Radiosensitizing effects of pyrogallol-loaded mesoporous or-ganosilica nanoparticles on gastric cancer by amplified ferroptosis

Radiotherapy (RT) incorporated multidisciplinary treatment is producing excellent clinical results, but its efficacy in treating late-stage gastric cancer is constrained by radioresistance and RT-related toxicity. Especially, since reactive oxygen species are the pivotal effectual molecules of ionizing radiation, improving ROS production by nanoparticles and other pharmacological modulation to amplify oxidation of polyunsaturated fatty acids and subsequent ferroptotic cell death is shown to enhance cancer cell radioresponse. Herein, we constructed a nanosystem by loading Pyrogallol (PG), a polyphenol compound and ROS generator, into mesoporous organosilica nanoparticles named as MON@pG. The nanoparticles exhibit proper size distribution with amplified ROS production and substantial glutathione depletion under X-ray radiation in gastric cancer cell line. Meanwhile, MON@PG enhanced radiosensitivity of gastric cancer in xenograft tumor model by ROS-mediated accumulation of DNA damage and apoptosis. Furthermore, this augmented oxidative process induced mitochondrial dysfunction and ferroptosis. In summary, MON@PG nanoparticles show the capacity to improve RT potency in gastric cancer by disrupting redox balance and augmenting ferroptosis.

[1]  Hongyan Li,et al.  Bioinspired nanocatalytic tumor therapy by simultaneous reactive oxygen species generation enhancement and glutamine pathway-mediated glutathione depletion. , 2022, Journal of materials chemistry. B.

[2]  E. Gavathiotis,et al.  Mitochondrial dynamics proteins as emerging drug targets. , 2022, Trends in pharmacological sciences.

[3]  Xiang Li,et al.  Biomimetic CuS nanoparticles for radiosensitization with mild photothermal therapy and GSH-depletion , 2022, Frontiers in Oncology.

[4]  Rasha R Radwan,et al.  Design of pH-responsive polymeric nanocarrier for targeted delivery of pyrogallol with enhanced antitumor potential in colon cancer. , 2022, Archives of biochemistry and biophysics.

[5]  G. Tortora,et al.  Immunogenic Cell Death: An Emerging Target in Gastrointestinal Cancers , 2022, Cells.

[6]  A. Pepoyan,et al.  Evaluation of Malondialdehyde Levels, Oxidative Stress and Host–Bacteria Interactions: Escherichia coli and Salmonella Derby , 2022, Cells.

[7]  Jun Zhang,et al.  Synergistic Radiosensitization Mediated by Chemodynamic Therapy via a Novel Biodegradable Peroxidases Mimicking Nanohybrid , 2022, Frontiers in Oncology.

[8]  Zhenhao Li,et al.  Improved Immunotherapy for Gastric Cancer by Nanocomposites with Capability of Triggering Dual-Damage of Nuclear/Mitochondrial DNA and Cgas/Sting-Mediated Innate Immunity , 2022, SSRN Electronic Journal.

[9]  T. Behl,et al.  Ferroptosis: A New Road towards Cancer Management , 2022, Molecules.

[10]  K. Takeda,et al.  Palliative radiotherapy for gastric cancer bleeding: a multi-institutional retrospective study , 2022, BMC Palliative Care.

[11]  A. Jemal,et al.  Cancer statistics, 2022 , 2022, CA: a cancer journal for clinicians.

[12]  Yu Mao,et al.  Knockdown of SHMT2 enhances the sensitivity of gastric cancer cells to radiotherapy through the Wnt/β-catenin pathway , 2022, Open life sciences.

[13]  Xiangxia Luo,et al.  Ionizing Radiation Upregulates Glutamine Metabolism and Induces Cell Death via Accumulation of Reactive Oxygen Species , 2021, Oxidative Medicine and Cellular Longevity.

[14]  Jiang Zheng,et al.  Imbalanced GSH/ROS and sequential cell death , 2021, Journal of biochemical and molecular toxicology.

[15]  Shulian Wang,et al.  Efficacy and toxicity of capecitabine combined with intensity-modulated radiotherapy after D1/D2 lymph node dissection in patients with gastric cancer , 2021, World journal of gastrointestinal oncology.

[16]  W. Koom,et al.  Efficacy of radiotherapy for gastric bleeding associated with advanced gastric cancer , 2021, Radiation oncology.

[17]  Li Li,et al.  Coordination and Redox Dual-Responsive Mesoporous Organosilica Nanoparticles Amplify Immunogenic Cell Death for Cancer Chemoimmunotherapy. , 2021, Small.

[18]  Junjie Chen,et al.  mTORC1 couples cyst(e)ine availability with GPX4 protein synthesis and ferroptosis regulation , 2021, Nature Communications.

[19]  F. Lordick,et al.  Adjuvant Radiotherapy for Gastric Cancer - End of the Road? , 2020, Annals of oncology : official journal of the European Society for Medical Oncology.

[20]  D. S. Petrov,et al.  Glutathione system in the blood of gastric cancer patients with various tumor histotypes and prevalence of the disease. , 2020 .

[21]  Yunfeng Zhou,et al.  Glutathione‐Depleting Nanoenzyme and Glucose Oxidase Combination for Hypoxia Modulation and Radiotherapy Enhancement , 2020, Advanced healthcare materials.

[22]  Y. Liang,et al.  Biodegradable hollow mesoporous organosilica nanotheranostics (HMON) for multi-mode imaging and mild photo-therapeutic-induced mitochondrial damage on gastric cancer , 2020, Journal of Nanobiotechnology.

[23]  Fangyuan Hu,et al.  Mitochondrial DNA drives noncanonical inflammation activation via cGAS–STING signaling pathway in retinal microvascular endothelial cells , 2020, Cell communication and signaling : CCS.

