Irradiated Tumor Research Articles

NANO-GBM trial of AGuIX nanoparticles with radiotherapy and temozolomide in the treatment of newly diagnosed Glioblastoma: Phase 1b outcomes and MRI-based biodistribution

BackgroundIn glioblastoma (GBM), tumor progression occurs mainly within the irradiated tumor volume. To address this challenge, a radiosensitization strategy with intravenous gadolinium-based theranostic nanoparticles (AGuIX) is being explored in the NANO-GBM phase1b/2R trial (NCT04881032). Here, we present the results of the phase 1b part, which is the first-in-human use of these nanoparticles with radiotherapy and chemotherapy for the treatment of newly diagnosed GBM. Material and MethodsEligible patients were aged 18 to 75 years with newly diagnosed and histologically confirmed GBM, with incomplete resection (biopsy or partial surgery). The phase 1b part was a dose escalation approach (Time-to-event Continuous Reassessment Method) with three dose levels: 50, 75, and 100 mg/kg. Patients were treated with RT (60 Gy), and concomitant and adjuvant TMZ, and 4 injections of AGuIX (D-3/-7, D1, D8, and D15). Dose-limiting-toxicity (DLT) was defined as any grade 3–4 adverse event (CTCAE v5.0), excluding alopecia, nausea, and rapidly controlled vomiting. Pharmacokinetic (PK), and biodistribution based on MRI were evaluated. ResultsBetween March 2022 and March 2023, eight patients were enrolled: 1 at 50 mg/kg, 1 at 75 mg/kg, and 6 at 100 mg/kg. All patients received the four AGuIX injections. Only one patient experienced a DLT (at 100 mg/kg): a grade 3 lymphopenia (related to TMZ). The RP2D of AGuIX was determined as 100 mg/kg. AGuIX mean AUC increased with dose. Regions of GBM with moderate (36–123 µM), and high (123–291 µM) or very high (>291 µM) AGuIX concentrations accounted in average for 38.7 and 26.8 %, respectively. ConclusionThese results confirm the lack of AGuIX-related toxicity and the widespread dispersion of nanoparticles throughout GBM. This supports progression to the randomized phase 2 part, utilizing an RP2D of AGuIX of 100 mg/kg (4 injections).

Irradiated tumor cell-released microparticles enhance the therapeutic efficacy of PD-1 inhibitors by promoting M1-TAMs polarization in NSCLC brain metastases

Brain metastases (BMs) are the most common sites of metastasis in patients with non-small cell lung cancer (NSCLC). However, BMs are not responsive to immunotherapy because of the blood-brain barrier. This is because intracranial immune cells such as M2 tumor-associated macrophages (TAMs) accumulate, creating an immunosuppressive tumor microenvironment. In this study, we focused on irradiated tumor cell-released microparticles (RT-MPs) that can cross the blood-brain barrier and influence the intracranial immune microenvironment. Using animal models of BMs, we observed that RT-MPs could penetrate the blood-brain barrier and be swallowed by TAMs. Then the microenvironment of TAMs is shifted from the M2 phenotype to the M1 phenotype, thereby modulating the interactions between TAMs and tumor cells. Single-cell sequencing analysis demonstrated that TAMs, after internalizing RT-MPs, active chemokine signaling pathways and secrete more chemokines, such as CCL5, CXCL2, CXCL1, CCL3, CCL4, and CCL22, attracting more CD4+ T cells and CD8+ T cells, improving immune-mediated killing, and enhancing subsequent combination anti-PD-1 therapy. These findings provide a preclinical foundation for exploring alternative treatments for patients with immunoresistant NSCLC BMs.

Boron Neutron Capture Therapy-Derived Extracellular Vesicles via DNA Accumulation Boost Antitumor Dendritic Cell Vaccine Efficacy.

Radiated tumor cell-derived extracellular vesicles (RT-EVs) encapsulate abundant DNA fragments from irradiated tumor cells, in addition to acting as integrators of multiple tumor antigens. Accumulating evidence indicates these DNA fragments from damaged cells are involved in downstream immune responses, but most of them are degraded in cells before incorporation into derived RT-EVs, thus the low abundance of DNA fragments limits immune responses of RT-EVs. Here, this study found that different radiations affected fates of DNA fragments in RT-EVs. Boron neutron capture therapy (BNCT) induced DNA accumulation in RT-EVs (BEVs) by causing more DNA breaks and DNA oxidation resisting nuclease degradation. This is attributed to the high-linear energy transfer (LET) properties of alpha particles from the neutron capture reaction of 10B. When being internalized by dendritic cells (DCs), BEVs activated the DNA sensing pathway, resulting in functional enhancements including antigen presentation, migration capacity, and cytokine secretion. After vaccination of the BEVs-educated DCs (BEV@BMDCs), the effector T cells significantly expanded and infiltrated into tumors, suggesting robust anti-tumor immune activation. BEV@BMDCs not only effectively inhibited the primary tumor growth and metastasis formation but also elicited long-term immune memory. In conclusion, a successful DC vaccine is provided as a promising candidate for tumor vaccine.

