The critical role of glutamine and fatty acids in the metabolic reprogramming of anoikis-resistant melanoma cells.
    S Peppicelli, T Kersikla, G Menegazzi, E Andreucci, J Ruzzolini, C Nediani, F Bianchini, L Calorini.
      Introduction: Circulating tumor cells (CTCs) represent the sub-population of cells shed into the vasculature and able to survive in the bloodstream, adhere to target vascular endothelial cells, and re-growth into the distant organ. CTCs have been found in the blood of most solid tumor-bearing patients and are used as a diagnostic marker. Although a complex genotypic and phenotypic signature characterizes CTCs, the ability to survive in suspension constitutes the most critical property, known as resistance to anoikis, e.g., the ability to resist apoptosis resulting from a loss of substrate adhesion. Here, we selected melanoma cells resistant to anoikis, and we studied their metabolic reprogramming, with the aim of identifying new metabolic targets of CTCs. Methods: Subpopulations of melanoma cells expressing a high anoikis-resistant phenotype were selected by three consecutive rocking exposures in suspension and studied for their phenotypic and metabolic characteristics. Moreover, we tested the efficacy of different metabolic inhibitors targeting glycolysis (2DG), LDHA (LDHA-in-3), the mitochondrial electron transport chain complex I (rotenone), glutaminase (BPTES), fatty acid transporter (SSO), fatty acid synthase (denifanstat), CPT1 (etomoxir), to inhibit cell survival and colony formation ability after 24 h of rocking condition. Results: Anoikis-resistant cells displayed higher ability to grow in suspension on agarose-covered dishes respect to control cells, and higher cell viability and colony formation capability after a further step in rocking condition. They showed also an epithelial-to-mesenchymal transition associated with high invasiveness and a stemness-like phenotype. Anoikis-resistant melanoma cells in suspension showed a metabolic reprogramming from a characteristic glycolytic metabolism toward a more oxidative metabolism based on the use of glutamine and fatty acids, while re-adhesion on the dishes reversed the metabolism to glycolysis. The treatment with metabolic inhibitors highlighted the effectiveness of rotenone, BPTES, SSO, and etomoxir in reducing the viability and the colony formation ability of cells capable of surviving in suspension, confirming the dependence of their metabolism on oxidative phosphorylation, using glutamine and fatty acids as the most important fuels. Discussion: This finding opens up new therapeutic strategies based on metabolic inhibitors of glutaminase and fatty acid oxidation for the treatment of CTCs and melanoma metastases.
    Keywords:  anoikis resistance; cell metabolism; circulating tumor cells; melanoma; therapy
    DOI:  https://doi.org/10.3389/fphar.2024.1422281
  6. Heliyon. 2024 Aug 15. 10(15): e35789
    Differential effect of asparagine and glutamine removal on three adenocarcinoma cell lines.
    Greta Pessino, Leonardo Lonati, Claudia Scotti, Silvia Calandra, Ornella Cazzalini, Ombretta Iaria, Andrea Previtali, Giorgio Baiocco, Paola Perucca, Anna Tricarico, Martina Vetro, Lucia Anna Stivala, Carlo Ganini, Marta Cancelliere, Massimo Zucchetti, Isabella Guardamagna, Maristella Maggi.
      Asparagine and glutamine depletion operated by the drug Asparaginase (ASNase) has revolutionized therapy in pediatric patients affected by Acute Lymphoblastic Leukemia (ALL), bringing remissions to a remarkable 90 % of cases. However, the knowledge of the proproliferative role of asparagine in adult and solid tumors is still limited. We have here analyzed the effect of ASNase on three adenocarcinoma cell lines (A549, lung adenocarcinoma, MCF-7, breast cancer, and 786-O, kidney cancer). In contrast to MCF-7 cells, 786-O and A549 cells proved to be a relevant target for cell cycle perturbation by asparagine and glutamine shortage. Indeed, when the cell-cycle was analyzed by flow cytometry, A549 showed a canonical response to asparaginase, 786-O cells, instead, showed a reduction of the percentage of cells in the G1 phase and an increase of those in the S-phase. Despite an increased number of PCNA and RPA70 positive nuclear foci, BrdU and EdU incorporation was absent or strongly delayed in treated 786-O cells, thus indicating a readiness of replication forks unmatched by DNA synthesis. In 786-O asparagine synthetase was reduced following treatment and glutamine synthetase was totally absent. Interestingly, DNA synthesis could be recovered by adding Gln to the medium. MCF-7 cells showed no significant changes in the cell cycle phases, in DNA-bound PCNA and in total PCNA, but a significant increase in ASNS and GS mRNA and protein expression. The collected data suggest that the effect observed on 786-O cells following ASNase treatment could rely on mechanisms which differ from those well-known and described for leukemic blasts, consisting of a complete block in the G1/S transition in proliferating cells and on an increase on non-proliferative (G0) blasts.