[24]  F. Hakkim,et al.  In Vivo Anti Cancer Potential of Pyrogallol in Murine Model of Colon Cancer , 2019, Asian Pacific journal of cancer prevention : APJCP.

[25]  T. Vanden Berghe,et al.  Targeting Ferroptosis to Iron Out Cancer. , 2019, Cancer cell.

[26]  Gang Zhao,et al.  Effect of Laparoscopic vs Open Distal Gastrectomy on 3-Year Disease-Free Survival in Patients With Locally Advanced Gastric Cancer: The CLASS-01 Randomized Clinical Trial. , 2019, JAMA.

[27]  Chunshui Yu,et al.  Radiation-responsive scintillating nanotheranostics for reduced hypoxic radioresistance under ROS/NO-mediated tumor microenvironment regulation , 2018, Theranostics.

[28]  Jun Lin,et al.  Tumor Microenvironment‐Responsive Mesoporous MnO2‐Coated Upconversion Nanoplatform for Self‐Enhanced Tumor Theranostics , 2018, Advanced Functional Materials.

[29]  Jelena Kolosnjaj-Tabi,et al.  Intracellular Biodegradation of Ag Nanoparticles, Storage in Ferritin, and Protection by a Au Shell for Enhanced Photothermal Therapy. , 2018, ACS nano.

[30]  A. Siegbahn,et al.  Estimation of Risk of Normal-tissue Toxicity Following Gastric Cancer Radiotherapy with Photon- or Scanned Proton-beams. , 2018, Anticancer research.

[31]  Jing Yu,et al.  Thiol-capped Bi nanoparticles as stable and all-in-one type theranostic nanoagents for tumor imaging and thermoradiotherapy. , 2018, Biomaterials.

[32]  Han Lin,et al.  Ultrasmall mesoporous organosilica nanoparticles: Morphology modulations and redox-responsive biodegradability for tumor-specific drug delivery. , 2018, Biomaterials.

[33]  Yongchang Wei,et al.  Reactive Oxygen Species-Mediated Tumor Microenvironment Transformation: The Mechanism of Radioresistant Gastric Cancer , 2018, Oxidative medicine and cellular longevity.

[34]  Na Li,et al.  A mitochondria-targeted nanoradiosensitizer activating reactive oxygen species burst for enhanced radiation therapy† †Electronic supplementary information (ESI) available. See DOI: 10.1039/c7sc04458e , 2018, Chemical science.

[35]  Kai Yang,et al.  Biodegradable Hollow Mesoporous Organosilica Nanotheranostics for Mild Hyperthermia-Induced Bubble-Enhanced Oxygen-Sensitized Radiotherapy. , 2018, ACS nano.

[36]  Xin-Hua Feng,et al.  Mitochondrial dynamics controls anti-tumour innate immunity by regulating CHIP-IRF1 axis stability , 2017, Nature Communications.

[37]  Haocai Chang,et al.  Induction of reactive oxygen species: an emerging approach for cancer therapy , 2017, Apoptosis.

[38]  D. Averill-Bates,et al.  Activation of apoptosis signalling pathways by reactive oxygen species. , 2016, Biochimica et biophysica acta.

[39]  W. Park Pyrogallol induces the death of human pulmonary fibroblast cells through ROS increase and GSH depletion. , 2016, International journal of oncology.

[40]  Matthew E. Welsch,et al.  Pharmacological inhibition of cystine–glutamate exchange induces endoplasmic reticulum stress and ferroptosis , 2014, eLife.

[41]  Jianbin Tang,et al.  Tumor Redox Heterogeneity‐Responsive Prodrug Nanocapsules for Cancer Chemotherapy , 2013, Advanced materials.

[42]  P. Lambin,et al.  PERK/eIF2α signaling protects therapy resistant hypoxic cells through induction of glutathione synthesis and protection against ROS , 2013, Proceedings of the National Academy of Sciences.

[43]  Masahiro Hiraoka,et al.  Microenvironment and Radiation Therapy , 2012, BioMed research international.

[44]  M. Yoshimura,et al.  Cancer cells that survive radiation therapy acquire HIF-1 activity and translocate towards tumour blood vessels , 2012, Nature Communications.

[45]  S. Ghosh,et al.  Mitochondria in innate immune responses , 2011, Nature Reviews Immunology.

[46]  A. Giaccia,et al.  Hypoxia, inflammation, and the tumor microenvironment in metastatic disease , 2010, Cancer and Metastasis Reviews.

[47]  A. El-Osta,et al.  γH2AX: a sensitive molecular marker of DNA damage and repair , 2010, Leukemia.

[48]  Jeffrey W. Smith,et al.  Mitochondrial p32 Protein Is a Critical Regulator of Tumor Metabolism via Maintenance of Oxidative Phosphorylation , 2010, Molecular and Cellular Biology.

[49]  Shelly C. Lu Regulation of glutathione synthesis. , 2009, Molecular aspects of medicine.

[50]  J. Brown,et al.  Exploiting tumour hypoxia in cancer treatment , 2004, Nature Reviews Cancer.

[51]  D. Hallahan,et al.  Inhibition of vascular endothelial growth factor receptor signaling leads to reversal of tumor resistance to radiotherapy. , 2001, Cancer research.

[52]  A. Porter,et al.  Emerging roles of caspase-3 in apoptosis , 1999, Cell Death and Differentiation.

[53]  Sang Woo Kim,et al.  Pyrogallol inhibits the growth of gastric cancer SNU-484 cells via induction of apoptosis. , 2008, International journal of molecular medicine.

[54]  P. Olive,et al.  The comet assay: a method to measure DNA damage in individual cells , 2006, Nature Protocols.