Outcome of Reconstruction with Irradiated Tumour Bone in Paediatric Malignant Bone Tumours

Outcome of Reconstruction with Irradiated Tumour Bone in Paediatric Malignant Bone Tumours

11C–methionine PET/CT in meningiomas

Currently, positron emission tomography (PET) is the standard imaging modality in neuro-oncology for gliomas and metastatic lesions. The experience of PET application in meningiomas, the most frequent primary CNS neoplasms, is much less, and the interpretation of the study results has a number of differences. The aim of the study was to evaluate the possibility and peculiarities of PET application in meningiomas based on our own clinical experience and literature review. The study included 70 patients with 77 meningiomas who underwent PET/CT with 11C-methionine. The mean age at the time of examination was 57.4 years (19–86 years). The main evaluation parameter, the tumor-to-brain ratio (TBR) of 11C-methionine (11C–MET) averaged 3.13 (1.00–10.66). Meningiomas were characterized by high 11C–MET TBR, with 89.6% of cases having TBR greater than 1.5. In histologically verified WHO grade 1, 2, and 3 meningiomas, the median TBR was 4.06 [3.04, 4.57], 2.32 [2.12, 3.69], and 4.29 [2.60, 5.10] and did not differ significantly between groups. Meanwhile, in histologically unresectable slow-growing or non-growing incidental meningiomas, TBR of 11C–MET was significantly lower than in WHO grade 1 and 3 meningiomas. There was no significant difference in the accumulation index between irradiated meningiomas with tumor growth control (3.81 [2.97, 3.98]) and recurrence (3.62 [2.60, 4.30]). When irradiated and non-irradiated meningiomas of WHO grade 1, 2 and 3, as well as the combined group of grade 1–3 tumors were compared, no significant differences in 11C–MET TBR were found. The use of PET/CT in meningiomas has a number of important features. Meningiomas are characterized by high TBR of 11C–MET. According to our data PET/CT with 11C–MET does not allow differentiating between meningiomas of different degrees of malignancy – 1, 2 or 3 according to WHO. With effective radiotherapy, meningiomas show partial reduction of TBR or remain stable. Even with prolonged growth control after radiation treatment, meningiomas may still have high TBR of 11C–MET. When comparing growing and stable meningiomas, irradiated and non-irradiated tumors, no significant differences in TBR of 11C–MET are found.

Extended Pharmacokinetics Improve Site-Specific Prodrug Activation Using Radiation.

Radiotherapy is commonly used to treat cancer, and localized energy deposited by radiotherapy has the potential to chemically uncage prodrugs; however, it has been challenging to demonstrate prodrug activation that is both sustained in vivo and truly localized to tumors without affecting off-target tissues. To address this, we developed a series of novel phenyl-azide-caged, radiation-activated chemotherapy drug-conjugates alongside a computational framework for understanding corresponding pharmacokinetic and pharmacodynamic (PK/PD) behaviors. We especially focused on an albumin-bound prodrug of monomethyl auristatin E (MMAE) and found it blocked tumor growth in mice, delivered a 130-fold greater amount of activated drug to irradiated tumor versus unirradiated tissue, was 7.5-fold more efficient than a non albumin-bound prodrug, and showed no appreciable toxicity compared to free or cathepsin-activatable drugs. These data guided computational modeling of drug action, which indicated that extended pharmacokinetics can improve localized and cumulative drug activation, especially for payloads with low vascular permeability and diffusivity and particularly in patients receiving daily treatments of conventional radiotherapy for weeks. This work thus offers a quantitative PK/PD framework and proof-of-principle experimental demonstration of how extending prodrug circulation can improve its localized activity in vivo.