    Keywords:  Adenocarcinoma; Asparaginase; Asparagine synthetase; Breast carcinoma; Cell cycle; Glutamine synthetase; Renal cell carcinoma; Solid tumors
    DOI:  https://doi.org/10.1016/j.heliyon.2024.e35789
  7. Transl Oncol. 2024 Aug 19. pii: S1936-5233(24)00226-2. [Epub ahead of print]49 102099
    A mini-review-cancer energy reprogramming on drug resistance and immune response.
    Chengxiang Liu, Liuxin Yang, Tingting Gao, Xingxing Yuan, Ousman Bajinka, Kuanyu Wang.
      With the growing interest to harness cancer metabolism and energy reprogramming, this mini review aimed to explain the metabolic programming revealing the mechanisms regarding the treatment resistance. This mini review summarized the prominent cancer metabolic reprogramming on macromolecules. In addition, metabolic reprogramming explaining immune response and treatment resistance as well as energy reprogramming mechanisms are briefly discussed. Finally, some prospects in MR for reversing cancer drug resistance are highlighted.
    Keywords:  Cancer; Energy metabolism; Metabolic reprogramming; Treatment resistance
    DOI:  https://doi.org/10.1016/j.tranon.2024.102099
  8. Cancer Sci. 2024 Aug 22.
    Cervical mucus can be used for metabolite screening in cervical cancer.
    Rie Kawasaki, Iwao Kukimoto, Tetsuya Tsukamoto, Eiji Nishio, Aya Iwata, Takuma Fujii.
      Approximately 660,000 women are diagnosed with cervical cancer annually. Current screening options such as cytology or human papillomavirus testing have limitations, creating a need to identify more effective ancillary biomarkers for triage. Here, we evaluated whether metabolomic analysis of cervical mucus metabolism could be used to identify biomarkers of cervical intraepithelial neoplasia (CIN) and cervical cancer. The case-control group consisted of 181 CIN, 69 squamous cell carcinoma (SCC) patients, and 48 healthy controls in the primary cohort. We undertook metabolomic analyses using ultra-HPLC-tandem mass spectrometry. Univariate and multivariate analyses were carried out to profile metabolite characteristics, and receiver operating characteristic (ROC) analysis identified biomarker candidates. Five metabolites conferred the highest discriminatory power for SCC: oxidized glutathione (GSSG) (area under the ROC curve, 0.924; 95% confidence interval, 0.877-0.971), malic acid (0.914, 0.859-0.968), kynurenine (0.884, 0.823-0.945), GSSG/glutathione (GSH) (0.936, 0.892-0.979), and kynurenine/tryptophan (0.909, 0.856-0.961). Malic acid was the best marker for detection of CIN2 or worse (0.858, 0.793-0.922) and was a clinically useful metabolite. We confirmed the reproducibility of the results by validation cohort. Additionally, metabolomic analyses revealed eight pathways strongly associated with cervical neoplasia. Of these, only the tricarboxylic acid cycle was strongly associated with all CINs and cancer, indicating active energy production. Aberrant arginine metabolism by decreasing arginine and increasing citrulline might reduce tumor immunity. Changes in cysteine-methionine and GSH pathways might drive the initiation and progression of cervical cancer. These results suggest that metabolic analysis can identify ancillary biomarkers and could improve our understanding of the pathophysiological mechanisms underlying cervical neoplasia.
    Keywords:  HPV; TCA cycle; cervical cancer screening; malic acid; metabolome
    DOI:  https://doi.org/10.1111/cas.16323
  9. Nat Metab. 2024 Aug 19.
    Cancer tissue of origin constrains the growth and metabolism of metastases.
