Radiation Sensitivity Of Cells Research Articles

Bromelain augments ionizing radiation sensitivity in breast cancer cells: A synergistic approach

BackgroundRadiation-sensitizing agents, such as Bromelain (pineapple extract) have been shown to significantly impact cancer cell cycle arrest. This study investigates the anticancer properties of Bromelain on MCF-7 breast cancer cell line under both two-dimensional (2D) and three-dimensional (3D) culture conditions. MethodsBromelain enzyme was initially applied at concentrations of 75, 96, and 115 μg/ml to sensitize the MCF-7 cells under both 2D and 3D culture conditions. Following treatment, the cells were irradiated with doses of 2, 4, and 6 Gy. The synergistic effects of bromelain enzyme treatment and gamma irradiation on MCF-7 cells were assessed using the MTT assay, neutral red uptake assay, alkaline comet assay, nitric oxide (NO) release measurement, catalase activity assay, reduced glutathione quantification, and caspase 3 assay. Data were analyzed and presented as Mean ± SD using GraphPad InStat software V. 8. ResultsThe MTT assay indicated that the combination of bromelain and ionizing radiation have synergistic effects compared to cells treated with 2 Gy of X-ray alone. The results from of the MTT assay indicated showed that 75 μg/ml of bromelain did not induce exhibit significant cytotoxicity. Consistent with the MTT assay results, the Neutral red uptake assay demonstrated increased mortality in MCF-7 cells following treatment with both bromelain and ionizing radiation. Additionally, treatment with bromelain and ionizing radiation resulted in elevated levels of released NO, GSH content, and catalase enzyme activity compared to cells treated with bromelain alone. Furthermore, the Combination of ionizing radiation and bromelain synergistically enhanced caspase-3 enzyme activity and increased the number of necrotic and apoptotic cells compared to treatment with bromelain alone. ConclusionBromelain's capacity to induce apoptosis and enhance radio-sensitization offers promising potentialfor improving cancer treatment outcomes. By promoting programmed cell death and increasing the sensitivity of cancer cells to radiation, bromelain could contribute to more effective treatment regimens while potentially reducing the adverse effects associated with more aggressive therapies.

Effects of a novel HDAC6-selective inhibitor's radiosensitization on cancer cells.

The radiation sensitivity of tumor cells is a critical determinant of their therapeutic response to radiotherapy. Histone deacetylase 6 (HDAC6), beyond its known role in modulating tubulin acetylation and influencing cell motility, is also involved in the DNA damage response, potentially enhancing tumor cell radiosensitivity. Targeted HDAC6 inhibitors have shown substantial promise in preclinical studies aimed at increasing radiosensitivity and inhibiting cellular migration. A new HDAC inhibitor, named OXHA, was designed by substituting the phenyl cap of SAHA with an N,5-diphenyloxazole-2-carboxamide group. The inhibitory activity of OXHA was evaluated via in vitro enzymatic assays. Its effects on tumor cell migration and radiosensitization potential were assessed using scratch wound healing assays, micronucleus formation, and clonogenic survival assays. Enzymatic assays confirmed OXHA's selective inhibition of HDAC6. Compared to SAHA, OXHA significantly increased α-tubulin acetylation while minimally impacting histone H3 acetylation, indicating a high selectivity for HDAC6. In combination with X-ray irradiation, OXHA markedly impaired wound healing in A549 and HepG2 cells, enhanced micronucleus formation, and reduced clonogenic survival across multiple tumor lines. OXHA exhibits potent and selective HDAC6 inhibition, effectively impeding tumor cell migration and enhancing radiosensitivity across multiple cell lines. These findings suggest that OXHA has strong potential as a therapeutic strategy to improve radiotherapy efficacy.