QOL-42. ANALYSIS OF LATE EVENTS AFTER RADIATION THERAPY FOR PRIMARY PEDIATRIC BRAIN TUMORS

Abstract BACKGROUND Late events after radiation therapy for primary brain tumors consist of secondary malignant neoplasms (SMN) and tumor recurrences. The incidence and biology of late events are not very well described. Therefore, we aimed to identify late events in our institutional cohort and describe their biology. METHODS A retrospective chart review of all irradiated pediatric brain tumor patients treated between 2000 and 2015 at our institution was performed to obtain demographics and clinical data of late events. Late events were defined as intracranial intraaxial SMN or tumor recurrence occurring later than 3 years after radiation therapy. A whole-genome methylation array was employed to identify the methylation class of the late event. RESULTS In the observed period, 267 patients received some form of cranial radiotherapy for primary brain tumor; high-grade glioma (HGG, n=66), medulloblastoma (n=74), ependymoma (n=50), germ-cell tumors (GCT, n=22), low-grade glioma (LGG, n=24), and other diagnoses (n=31). Out of the 174 patients who were alive and without an event after 3 years from the radiation therapy, 30 developed late events (16.8%), and 27 of them were histologically verified. Verified late events consisted of 8 SMNs (29.6%) and 19 primary tumor recurrences. SMNs were mainly radiation-induced gliomas (RIG, n=7) and one atypical teratoid/rhabdoid tumor (ATRT) after craniopharyngioma. All RIG tumors clustered with the “pediatricHGG_RTK1” methylation class. Tumor recurrences consisted of medulloblastomas (Group 4 and Wnt), ependymomas (PFA and ST_ZFTA), GCTs, gliomas (one NF1-associated HGG, one H3-altered thalamic glioma, one diffuse astrocytoma with BRAF-V600E mutation), and craniopharyngiomas. The overall survival rate 5 years after a late event was 39.7%, with a worse survival rate for SMN patients (14.3%) compared to those with recurrences (44.9%) (p=0.05). CONCLUSIONS Late events affected 16.8% of long-term survivors. Strikingly, SMNs represented almost 30% of late events and were associated with a very poor prognosis.

CDKN2A deletion and radiation sensitivity in IDH-mutant astrocytomas.

2041 Background: IDH-mutant astrocytomas represent the most prevalent primary tumors in younger adults (<45yo). A substantial minority of these tumors exhibit the deletion of CDKN2A (Cyclin-Dependent Kinase Inhibitor Gene 2A). Homozygous deletion of this gene– which encodes the tumor suppressor protein p16 – is associated with a malignant phenotype and poorer prognosis in IDH-mutant astrocytoma. CDKN2A deletions are primarily observed in tumors that have received radiation therapy (RT), suggesting a potential mechanistic relationship between RT and deletion. This observation gives rise to two alternative hypotheses: either RT is causing DNA damage in irradiated cells, leading to the induction of subclonal CDKN2A deletion, or a subset of cells already possesses the CDKN2A deletion and is resistant to RT, resulting in the treatment selecting for the subsequent emergence of these cells. Here, we sought to ascertain the influence of CDKN2A deletion on IDH-mutant astrocytoma cellular response to RT. Methods: The antitumor effect of RT was evaluated in vitro using patient-derived IDH-mutant astrocytoma cells, MGG152. A homozygous CDKN2A deletion was engineered in this parental line, creating a paired line to permit an isogenic comparison between CDKN2A intact versus CDKN2A deleted tumor cells. A photon irradiator was used to deliver a range of clinically-relevant RT doses spanning from 0 to 20 gray (Gy). Differences in cell viability after a predetermined incubation period were examined and relevant statistical comparisons performed. Results: Dose-response curves in response to radiation therapy, comparing CDKN2A intact and deleted cell lines, were generated (Table). Both CDKN2A intact and deleted cell lines exhibited significant reductions in viability following radiation exposure at and above 2Gy (p < 0.001). CDKN2A-deleted cells displayed a small but significantly greater sensitivity than CDKN2A-intact at 1, 2, and 5Gy (Table). Conclusions: Our findings offer evidence indicating that p16 loss does not bestow radioresistance in IDH-mutant astrocytomas. These findings align with a hypothesis that radiotherapy (RT) might promote DNA damage, and consequently, subclonal CDKN2A deletion, in irradiated IDH-mutant tumors. [Table: see text]

Clinical utility of AlphaMissense in predicting pathogenicity of DNA damage repair genes in cancer.