    Sharanya Sivanand, Yetis Gultekin, Peter S Winter, Sidney Y Vermeulen, Konstantine M Tchourine, Keene L Abbott, Laura V Danai, Florian Gourgue, Brian T Do, Kayla Crowder, Tenzin Kunchok, Allison N Lau, Alicia M Darnell, Alexandria Jefferson, Satoru Morita, Dan G Duda, Andrew J Aguirre, Brian M Wolpin, Nicole Henning, Virginia Spanoudaki, Laura Maiorino, Darrell J Irvine, Omer H Yilmaz, Caroline A Lewis, Dennis Vitkup, Alex K Shalek, Matthew G Vander Heiden.
      Metastases arise from subsets of cancer cells that disseminate from the primary tumour1,2. The ability of cancer cells to thrive in a new tissue site is influenced by genetic and epigenetic changes that are important for disease initiation and progression, but these factors alone do not predict if and where cancers metastasize3,4. Specific cancer types metastasize to consistent subsets of tissues, suggesting that primary tumour-associated factors influence where cancers can grow. We find primary and metastatic pancreatic tumours have metabolic similarities and that the tumour-initiating capacity and proliferation of both primary-derived and metastasis-derived cells is favoured in the primary site relative to the metastatic site. Moreover, propagating cells as tumours in the lung or the liver does not enhance their relative ability to form large tumours in those sites, change their preference to grow in the primary site, nor stably alter aspects of their metabolism relative to primary tumours. Primary liver and lung cancer cells also exhibit a preference to grow in their primary site relative to metastatic sites. These data suggest cancer tissue of origin influences both primary and metastatic tumour metabolism and may impact where cancer cells can metastasize.
    DOI:  https://doi.org/10.1038/s42255-024-01105-9
  10. J Exp Clin Cancer Res. 2024 Aug 21. 43(1): 239
    Connecting the dots: investigating the link between environmental, genetic, and epigenetic influences in metabolomic alterations in oral squamous cell carcinoma.
    Ishita Gupta, Fariba Badrzadeh, Yuri Tsentalovich, Daria A Gaykalova.
      Oral squamous cell carcinoma (OSCC) accounts for around 90% of all oral cancers and is the eighth most common cancer worldwide. Despite progress in managing OSCC, the overall prognosis remains poor, with a survival rate of around 50-60%, largely due to tumor size and recurrence. The challenges of late-stage diagnosis and limitations in current methods emphasize the urgent need for less invasive techniques to enable early detection and treatment, crucial for improving outcomes in this aggressive form of oral cancer. Research is currently aimed at unraveling tumor-specific metabolite profiles to identify candidate biomarkers as well as discover underlying pathways involved in the onset and progression of cancer that could be used as new targets for diagnostic and therapeutic purposes. Metabolomics is an advanced technological approach to identify metabolites in different sample types (biological fluids and tissues). Since OSCC promotes metabolic reprogramming influenced by a combination of genetic predisposition and environmental factors, including tobacco and alcohol consumption, and viral infections, the identification of distinct metabolites through screening may aid in the diagnosis of this condition. Moreover, studies have shown the use of metabolites during the catalysis of epigenetic modification, indicating a link between epigenetics and metabolism. In this review, we will focus on the link between environmental, genetic, and epigenetic influences in metabolomic alterations in OSCC. In addition, we will discuss therapeutic targets of tumor metabolism, which may prevent oral tumor growth, metastasis, and drug resistance.
    Keywords:  Epigenetics; Metabolism; Metabolomics; Oral squamous cell carcinoma; Risk factors
    DOI:  https://doi.org/10.1186/s13046-024-03141-5
  11. Elife. 2024 Aug 20. pii: e95555. [Epub ahead of print]13
    Discovery of the 1-naphthylamine biodegradation pathway reveals a broad-substrate-spectrum enzyme catalyzing 1-naphthylamine glutamylation.
    Shu-Ting Zhang, Shi-Kai Deng, Tao Li, Megan E Maloney, De-Feng Li, Jim C Spain, Ning-Yi Zhou.