Defining the role of Tip60 in the DNA damage response of glioma cell lines

Purpose Glioblastomas are resistant to conventional therapies, including radiotherapy. Our previous study proved that epigenetic regulation influences the radiation response of glioma cells. This study evaluated the role of the acetyltransferase Tip60 on the radiation response. Material and Methods Tip60 expression was down-regulated by transfecting specific siRNA’s in A7 and MO59K cells with high and low expression of Tip60, respectively, and its effect on survival was assessed. DNA repair was analyzed by foci scoring (γH2AX, Rad51, 53BP1, pATM). The interaction of Tip60 with ATM and DNA-PK was investigated using the specific inhibitors KU55933 and NU7441, respectively. Results Knockdown of Tip60 significantly (p < .001) reduced survival in both cell lines, but the effect was more pronounced in A7 cells. ATMi and DNA-PKi significantly reduced the surviving fraction following irradiation. However, no further effect of siTip60 on the radiosensitivity of ATMi treated A7 cells was observed. In contrast, DNA-PKi effectively enhanced the sensitizing effect of siTip60. Mechanistically, siTip60 reduced the number of initial Rad51 and ATM foci formation after irradiation and prevented their dissolution at 24 h. siTip60 had no impact on the formation of 53BP1 and γH2AX foci and did not further affect these end-points if combined with ATMi or DNA-PKi. Conclusions Downregulation of Tip60 enhances the radiation sensitivity of both glioma cells and markedly elevates the radiation sensitivity when combined with DNA-PKi. Therefore, treatment with DNA-PK inhibitors represents a promising approach to augment the radiation sensitivity of glioma cell lines with deficient Tip60 activity in a synergistic manner.

The Effect of Ionizing Irradiation on the Autotaxin-Lysophasphatidic Acid Axis and Interleukin-6/8 Secretion in Different Breast Cancer Cell Lines.

The Autotaxin (ATX)-lysophosphatidic acid (LPA) axis is involved in decreasing radiation sensitivity of breast tumor cells. This study aims to further elucidate the effect of irradiation on the ATX-LPA axis and cytokine secretion in different breast cancer cell lines to identify suitable breast cancer subtypes for targeted therapies. Different breast cancer cell lines (MCF-7 (luminal A), BT-474 (luminal B), SKBR-3 (HER2-positive), MDA-MB-231 and MDA-MB-468 (triple-negative)) and the breast epithelial cell line MCF-10A were irradiated. The influence of irradiation on LPA receptor (LPAR) expression, ATX expression, and Interleukin (IL)-6 and IL-8 secretion was analyzed. Further, the effect of IL-6 and IL-8 on ATX expression of adipose-derived stem cells (ADSC) was investigated. Irradiation increased ATX and LPAR2 expression in MDA-MB-231 cells. Additionally, IL-6 secretion was enhanced in MDA-MB-231, and IL-8 secretion in MDA-MB-231 and MDA-MB-468. Stimulation of ADSC with IL-6 and IL-8 increased ATX expression in ADSC. Targeting ATX or its downstream signaling pathways might enhance the sensitivity of triple-negative breast cancer cells to radiation. Further exploration of the interplay between irradiation, the ATX-LPA axis, and inflammatory cytokines may elucidate novel pathways for overcoming radioresistance and improving individual treatment outcomes.

1715: Pathological Phenotypes and Radiation Sensitivity of Airway Stem Cells Derived from COPD Patients.

1715: Pathological Phenotypes and Radiation Sensitivity of Airway Stem Cells Derived from COPD Patients.

Dual role of targeting NAE1 in nasopharyngeal carcinoma: Antitumor effects yet inducing radiotherapy resistance

Background and objectivesThe inhibitor MLN4924 of Neural Precursor Cell-Expressed Developmentally Down-Regulated 8 (NEDD8) Activating Enzyme 1 (NAE1) has been found to suppress the growth of nasopharyngeal carcinoma (NPC). However, its effect on NPC's radiotherapy sensitivity remains unclear. MethodsBy integrating single-cell RNA sequencing and bulk RNA sequencing, we predict the impact of NAE1 on the cell cycle, cell death, and its relationship with radiotherapy sensitivity and prognosis in NPC. The effect of inhibiting NAE1 on NPC cell behavior and radiation sensitivity is explored through MLN4924 intervention in vitro and in vivo. We construct a prognosis prediction model based on NAE1 using machine learning methods and validate the efficacy of NAE1 and the model in clinical cohorts. ResultsNPC patients with high NAE1 expression have better prognosis and higher expression in the radiotherapy-sensitive group. Inhibiting NAE1 with MLN4924 causes cell cycle arrest in NPC cells, preventing them from entering the G2/M phase, thereby inhibiting proliferation but not affecting migration and metastasis. However, in vitro and in vivo experiments demonstrate that inhibiting NAE1 with MLN4924 leads to increased resistance of NPC to radiation. ConclusionsTargeting NAE1 for NPC treatment may have dual effects, inhibiting NPC proliferation while also increasing radiation resistance.