10581 Background: Deficiencies in DNA damage repair (DDR) impact cancer predisposition and various treatment responses.Functional implications of missense variants in DDR genes remain elusive.AlphaMissense, a new AI-based method, accurately predicts the pathogenicity of missense variants, but its clinical utility requires validation. We evaluated the accuracy of AlphaMissense predictions by analyzing known mutational signatures, genomic characteristics, and therapeutic vulnerabilities of DDR-deficient tumors. Methods: We analyzed data from TCGA (n=8,178) and MSK-IMPACT targeted panel sequencing (n=56,695) to evaluate the performance of AlphaMissense in predicting clinically actionable DDR genes, including core homologous recombination (HR) genes ( BRCA1/2, PALB2, RAD51C), POLE, and ATM. Missense mutations were classified as known pathogenic by OncoKB or previous literature, newly pathogenic identified with AlphaMisense, or benign. Mutational signatures were computed using SigMA algorithm, classifying each signature as positive at >20%. The irradiated tumor control was evaluated in patients with ATM missense mutations who received radiotherapy. Results: Among 6,743 unique DDR missense mutations from MSK-IMPACT, 372 (3.5%) were known pathogenic, and 1,182 (17.5%) were new pathogenic mutations. In 205 tumors with bi-allelic core-HR missense mutations in breast, ovarian, pancreatic, and prostate cancers, 20 (9.8%) had new pathogenic mutations. Tumors with new pathogenic mutations more frequently exhibited HR-deficient signatures (65%) than wild-type (31.8%, p < .001), similar to tumors with known pathogenic mutations (62.8%, p = 1.0). In TCGA, HR-deficient signatures tended to be more frequent in tumors with new pathogenic missense mutations than in wild-type tumors (41.7% vs. 21.0%, p = .16). Of 1,010 tumors with POLE missense mutations from MSK-IMPACT, 300 (30%) had new pathogenic mutations. The presence of POLE signatures in tumors with new pathogenic mutations (11.9%) was not significantly different from those with benign mutations (4.3%, p = .19) and less frequent than in tumors with known pathogenic mutations (91.0%, p < .001). In MSK-IMPACT, tumors with new pathogenic ATM missense mutations were less likely to have TP53 mutations than benign missense mutations (32.7% vs. 56.6%, p < .001), consistent with bona-fide pathogenicity. Further, patients with new pathogenic ATM missense mutations showed increased radiosensitivity, characteristic of ATM deficiency, and improved irradiated tumor control compared to those with benign missense mutations (Hazard ratio 0.58, 95% Cl 0.35-0.95, p = .03). Conclusions: AlphaMissense can identify previously unknown pathogenic DDR missense mutations, but its accuracy is gene-dependent. AlphaMissense pathogenicity predictions for DDR genes can utilized to help classify mutations, but may not be sufficient on their own.

Radiotherapy enhances efficacy of PD-1 inhibitors in advanced hepatocellular carcinoma: A propensity-matched real-world study.

To address the need for immunotherapy in patients with advanced primary hepatocellular carcinoma (HCC), combination with radiotherapy (RT) has emerged as a promising strategy. In preclinical studies, irradiated tumors released tumor antigens to synergistically increase the antitumor effect of immunotherapy. Hence, we investigated whether RT enhances the efficacy of anti-programmed death receptor-1 (PD-1) inhibitors in advanced HCC in real-world practice. Between August 2018 and June 2021, 172 patients with advanced primary HCC were enrolled in the tertiary center (Zhongshan Hospital of Fudan University); 95 were treated with a combination of RT and the inhibitor of PD-1 (RT-PD1 cohort), and 77 were administered anti-PD-1 therapy (PD1 cohort). The first cycle of PD-1 inhibitors was administered within 60 days or concurrently with RT. Propensity score matching for bias reduction was used to evaluate the clinical outcomes. Among 71 propensity-matched pairs, median progression-free survival was 5.7 months in the RT-PD1 cohort vs. 2.9 months in the PD1 cohort ( P <0.001). Median overall survival was 20.9 months in the RT-PD1 cohort vs. 11.2 months in the PD1 cohort ( P =0.018). Compared with patients in the PD1 cohort, patients in the RT-PD1 cohort had significantly higher objective response rates (40.8%, 29/71 vs. 19.7%, 14/71, P =0.006) and disease control rates (62.0%, 44/71 vs. 31.0%, 22/71, P <0.001). The incidences of toxic effects were not significantly different between the two cohorts. RT plus anti-PD-1 therapy is well tolerated. RT enhances the efficacy of anti-PD-1 therapy in patients with advanced primary HCC by improving survival outcomes without increased toxic effects.

Fluorescent tracing unveils the impact of radiation therapy on the migration and plasticity of Tregs in the tumor microenvironment

Abstract Radiation therapy (RT) is a pivotal component of cancer treatment, yet its impact on the immune system is not fully understood. RT induces DNA damage in cancer cells, promoting cancer cell death and RT-induced immune responses with the potential to clear surviving cancer cells. However, RT can also recruit suppressive T regulatory cells (Tregs), that hinder adaptive immunity. Following RT-mediated death of tumor Tregs, we hypothesize that immature Tregs are recruited to the post-RT tumor and converted into suppressive phenotypes. Using the Kaede mouse model, we tracked photoconverted cells from either the tumor or TdLN after RT. In photoconverted tumors, Tregs in the TdLN constituted a higher proportion of photoconverted cells compared to non-Treg CD4 or CD8 T cells. When RT was applied to tumors, photoconverted Tregs and non-Treg CD4 T cells decreased in the TdLN. When photoconverting the TdLN we observed selective migration of Tregs to the tumor rather than to NdLN. Analyzing these newly arrived photoconverted Tregs in the tumor post-RT revealed increased expression of CD69, KLRG1, and Ly6C compared to non-photoconverted Tregs, indicating limited suppressive capacity. Ongoing studies are examining the impact of the irradiated tumor environment on newly-entered Treg plasticity. These findings unveil intricate dynamics between RT, Tregs, and the use of site-specific photoconversion for tracking immune cell movement over time.