      1-Naphthylamine (1NA), which is harmful to human and aquatic animals, has been used widely in the manufacturing of dyes, pesticides, and rubber antioxidants. Nevertheless, little is known about its environmental behavior and no bacteria have been reported to use it as the growth substrate. Herein, we describe a pathway for 1NA degradation in the isolate Pseudomonas sp. strain JS3066, determine the structure and mechanism of the enzyme NpaA1 that catalyzes the initial reaction, and reveal how the pathway evolved. From genetic and enzymatic analysis, a five gene-cluster encoding a dioxygenase system was determined to be responsible for the initial steps in 1NA degradation through glutamylation of 1NA. The γ-glutamylated 1NA was subsequently oxidized to 1,2-dihydroxynaphthalene which was further degraded by the well-established pathway of naphthalene degradation via catechol. A glutamine synthetase-like (GS-like) enzyme (NpaA1) initiates 1NA glutamylation, and this enzyme exhibits a broad substrate selectivity toward a variety of anilines and naphthylamine derivatives. Structural analysis revealed that the aromatic residues in the 1NA entry tunnel and the V201 site in the large substrate-binding pocket significantly influence NpaA1's substrate preferences. The findings enhance understanding of degrading polycyclic aromatic amines, and will also enable the application of bioremediation at naphthylamine contaminated sites.
    Keywords:  1-Naphthylamine; Glutamine synthetase; Pseudomonas; biochemistry; chemical biology
    DOI:  https://doi.org/10.7554/eLife.95555
  12. Free Radic Biol Med. 2024 Aug 15. pii: S0891-5849(24)00605-1. [Epub ahead of print]
    Oxidative Phosphorylation and Fatty Acid Oxidation in Slow-Aging Mice.
    Ahmed M Elmansi, Richard A Miller.
      Oxidative metabolism declines with aging in humans leading to multiple metabolic ailments and subsequent inflammation. In mice, there is evidence of age-related suppression of fatty acid oxidation and oxidative phosphorylation in the liver, heart, and muscles. Many interventions that extend healthy lifespan of mice have been developed, including genetic, pharmacological, and dietary interventions. In this article, we review the literature on oxidative metabolism changes in response to those interventions. We also discuss the molecular pathways that mediate those changes, and their potential as targets for future longevity interventions.
    DOI:  https://doi.org/10.1016/j.freeradbiomed.2024.08.018
  13. Angew Chem Int Ed Engl. 2024 Aug 21. e202413661
    Multi-Enzyme Mimetic MoCu Dual-Atom Nanozyme Triggering Oxidative Stress Cascade Amplification for High-Efficiency Synergistic Cancer Therapy.
    Ziyao Li, Binbin Ding, Jing Li, Hao Chen, Jiashi Zhang, Jia Tan, Xinyu Ma, Di Han, Ping'an Ma, Jun Lin.
      Single-atom nanozymes (SAzymes) with ultrahigh atom utilization efficiency have been extensively applied in reactive oxygen species (ROS)-mediated cancer therapy. However, the high energy barriers of reaction intermediates on single-atom sites and the overexpressed antioxidants in the tumor microenvironment restrict the amplification of tumor oxidative stress, resulting in unsatisfactory therapeutic efficacy. Herein, we report a multi-enzyme mimetic MoCu dual-atom nanozyme (MoCu DAzyme) with various catalytic active sites, which exhibits peroxidase, oxidase, glutathione (GSH) oxidase, and nicotinamide adenine dinucleotide phosphate (NADPH) oxidase mimicking activities. Compared with Mo SAzyme, the introduction of Cu atoms, formation of dual-atom sites, and synergetic catalytic effects among various active sites enhance substrate adsorption and reduce the energy barrier, thereby endowing MoCu DAzyme with stronger catalytic activities. Benefiting from the above enzyme-like activities, MoCu DAzyme can not only generate multiple ROS, but also deplete GSH and block its regeneration to trigger the cascade amplification of oxidative stress. Additionally, the strong optical absorption in the near-infrared II bio-window endows MoCu DAzyme with remarkable photothermal conversion performance. Consequently, MoCu DAzyme achieves high-efficiency synergistic cancer treatment incorporating collaborative catalytic therapy and photothermal therapy. This work will advance the therapeutic applications of DAzymes and provide valuable insights for nanocatalytic cancer therapy.
    Keywords:  catalytic therapy; dual-atom catalyst; nanozyme; oxidative stress; photothermal therapy
    DOI:  https://doi.org/10.1002/anie.202413661
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