Study on the sensitizing effect of SM-1 combined with irradiation on head and neck squamous cell carcinoma

Purpose Head and neck squamous cell carcinoma (HNSCC) is globally prevalent with high recurrence, low survival rate, and poor quality of life for patients. Derived from PAC-1, SM-1 can activate procaspase-3 and induce apoptosis in cancer cells to exert anti-tumor effects. However, the inhibitory effect of SM-1 on HNSCC after combination with radiation are unclear. This study aims to investigate the radiosensitizing effect of SM-1 on HNSCC in vitro and in vivo. Methods MTT method was used to detect the effect of SM-1 on the viability of HNSCC cell lines (HONE1, HSC-2, and CAL27). The effects of SM-1 combined with radiation on the survival index of HONE1, HSC-2, and CAL27 cell lines were determined by colony formation assay. Flow cytometry was used to investigate the effects of SM-1 and radiation combination on cell apoptosis and cell cycle, and western blot experiments were performed to detect the expression of apoptosis and cell cycle-related proteins. Finally, a xenograft tumor model of CAL27 was established to evaluate the anti-tumor effect of SM-1 combined with radiation in vivo. Results In vitro, SM-1 effectively inhibited the activity of HNSCC cell lines HONE1, HSC-2, and CAL27 cells, and synergistically showed anti-proliferation activity during combined irradiation. Meanwhile, anti-tumor effect of SM-1 on HNSCC was higher than that of Debio1143, and the radiosensitivity of cells was greatly increased. Flow cytometry and western blot analysis showed that SM-1 induced G2/M phase arrest of head and neck squamous cell carcinoma cells via inhibiting the expression of CyclinB1 and CDC2. Moreover, SM-1 activated caspase-3 activity and up-regulated the cleaved form of PARP1 to induce cell apoptosis. In vivo, SM-1 combined irradiation showed a good anti-tumor effect. Conclusion SM-1 enhances HNSCC cell radiation sensitivity in vitro and in vivo, supporting its potential as a radiosensitizer for clinical trials in combination with radiotherapy.

Role of Telomere Length in Radiation Response of Hematopoietic Stem & Progenitor Cells in Newborns

Objective Wide inter-individual variations in ionizing radiation (IR) responses of neonatal hematopoietic system calls for identifying reliable biomarkers to effectively estimate radiation exposure damages in neonates. Methods Association between telomere length (TL) at birth and radiation sensitivity of cord blood hematopoietic stem cells (HSC) from 166 healthy newborns were investigated by assessing their clonogenic differentiation. TL was determined as terminal restriction fragment (TRF) by Southern blot method. Results TL correlated with surviving fractions of total progenitor colony forming cell (CFC) content at 0.75 Gy (p < 0.05), granulo-macrophagic lineage colony forming units (CFU-GM) at 0.75 Gy (p < 0.05) and erythroid burst forming unit (BFU-E) at 0.75 Gy (p < 0.05) & at 3 Gy (p < 0.05) of newborns. Conclusion Our results indicate risks for HSC clonogenic survival in neonates with shorter telomeres after IR exposure. These observations might aid in considering TL at birth as an assessment factor for radiation related hematopoietic challenges in children.

Azido derivatives of sesquiterpene lactones: Synthesis, anticancer proliferation, and chemistry of nitrogen-centered radicals