Modulation of epithelial-mesenchymal transition by gemcitabine: Targeting ionizing radiation-induced cellular senescence in lung cancer cell

Ionizing radiation, a standard therapeutic approach for lung cancer, often leads to cellular senescence and the induction of epithelial-mesenchymal transition (EMT), posing significant challenges in treatment efficacy and cancer progression. Overcoming these obstacles is crucial for enhancing therapeutic outcomes in lung cancer management. This study investigates the effects of ionizing radiation and gemcitabine on lung cancer cells, with a focus on induced senescence, EMT, and apoptosis. Human-derived A549, PC-9, and mouse-derived Lewis lung carcinoma cells exposed to 10 Gy X-ray irradiation exhibited senescence, as indicated by morphological changes, β-galactosidase staining, and cell cycle arrest through the p53-p21 pathway. Ionizing radiation also promoted EMT via TGFβ/SMAD signaling, evidenced by increased TGFβ1 levels, altered EMT marker expressions, and enhanced cell migration. Gemcitabine, a first-line lung cancer treatment, was shown to enhance apoptosis in senescent cells caused by radiation. It inhibited cell proliferation, induced mitochondrial damage, and triggered caspase-mediated apoptosis, thus mitigating EMT in vitro. Furthermore, in vivo studies using a lung cancer mouse model revealed that gemcitabine, combined with radiation, significantly reduced tumor volume and weight, extended survival, and suppressed malignancy indices in irradiated tumors. Collectively, these findings demonstrate that gemcitabine enhances the therapeutic efficacy against radiation-resistant lung cancer cells, both by inducing apoptosis in senescent cells and inhibiting EMT, offering potential improvements in lung cancer treatment strategies.

Irradiated tumour cell-derived microparticles upregulate MHC-I expression in cancer cells via DNA double-strand break repair pathway

Radiotherapy (RT) is used for over 50 % of cancer patients and can promote adaptive immunity against tumour antigens. However, the underlying mechanisms remain unclear. Here, we discovered that RT induces the release of irradiated tumour cell-derived microparticles (RT-MPs), which significantly upregulate MHC-I expression on the membranes of non-irradiated cells, enhancing the recognition and killing of these cells by T cells. Mechanistically, RT-MPs induce DNA double-strand breaks (DSB) in tumour cells, activating the ATM/ATR/CHK1-mediated DNA repair signalling pathway, and upregulating MHC-I expression. Inhibition of ATM/ATR/CHK1 reversed RT-MP-induced upregulation of MHC-I. Furthermore, phosphorylation of STAT1/3 following the activation of ATM/ATR/CHK1 is indispensable for the DSB-dependent upregulation of MHC-I. Therefore, our findings reveal the role of RT-MP-induced DSBs and the subsequent DNA repair signalling pathway in MHC-I expression and provide mechanistic insights into the regulation of MHC-I expression after DSBs.

Intraoperative assessment of cochlear nerve functionality in various vestibular schwannoma scenarios: Lessons learned

The use of cochlear implants (CIs) is on the rise for patients with vestibular schwannoma (VS). Besides CI following tumor resection, new scenarios such as implantation in observed and/or irradiated tumors are becoming increasingly common. A significant emerging trend is the need of intraoperative evaluation of the functionality of the cochlear nerve in order to decide if a CI would be placed. The purpose of this paper is to explore the experience of a tertiary center with the application of the Auditory Nerve Test System (ANTS) in various scenarios regarding VS patients. The results are compared to that of the studies that have previously used the ANTS in this condition.Patients with unilateral or bilateral VS (NF2) who were evaluated with the ANTS prior to considering CI in a tertiary center between 2021 and 2023 were analyzed. The presence of a robust wave V was chosen to define a positive electrical auditory brainstem response (EABR). Two patients underwent promontory stimulation (PromStim) EABR previous to ANTS evaluation.Seven patients, 2 NF-2 and 5 with sporadic VS were included. The initial scenario was simultaneous translabyrinthine (TL) tumor resection and CI in 3 cases while a CI placement without tumor resection was planned in 4 cases. The ANTS was positive in 4 cases, negative in 2 cases, and uncertain in one case. Two patients underwent simultaneous TL and CI, 1 patient simultaneous TL and auditory brainstem implant, 3 patients posterior tympanotomy with CI, and 1 patient had no implant placement. In the 5 patients undergoing CI, sound detection was present. There was a good correlation between the PromStim and ANTS EABR. The literature research yielded 35 patients with complete information about EABR response. There was one false negative and one false positive case; that is, the 28 implanted cases with a present wave V following tumor resection had some degree of auditory perception in all but one case.The ANTS is a useful intraoperative tool to asses CI candidacy in VS patients undergoing observation, irradiation or surgery. A positive strongly predicts at least sound detection with the CI.