Sesquiterpene lactones (SLs) such as parthenolide (PTL) and dehydroleucodine (DhL) selectively kill cancer cells without exerting normal tissue toxicity, potentially due to presence of α-methylene-γ-lactone (αMγL) fragment. We hypothesize that the addition of an azido group to the αMγL fragment of PTL or DhL further augments their anticancer properties as well as radiation sensitivity of cancer cells. Azido-SLs containing the azido group at the C14 methyl position of PTL (i.e., azido-melampomagnolide B, AzMMB) while preserving the mechanistically crucial exomethylene unit of αMγL fragment were also prepared. Sham-irradiated (i.e., unirradiated control) or irradiated human breast cancer cells (MCF7) were treated with different concentrations of azido-PTL (AzPTL) or azido-DhL (AzDhL) along with parental SLs. Proliferation rate of MCF7 cells were measured by MTT-assay, and their colony forming ability was determined by colony formation assay. Both AzPTL and AzDhL significantly suppress proliferation rate and colony forming ability of MCF-7 cells. AzPTL suppressed colony forming ability, not cellular proliferation, following irradiation to a greater extent than PTL at lower concentrations (5 and 10 μM). Electron spin resonance (ESR) studies were performed employing gamma-irradiated homogeneous supercooled aqueous solutions to investigate radical formation through addition of radiation-mediated prehydrated electrons to the azide group of AzPTL and AzDhL and to follow subsequent reactions of these radicals. In AzPTL, formation of a tertiary carbon-centered radical plausibly via a metastable aminyl radical was observed, whereas AzDhL produced both π-aminyl and α-azidoalkyl radicals. These radicals may contribute to the antitumor activities of AzPTL and AzDhL.

Oleandrin enhances radiotherapy sensitivity in lung cancer by inhibiting the ATM/ATR-mediated DNA damage response.

Despite active clinical trials on the use of Oleandrin alone or in combination with other drugs for the treatment of solid tumors, the potential synergistic effect of Oleandrin with radiotherapy remains unknown. This study reveals a new mechanism by which Oleandrin targets ATM and ATR kinase-mediated radiosensitization in lung cancer. Various assays, including clonogenic, Comet, immunofluorescence staining, apoptosis and Cell cycle assays, were conducted to evaluate the impact of oleandrin on radiation-induced double-strand break repair and cell cycle distribution. Western blot analysis was utilized to investigate alterations in signal transduction pathways related to double-strand break repair. The efficacy and toxicity of the combined therapy were assessed in a preclinical xenotransplantation model. Functionally, Oleandrin weakens the DNA damage repair ability and enhances the radiation sensitivity of lung cells. Mechanistically, Oleandrin inhibits ATM and ATR kinase activities, blocking the transmission of ATM-CHK2 and ATR-CHK1 cell cycle checkpoint signaling axes. This accelerates the passage of tumor cells through the G2 phase after radiotherapy, substantially facilitating the rapid entry of large numbers of inadequately repaired cells into mitosis and ultimately triggering mitotic catastrophe. The combined treatment of Oleandrin and radiotherapy demonstrated superior inhibition of tumor proliferation compared to either treatment alone. Our findings highlight Oleandrin as a novel and effective inhibitor of ATM and ATR kinase, offering new possibilities for the development of clinical radiosensitizing adjuvants.

The COP9 signalosome stabilized MALT1 promotes Non-Small Cell Lung Cancer progression through activation of NF-κB pathway

MALT1 has been implicated as an upstream regulator of NF-κB signaling in immune cells and tumors. This study determined the regulatory mechanisms and biological functions of MALT1 in non-small cell lung cancer (NSCLC). In cell culture and orthotopic xenograft models, MALT1 suppression via gene expression interference or protein activity inhibition significantly impaired malignant phenotypes and enhanced radiation sensitivity of NSCLC cells. CSN5, the core subunit of COP9 signalosome, was firstly verified to stabilize MALT1 via disturbing the interaction with E3 ligase FBXO3. Loss of FBXO3 in NSCLC cells reduced MALT1 ubiquitination and promoted its accumulation, which was reversed by CSN5 interference. An association between CSN5/FBXO3/MALT1 regulatory axis and poor prognosis in NSCLC patients was identified. Our findings revealed the detail mechanism of continuous MALT1 activation in NF-κB signaling, highlighting its significance as predictor and potential therapeutic target in NSCLC.Graphical

Ras-Targeting Stabilized Peptide Increases Radiation Sensitivity of Cancer Cells.