Abstract 693: The effect of butyrophilin 1A1 blockade in combination with radiation treatment in tumor models

Abstract Expression of radiation-induced immune escape molecules, including PD-L1, contributes to the efficacy of cancer immunotherapy. We used an unbiased in vivo gene knockdown screen in naïve T-cells and introduced them into irradiated host tumors to identify novel immunosuppressive genes activated during radiation. From the screen, we found that butyrophilin 1A1 (BTN1A1) knockdown causes T-cell expansion in irradiated tumors. This points to the potential immune checkpoint role of BTN1A1. We validated that BTN1A1 expression is inducible in activated T-cells and that blocking BTN1A1 contributes to T-cell activation. We tested an anti-mouse BTN1A1 antibody (STC109) in mouse colon tumor models (CT26 tumors), we observed partial anti-tumor efficacy using single agent STC109, which was enhanced by the combination of STC109 with radiation. We also got similar result in in mouse lung tumor models (LLC tumors) using anti-mouse BTN1A1 antibody, and the combination treatment showed an improved suppression of tumor growth and lung metastasis compared to single agent. Moreover, our data shown that knockout of BTN1A1 in 4T1 tumor models shown dramatic defect of tumor growth, and the BTN1A1 ko tumors are more sensitive to radiotherapy. These findings indicate the role of BTN1A1 in tumor immune response from radiation stress, and that anti-BTN1A1 has strong potential to enhance efficacy of radiotherapy for cancer treatment. Citation Format: Nan Li, Chen Braun, Young-Seung Kim, Andrew Park, Stephen S Yoo, Steven H. Lin. The effect of butyrophilin 1A1 blockade in combination with radiation treatment in tumor models [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 693.

Abstract 4987: TREM2 is a radiation-induced target for immunomodulation of tumor-associated macrophages in the prostate cancer tumor microenvironment

Abstract Background: The prostate cancer (PCa) tumor microenvironment (TME) is characterized by a predominance of myeloid cells that may have a key role in immunosuppression and disease progression. Stereotactic Body Radiation Therapy (SBRT) is utilized for treatment of localized and metastatic PCa and promotes inflammatory remodeling of the TME. We analyzed human PCa specimens at acute post-SBRT timepoints to identify radiation-induced targets in the PCa TME and used in vitro and in vivo models to test and validate our findings. Methods: We performed 10X single-cell RNA sequencing (scRNA-seq) on prostatectomy specimens from men with high-risk localized PCa; 12,988 cells from 4 patients that underwent pre-operative SBRT and 47,314 cells from 6 patients that underwent prostatectomy alone. THP-1 monocytes polarized into macrophage (Mɸ) states [M0, M1, M2 and tumor-associated macrophages (TAM), were used to characterize TREM2 expression and immune responses to radiation or conditioned media (CM) derived from irradiated PC3 cells. In vivo studies with C57BL/6 mice inoculated with MC38 flank tumors or PTEN-/- SPOPmut CHD1del mouse prostate organoid line were used to analyze intratumoral myeloid populations in response to SBRT (37.5Gy in 5 fractions). Results: scRNA-seq analysis (Cell Ranger 7.1.0 pipelines; Seurat v5 R package) revealed enrichment of a cluster of myeloid cells defined by a damage-associated Mɸ gene signature (TREM2, APOE, SPP1, LGALS3, CD9) in response to SBRT compared with non-irradiated specimens (35.6% vs 5.7%). TREM2 expression was significantly upregulated in THP-1 cells polarized in M2 (p&amp;lt;0.001) and TAM (p&amp;lt;0.001) conditions, compared to M1 conditions. Irradiation (20Gy x1) of THP-1 cells significantly increased TREM2 expression in M0 (p&amp;lt;0.01), M1 (p&amp;lt;0.001), and TAM (p&amp;lt;0.01) conditions. Proliferation of PC3 cells exposed to CM from irradiated TAMs was significantly increased (p&amp;lt;0.0001) compared to CM from non-irradiated TAM. Alternatively, CM derived from irradiated PC3 cells significantly increased (p&amp;lt;0.05) TREM2 expression in M0-polarized Mɸ. In vivo studies, in MC38 and organoid models, noted a significant reduction (p&amp;lt;0.0001) in tumor volume at day 7 post-SBRT. Multi-parametric flow cytometry demonstrated robust myeloid infiltration in response to SBRT dominated by CD11b+F4/80+ TAMs in irradiated tumors. Among irradiated tumors, TREM2 expression was markedly elevated in TAMs (organoid and MC38, p&amp;lt;0.0001). Conclusion: Preliminary data in human irradiated PCa and validation studies in preclinical models suggest TREM2 expression on myeloid cells is a radiation-induced target. Further studies are underway to understand the functional and immunological implications of SBRT-induced TREM2 expression on TAMs and whether this can be therapeutically targeted to enhance anti-tumor immunity in PCa. Citation Format: Janny A. Villa-Pulgarin, Un In Chan, Francesca Khani, Fabio Socciarelli, Jiansheng Wu, Ryan Carelli, Jeffrey Kraynak, Silvia C. Formenti, Luigi Marchionni, Massimo Loda, Himanshu Nagar, Ariel E. Marciscano, Christopher E. Barbieri. TREM2 is a radiation-induced target for immunomodulation of tumor-associated macrophages in the prostate cancer tumor microenvironment [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 4987.