Radiation therapy is one of the most common treatments for cancer. However, enhancing tumors' radiation sensitivity and overcoming tolerance remain a challenge. Previous studies have shown that the Ras signaling pathway directly influences tumor radiation sensitivity. Herein, we designed a series of Ras-targeting stabilized peptides, with satisfactory binding affinity (KD = 0.13 μM with HRas) and good cellular uptake. Peptide H5 inhibited downstream phosphorylation of ERK and increased radio-sensitivity in HeLa cells, resulting in significantly reduced clonogenic survival. The stabilized peptides, designed with an N-terminal nucleation strategy, acted as potential radio-sensitizers and broadened the applications of this kind of molecule. This is the first report of using stabilized peptides as radio-sensitizers, broadening the applications of this kind of molecule.

Abstract 690: Investigation of BH-3 mimetics as radiosensitizing agents in glioblastoma

Abstract Glioblastoma (GBM) is a highly aggressive primary brain tumor. Treatment consists of maximal safe tumor resection, chemotherapy (temozolomide) and radiotherapy; however, this aggressive treatment offers only a modest improvement in outcomes, with average life expectancy of approximately 12 months. Consequently, novel, effective and easily translatable therapies are urgently required. While radiotherapy is an effective treatment for many solid tumors, GBM displays an innate radio-resistance that contributes to treatment failure. Therefore, there is a need to identify chemotherapeutics that can be used as radiosensitizers to increase efficacy. Notably, a key pathway involved in therapeutic resistance is apoptotic evasion, which is driven by upregulation of pro-survival BCL-2 proteins that inhibit the pro-apoptotic proteins necessary for the apoptotic response. Recent advances in drug development have produced a range of BH3 mimetics - novel chemotherapeutics with potential to reinstate apoptosis by targeting specific pro-survival molecules. We hypothesized that the radiation sensitivity of GBM cells would be enhanced by using BH3 mimetics to inhibit pro-survival molecules and release the apoptotic block. A panel of BH3 mimetics was tested in combination with radiotherapy across three patient-derived GBM cell lines (G7, E2 and R15), using a 3D clonogenic culture system that recapitulates in vivo growth patterns and responses. We found that the BCL-XL inhibitor, A1331852, significantly radiosensitized all 3 GBM lines. In addition, Western blot analysis revealed A1331852 to induce PARP1 cleavage in G7 cells when used as a single agent. Subsequent in vivo studies were conducted in our well characterized orthotopic G7 xenograft murine model of GBM. Immunohistochemical studies showed that the pro-survival proteins MCL-1 and BCL-XL were upregulated in irradiated tumors. Furthermore, a pharmacokinetic study in the same orthotopic murine model, allowing for drug delivery evaluation, and optimized treatment scheduling. Importantly, A1331852 was found to be blood brain barrier penetrant at 25 mg/kg, with increased drug detected in tumor vs normal brain tissue. From these data, a survival study investigating A1331852 as a radiosensitizing agent was carried out in the same G7 GBM orthotopic xenograft model. Kaplan-Meier analysis showed an increase in survival of mice treated with A133852 plus radiotherapy compared with the radiotherapy only group (p = 0.0309). Overall, we have demonstrated that dependence on BCL-2 family proteins is a vulnerability that can be targeted to improve radiotherapy response in GBM. Furthermore, we have identified a promising BH3 mimetic, A1331852, to use in combination with RT and have completed a proof-of-concept in vivo study that confirms the potential of BH3 mimetics to improve outcomes for patients with GBM. Citation Format: Louise R. Dutton, Clara Mullen, Anna L. Koessinger, Mark Jackson, Katrina Stevenson, Anthony J. Chalmers, Stephen Tait, Kirsteen J. Campbell, Joanna L. Birch. Investigation of BH-3 mimetics as radiosensitizing agents in glioblastoma [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 690.

Modification of BCLX pre-mRNA splicing has antitumor efficacy alone or in combination with radiotherapy in human glioblastoma cells

Dysregulation of anti-apoptotic and pro-apoptotic protein isoforms arising from aberrant splicing is a crucial hallmark of cancers and may contribute to therapeutic resistance. Thus, targeting RNA splicing to redirect isoform expression of apoptosis-related genes could lead to promising anti-cancer phenotypes. Glioblastoma (GBM) is the most common type of malignant brain tumor in adults. In this study, through RT-PCR and Western Blot analysis, we found that BCLX pre-mRNA is aberrantly spliced in GBM cells with a favored splicing of anti-apoptotic Bcl-xL. Modulation of BCLX pre-mRNA splicing using splice-switching oligonucleotides (SSOs) efficiently elevated the pro-apoptotic isoform Bcl-xS at the expense of the anti-apoptotic Bcl-xL. Induction of Bcl-xS by SSOs activated apoptosis and autophagy in GBM cells. In addition, we found that ionizing radiation could also modulate the alternative splicing of BCLX. In contrast to heavy (carbon) ion irradiation, low energy X-ray radiation-induced an increased ratio of Bcl-xL/Bcl-xS. Inhibiting Bcl-xL through splicing regulation can significantly enhance the radiation sensitivity of 2D and 3D GBM cells. These results suggested that manipulation of BCLX pre-mRNA alternative splicing by splice-switching oligonucleotides is a novel approach to inhibit glioblastoma tumorigenesis alone or in combination with radiotherapy.

Acute Large Dose Irradiation Sensitizes Surviving Cells to Subsequent Irradiation; Implications for Stereotactic Body Radiation Therapy.

To determine if the radiation sensitivity of cells that survive acute high-dose radiation exposure used in stereotactic body radiation therapy (SBRT), differs from the sensitivity of non-irradiated cells and cells that survive multiple 2 Gy doses of radiation. Isogenic rodent and two human tumor cell lines were exposed to 14 × 2 Gy of radiation, or a single acute dose of 12 Gy. The most resistant cell line was also exposed to an acute dose of 15 Gy. One week after 12 Gy, and 4 days after 14 × 2 Gy, surviving cells were exposed to 0-8 Gy in 2 Gy doses and cell survival was assessed by colony formation. In addition, the colony forming efficiency of 12 Gy survivors was evaluated for 1 month postirradiation. For cells exposed to 15 Gy, the response of surviving cells to 6 Gy was determined for up to 35 days postirradiation and compared to the 6 Gy surviving fraction of control cells. The radiation sensitivity of cells that survived 12 Gy exposure, and cells that survived 14 fractions of 2 Gy irradiation did not differ from the response of unirradiated control cells. However, the growth rate and colony forming efficiency of 12 Gy survivors was transiently reduced for greater than 2 weeks postirradiation. In contrast to the unchanged sensitivity of 12 Gy surviving cells at day 7 postirradiation, 15 Gy survivors exhibited enhanced sensitivity to radiation for up to 21 days postirradiation and suggests a biological basis for SBRT.

CHAC1 promotes cell ferroptosis and enhances radiation sensitivity in thyroid carcinoma.

ChaC glutathione-specific γ-glutamylcyclotransferase 1 (CHAC1) is involved in intracellular glutathione depletion, ferroptosis, and tumorigenesis. The functional role of CHAC1 expression in thyroid carcinoma has not yet been established. The present study aimed to investigate the impact and mechanisms of CHAC1 on ferroptosis and radiation sensitivity in thyroid carcinoma. CHAC1 expression was examined in tumor tissue specimens and microarrays and thyroid carcinoma cell lines. CHAC1 was silenced or overexpressed by lentivirus transfection in thyroid carcinoma cells. Cell viability and lipid ROS levels were evaluated by Cell Counting Kit-8 and flow cytometry, respectively. The effect of CHAC1 on tumor growth in vivo was also measured. Ferroptosis-related proteins were measured by western blotting. CHAC1 expression was decreased in patients with thyroid carcinoma, and overexpression of CHAC1 suppressed cell viability of BCPAP cells and tumor growth in xenografted nude mice. Exposure to Ferrostatin-1, a ferroptosis inhibitor, significantly attenuated the inhibitory effects of CHAC1 overexpression on cell viability. In CHAC1-overexpressing BCPAP cells, ferroptosis was induced as indicated by increased lipid ROS production and PTGS2 expression. Knocking down of CHAC1 in K1 cells significantly induced cell viability, reduced lipid ROS production and PTGS2 expression, and enhanced GPX4 expression. Such effects were attenuated by RSL3, a ferroptosis inducer. Furthermore, we showed that CHAC1 overexpression enhanced radiation sensitivity in BCPAP cells as indicated by decreased cell viability, while CHAC1 knockdown had reversed effects in K1 cells as indicated by increased cell viability. Taken together, CHAC1 overexpression promoted ferroptosis and enhanced radiation sensitivity in thyroid carcinoma.