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.

Abstract 1122: Inhibition of HDAC6 enhanced radiation therapy induced antitumor response in melanoma

Abstract Patients with advanced melanoma are often treated with radiation therapy (RT) in combination with immunotherapies. Immunogenic tumor cell death induced by radiation is known to activate innate and adaptive immunity. Macrophage activity in the irradiated tumor microenvironment (TME) has been implicated to play a critical role in post-RT innate immune responses. However, tumor-associated macrophages (TAMs) due to their phenotypic plasticity convert from initial antitumor M1 phenotype to protumor M2 macrophages resulting in relapse and metastasis of any surviving tumor cells. Therefore, strategies regulating tumor macrophages post-radiation can enhance the therapeutic effectiveness of radiation therapy. Here, we report targeting HDAC6 function with a novel selective inhibitor (SP-2-225) as a potential therapeutic candidate for combination with RT. When administered intraperitoneally at a dose of 25mg/kg, SP-2-225 resulted in significant tumor suppression in the immunocompetent SM1 murine melanoma model. Phenotyping of tumor immune infiltrate indicated a profound decrease in M2 macrophages resulting in an M1/M2 macrophage ratio and an increase in CD8 effector memory T-cells. Further, in-vitro co-culture studies using trans-well assays indicated that irradiated tumor cells attract M2 macrophages, and treatment with SP-2-225 abrogated the M2 macrophage migration but did not alter M1 macrophage migration. In addition, 24 hours post-RT, intratumor administration of SP-2-225 treated M1 macrophages as adoptive cell therapy resulted in diminished tumor growth. The combination of conditioned M1 macrophages with an irradiated tumor microenvironment resulted in an increased M1/M2 ratio and infiltration of effector memory and central memory CD8 T-cells underscoring the influence of transplanted macrophages on the local antitumor immunity. Therefore, our findings demonstrate the ability of HDAC6 inhibitors to regulate macrophage function and phenotype as a cell therapy for use in combination with radiation therapy. Citation Format: Xintang Li, Manasa Suresh, Hawa Coulibaly, David Quiceno-Torres, Nithya Gajendran, Karen Tan, Satish Noonepalle, Scott Grindrod, Anatoly Dritschilo, Alejandro Villagra. Inhibition of HDAC6 enhanced radiation therapy induced antitumor response in melanoma [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 1122.

Abstract 1127: Single cell network-based analyses reveal dose-dependent increase in myeloid suppressive cell sub-populations in response to radiation therapy

Abstract Background: More than half of all cancer patients undergo radiation therapy (RT) with curative or palliative intent. With the widespread use of immunotherapy to treat cancer, immune effects of radiation are an important consideration in design of sequential and combination therapies. While radiation has been found to deplete lymphocytes, less is known about its effects on the myeloid compartment, which includes both immune activating and suppressive populations. We hypothesized that a network-based analysis of single cell proteogenomic data generated from tumor-infiltrating immune cells can identify druggable proteins in pathways driving unwanted immunosuppressive changes with radiation, particularly among myeloid cells. Methods: Proteogenomic (CITE-Seq) analysis was conducted on CD45+ immune cells from unirradiated and irradiated orthotopic 4T1 murine mammary tumors three- and ten-days after tumor irradiation (8 Gy x 1 or 8 Gy x 3). Based on expression of select surface proteins, analysis of the CITE-Seq data resulted in eight distinct immune clusters, including three myeloid clusters — monocytes, macrophages, and granulocytes. Using VIPER (virtual inference of protein activity by enriched regulon), an algorithm that infers protein activities from weighted expression on each protein’s downstream targets, we identified distinct functional subpopulations within these eight clusters. Further profiling subclusters enriched by RT using the OncoTarget algorithm, we identified druggable proteins with significant inferred activity as potential targets of therapeutic interest. Results: As expected, lymphocytes were persistently depleted after RT on both radiotherapy schedules. However, three distinct subclusters of myeloid cells with immune-suppressive phenotype became enriched following tumor irradiation, with greater enrichment at the lower radiation dose of 8 Gy x 1: TAM2, PMN1, and PMN4. Surface protein expression enabled us to define the immunophenotype and isolate these three cell clusters from murine 4T1 tumors as well as human renal cell carcinoma tumors for further functional analyses. OncoTarget identified a number of druggable targets, including PARP1 for the PMN1 subcluster. Conclusion: Suppressive myeloid subpopulations induced by radiation were identified among the immune cells. Combining radiation therapy with inhibitors of these cell populations may provide therapeutic benefit over radiation therapy alone or in combination with checkpoint inhibitor immunotherapies. Future work will experimentally determine if inhibition of druggable protein targets in these myeloid subpopulations improves the overall efficacy of RT. Citation Format: Aparna Krishnan, Shruti Bansal, Samanta Sarti, Michael D. Kissner, Charles Karan, Andrea Califano, Aleksandar Z. Obradovic, Catherine S. Spina. Single cell network-based analyses reveal dose-dependent increase in myeloid suppressive cell sub-populations in response to radiation therapy [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 1127.

Abstract 1360: TIGIT blockade combined with local radiotherapy and PD-1 blockade in a murine triple-negative breast cancer model

Abstract Background: Immune checkpoint blockades (ICB) improve outcomes of patients with some solid tumors such has melanoma and lung cancer, however the efficacy of ICB alone showed limited efficacy in many other tumors such as breast cancer. Radiation therapy is a promising combination partner of ICB as a strong immune stimulator so called in situ tumor vaccine, however it also can increase immune suppressive repertoires. TIGIT (T cell Immunoglobulin and ITIM domain) is an inhibitory receptor expressed on activated T cells and NK cells. We evaluated the effects of TIGIT blockade in addition to local RT and PD-1 blockade as a strategy to overcome therapeutic resistance of ICI in a murine breast cancer model. Materials and Methods: 4T1-Luc tumors were treated with various strategies including control, RT, anti-PD-1, anti-TIGIT, RT+anti-PD-1, RT+anti-TIGIT, anti-PD-1+anti-TIGIT, and RT+anti-PD-1+anti-TIGIT. A total of 24 Gy in 3 fractions at 1 week was delivered to the tumor at hindlimb (primary tumor) while the tumor at flank (secondary tumor) was left unirradiated. 10 mg/kg of anti-PD-1 blocking antibodies and 10 mg/kg of anti-TIGIT blocking antibodies were intraperitoneally injected for 6 times for 2 weeks. Flow cytometry, IHC staining, and ELISA were performed to assess the immunologic status after treatments. Results: The triple combination therapy (TCT) group showed the most superior growth delay of primary and secondary tumor growth among treatments. The number of metastatic lung nodule was significantly reduced by TCT as well. Plasma levels of interferon-β and interferon-γ were the highest after TCT. Moreover, TCT significantly increased the proportion of splenic CD8+ dendritic cells among myeloid cells, and effector-memory (CD44+CD62L−) cells among splenic Foxp3− non-regulatory CD4+ and CD8+ T cells. Furthermore, expression of CD226, which is an activating counter-receptor of TIGIT, on splenic CD8+ T cells was elevated by TIGIT blockade, possibly suggesting the activation of systemic immune response by addition of TIGIT blockade to local RT and PD-1 blockade. Meanwhile, TCT decreased splenic Foxp3+ regulatory T cells, as well as the expression of CD39 on splenic Foxp3+ regulatory T cells. The increase of CD8+ T cell infiltration in primary and secondary tumors was most prominent in TCT group. Conclusion: TIGIT blockade elicits systemic immune responses in a murine triple-negative breast cancer model. when combined with local RT and PD-1 blockade, which were correlated with significant delay in the growth of both irradiated and unirradiated tumors. These results suggest that TIGIT blockade could be a viable approach to increase the efficacy of RT and immune checkpoint inhibitors in breast cancer which is a relatively immunologically cold tumor. (Work supported by a grant from National Research Foundation of Korea #2023R1A2C3003782 to In Ah Kim). Citation Format: Seongmin Kim, Seung Hyuck Jeon, In Ah Kim. TIGIT blockade combined with local radiotherapy and PD-1 blockade in a murine triple-negative breast cancer model [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 1360.