Biodegradable hafnium-doped CaCO3 nanoparticles as a dual-modality radiosensitizer for cancer radiotherapy.

Aim: Radiotherapy employs high-energy ionizing radiation to inflict DNA damage on cancer cells, thereby causing their demise. However, this procedure can inadvertently harm healthy tissue. Thus, thisstudy aimed to develop biodegradable radiosensitizers that counteract these adverse effects by enhancing the radiation sensitivity of tumor cells and safeguarding normal cells.Materials & methods: A biodegradable radiosensitizer was engineered by incorporating hafnium ions (Hf) into calcium carbonate (CaCO3) nanoparticles via a chemical precipitation technique, resulting in the formation of Hf:CaCO3 nanoparticles.Results & conclusion: Our findings demonstrate that Hf:CaCO3 nanoparticles exhibit pH-dependent solubility and can augment the efficacy of radiotherapy in treating cancer cells. This research underscores the potential of Hf:CaCO3 nanoparticles as a dual-modality radiosensitizer in radiotherapy.

THU552 Understanding Radiation Therapy Sensitivity In Invasive Lobular Carcinoma Of The Breast

Abstract Disclosure: M.R. Boysen: None. M.J. Sikora: None. M. Shackleford: None. J. Sottnik: None. Invasive lobular carcinoma of the breast (ILC) affects ∼40,000 US women annually and is a top-ten most common cancer affecting women. Despite most ILC having biomarkers of “low risk” disease (e.g. ∼95% are estrogen receptor α /ER-positive), ILC is associated with poorer long-term outcomes and anti estrogen resistance. ILC are also notoriously non-responsive to chemotherapy, critically limiting treatment options for advanced or metastatic ILC. However, ILC are highly responsive to radiation therapy (XRT), which suppresses ILC recurrence and improves survival. We hypothesize that this sensitivity may be due to a dysfunction in DNA damage repair unique to ILC cells. We examined formation and resolution of DNA damage repair foci (namely RAD51, γH2AX and 53BP1 foci) by immunofluorescence with ILC and IDC cell lines treated with ionizing radiation +/- anti-estrogen therapy as surrogates for the initiation and resolution of DNA repair. We also assessed cell growth via 7-day growth assays with ILC and IDC cell lines treated with ionizing radiation. Imaging with immunofluorescence suggested a deficiency in γH2AX foci formation in ILC cells compared to IDC cells following treatment with XRT, despite robust formation of 53BP1 foci. This suggests that a deficiency in performing DNA damage repair in response to XRT is likely present in ILC cells. Additionally, our growth assays demonstrated an inability in ILC cells to recover from ionizing radiation compared to IDC cells. Taken together, the potential dysfunction in γH2AX foci formation in ILC cells suggests that ILC cells may not form the appropriate DNA repair structures to initiate the DNA damage response, suggesting that a form of DNA repair deficiency underlies radiation sensitivity in ILC cells. Presentation: Thursday, June 15, 2023

Pharmacological Targeting of Interferon-Related DNA Damage Resistant Signature (IRDS) and XRCC4-Mediated DNA Repair Pathways ss a Novel Therapeutic Approach to DIPG Radio-Sensitization

Despite significant efforts to improve the outcomes of pediatric diffuse midline gliomas, such as diffuse intrinsic pontine glioma (DIPG), prognosis remains dismal with a 5-year survival of <1%. The standard of care treatment for DIPG is fractionated radiation, but the disease inevitably progresses in 6 months or less. There is a significant unmet need to improve the clinical outcomes for pediatric DIPG patients. Approximately 70-80% of DIPG tumors contain mutations in TP53 tumor suppressor protein. These TP53 mutations are associated with resistance to radiation treatments in DIPG patients. The mechanisms of increased radio-resistance of p53-mutant DIPG are poorly understood. The objective of this study was to identify novel pharmacological agents that would augment radiation sensitivity of p53 mutant DIPG cell lines, and to establish their molecular mechanism of action. SF8628 pediatric DIPG cell line harboring p53 mutation was obtained from MilliporeSigma. CellRad benchtop X-ray irradiator (Precision X-Ray) was used for radiation sensitization experiments. Vi-CELL BLU cell viability analyzer was used for high-throughput screening of small molecule compound libraries with and without radiation treatments. Proteomics Core facility was utilized for mass spec analysis of protein targets of Compound-X. To identify novel drug candidates that would sensitize DIPG to therapeutic radiation, we carried out an unbiased screen of curated libraries of small molecules with diverse scaffolds in p53 mutant DIPG cells. This radio-sensitization screen yielded a single molecule, Compound-X, that was found to have profound growth-inhibitory and radiation-sensitizing effects in DIPG cells. Compound-X was found to induce a robust cell cycle arrest of DIPG cells in G2/M, the most radio-sensitive phase of the cell cycle. Furthermore, Compound-X elicited a massive apoptotic cell death of DIPG cells. An unbiased RNA sequencing approach revealed that Compound-X inhibits expression of the Interferon-related DNA damage Resistant Signature (IRDS), a sub-group of interferon-stimulated genes (ISGs) known to promote radiation and chemotherapy resistance in high-grade gliomas. To identify the target of Compound-X, we carried out affinity purification of Compound-X associated complexes from p53 mutant DIPG cell lysates. Mass spectrometry analysis of Compound-X-purified protein complexes identified XRCC4 as a protein that uniquely associated with Compound-X. RNAi knock-down experiments revealed that XRCC4 is required for cytotoxic effects of Compound-X. Importantly, Compound-X-mediated XRCC4 targeting caused a delay in DNA DSBs repair after radiation treatment. An unbiased screen of small molecule drug candidates identified a novel XRCC4-targeting agent, Compound-X, as potent radiation sensitizer in p53 mutant DIPG cells. This work may lead to clinical trials investigating novel XRCC4-targeting agent in pediatric patients with DIPG.

RUNX1 as a Potential Target for Combined Radioimmunotherapy of Lung Adenocarcinoma

Radioimmunotherapy for non-small cell lung cancer has good clinical application prospects. The role and mechanism of RUNX1 in DNA damage repair were explored for its potential role in lung adenocarcinoma radioimmunotherapy. To study the effect of RUNX1 expression level on the expression of DNA damage repair system related factors and radiation sensitivity of lung adenocarcinoma cells. As an important nuclear transcription factor, RUNX1 was explored whether directly regulating the expression of Nrf2, Rad51, BRCA1, and verifying their respective DNA binding sites in the promoter region through relevant databases. To observe the effect of RUNX1 knockout and overexpression on the expression level of PD-L1 in tumor cells at the cell level; The effect of RUNX1 expression level on the sorting and presentation of PD-L1 cells was investigated by the method of nucleocytoplasmic separation. According to literature reports, CMTM6 and ALIX play a key role in the process of PD-L1 cell sorting and presentation, and explore whether RUNX1 plays a role through this factor. The effect of phosphorylation level of different splicing bodies of RUNX1 (RUNX1a/b/c) on the expression level and DNA damage repair system related factors on tumor radiosensitivity were also explored. According to TCGA database, RUNX1 is highly expressed and phosphorylated in lung adenocarcinoma. Through gene comparison with the database, it was found that RUNX1 binding sites existed in the promoter region of several factors related to this study, including ALIX, Nrf2, BRCA1, RAD51, ATM, H2AX, etc. After being activated by MAPKp38 phosphorylation, RUNX1a can positively regulate Nrf2 signal pathway. The expression of RUNX1 and p-RUNX1 is time-dependent on ionizing radiation. At the same time, it was found that the expression of RUNX1 and p-RUNX1 was dose-dependent on ionizing radiation, and the expression trend of Nrf2 signal pathway related factors was consistent with RUNX1. RUNX1 regulates the expression of PD-L1, BRCA1, ALIX and Nrf2. Bioinformatics analysis and flow cytometry data show that RUNX1 has inhibitory effect on tumor microenvironment of lung adenocarcinoma. RUNX1 regulates DNA damage repair system and has inhibitory effect on tumor immunity. Inhibiting the expression of RUNX1 in lung adenocarcinoma cells can enhance the effect of radioimmunotherapy.