Oncolytic Adenovirus Research Articles

EXTH-55. ANTI-TUMOR ACTIVITY OF A NEW ONCOLYTIC ADENOVIRUS DELTA-24-RGDOX-IL15 CO-EXPRESSING OX40L AND IL-15

Abstract Accumulating evidence show that the interaction between oncolytic viruses (OVs) and host immune system plays an essential role in cancer virotherapy. Compared to lytic potency of OVs, enhancement of OV-mediated anti-tumor immunity has become a more attractive strategy to improve OV efficacy. To this end, we have reported that the third-generation oncolytic adenovirus (OA), Delta-24-RGDOX, which expresses the immune co-stimulator OX40 ligand (OX40L), is more potent to elicit anti-tumor immunity than the second-generation OA Delta-24-RGD. Since IL-15 activates T and NK cells and promotes persistence of CD8+ memory T cells, we hypothesize that co-expression of OX40L and IL-15 by OAs will further potentiate their efficacy. For this purpose, we constructed the next generation OA Delta-24-RGDOX-IL15. In cultured human and murine tumor cell lines, this new virus effectively expressed the two molecules and displayed comparable potency in viral replication and oncolysis as OAs expressing either of the two (Delta-24-RGDOX, Delta-24-RGD-IL15). Then, we tested the anti-tumor activity of Delta-24-RGDOX-IL15 (two doses, intratumorally, one week interval) in two syngeneic tumor models in C57BL/6 mice: 1) intracranial (i.c.) gliomas from GL261-5 cells; 2) subcutaneous (s.c.)/i.c. melanomas from B16 cells (virus injected into s.c. tumors only). We found Delta-24-RGDOX-IL15 was more efficacious than the other two OAs to inhibit tumor growth of both treated tumor and the untreated i.c. tumors in the second model, leading to long-term survivors (p < 0.05). Different from adoptive cell therapies with cells engineered to express IL-15, we haven’t observed any obvious toxicity with this new virus when it was injected intratumorally into either the i.c. or s.c. tumors. Further studies are in progress to analyze the modifications of the tumor microenvironment induced by the addition of IL-15 to Delta-24-RGDOX. We expect this virus to be a good candidate to be combined with CAR T cell therapies.

IMMU-35. TARGETING THE AHR IMMUNOMETABOLIC HUB DURING VIROIMMUNOTHERAPY OF GLIOMAS

Abstract Glioblastoma (GBM) poses a significant therapeutic challenge in oncology. Recent clinical trials have shown the feasibility of virotherapy to treat patients with GBM. Our laboratory developed an oncolytic adenovirus termed Delta-24-RGD that has been tested in clinical trials for recurrent GBM patients with encouraging results (NCT00805376, NCT02798406). These clinical studies, together with preclinical data, showed that the efficacy of Delta-24-RGD was due to direct tumor cell oncolysis and indirect activation of anti-tumor immune response. To further leverage this immune component, our group generated Delta-24-RGDOX, an armed version of Delta-24-RGD expressing the T-cell activator OX40-L, which exhibits a superior anti-cancer effect. In this project, we aim to further boost the effectiveness of Delta-24-RGDOX by targeting factors that maintain the immunosuppressive characteristic of gliomas. Specifically, we identified the environmental sensor and transcription factor Aryl Hydrocarbon Receptor (AhR) as one of the immunosuppressive factors. We show that AhR is overexpressed in GBM surgical specimens compared to healthy brain tissue, and high AhR expression correlates with poorer survival in glioma patients. Immunofluorescence staining of glioma cells treated with Delta-24-RGDOX demonstrated that AhR translocates to the nucleus, and qPCR showed that translocation resulted in the enhanced transcription of AhR-responsive elements. Additionally, bulk RNA-seq reveals that in vivo glioma models treated with Delta-24-RGDOX exhibit activation of the AhR pathway network. This unexpected and paradoxical activation may be responsible for immune suppression mechanisms, which might hinder the effect of Delta-24-RGDOX. Based on these data, we combined two innovative strategies, the oncolytic virus Delta-24-RGDOX and AhR inhibitors. Survival analysis in immunocompetent models of gliomas treated with this combined therapy showed the greatest therapeutic benefit compared to monotherapy controls. These findings highlight the critical role of AhR activation triggered by Delta-24-RGDOX and position AhR as a potential therapeutic target for enhancing the efficacy of oncolytic adenovirus therapy in GBM.

EXTH-21. WINNING THE TUG OF WAR BETWEEN VIRUS AND TUMOR IMMUNODOMINANCE IN GLIOMAS TREATED WITH ONCOLYTIC ADENOVIRUSES USING TOLEROGENIC STRATEGIES

Abstract Phase 1 and 2 clinical trials of our oncolytic adenovirus Delta-24-RGD for patients with recurrent malignant gliomas have demonstrated its safety and efficacy, and showed that 20% of the patients experienced long-term tumor remissions often associated with inflammatory responses and tumor infiltration of lymphocytes. Based on our preliminary data, we expected that the most frequent tumor-infiltrating CD8+ T cell clones will target adenoviral hexon, with a single virus-specific clone representing up to 5% of the total population. Competition between T cells for resources may limit the expansion of subdominant clones recognizing tumor antigens. We hypothesized that mitigating virus-specific immunity allows the expansion of tumor-specific T cells and results in better therapeutic efficacy. In mice, intravenously injected nanoparticles encapsulating adenoviral antigens preferentially accumulated in the liver (P<0.0001), where self-reactive immune cells are deleted through peripheral tolerance. RNA-sequencing of antigen-specific T cells isolated after nanoparticle injection revealed enriched expression of gene sets involved in immune tolerance through clonal deletion and T cell anergy, including increased expression of immune checkpoint molecules (P<0.001). In glioma-bearing mice treated with virotherapy in combination with nanoparticle administration, tumor infiltrating lymphocytes exhibited decreased IFNγ secretion against viral antigens and increased secretion against tumor antigens, suggesting a redirection of the immunity from anti-viral to anti-tumoral (P<0.05). Importantly, virotherapy with nanoparticles increased the overall survival of tumor-bearing mice compared to virus treatment alone (P<0.001). To further characterize the roles of virus- and tumor-specific immune cells during virotherapy we are analyzing the T cell receptor repertoire of surgical specimens from nine glioma patients treated with Delta-24-RGD in a phase 1 clinical trial. In summary, our data provide the basis for a future clinical trial using tolerogenic strategies to redirect immunodominance of the viral to the glioma antigens, and represent a novel strategy to enhance anti-tumor immunity during virotherapy of brain tumors.

EXTH-66. ONCOLYTIC ADENOVIRAL INFECTION SYNERGIZES WITH IMMUNE CHECKPOINT INHIBITION TO MEDIATE INTRACRANIAL TUMOR CONTROL IN DISPARATE MODELS OF MELANOMA BRAIN METASTASES

Abstract Amongst all solid cancers, melanoma brain metastases (MBM) have the highest likelihood of metastasizing to the brain. The emergence of immune checkpoint inhibitors (ICI) for metastatic melanoma have demonstrated increasingly promising results; however, intracranial progression remains a challenging obstacle. Oncolytic viral (OV) therapy leverages tumor cell replication machinery to selectively replicate and kill tumor cells and promote anti-tumor immunity. We propose this OV strategy can be applied to MBM through direct tumor infection that simultaneously sustains a distant antitumor immune response. To counteract immunosuppressive features of the tumor microenvironment (TME), a third-generation oncolytic adenovirus (Delta-24-RGDOX) has been developed which expresses the immune stimulatory OX40 ligand (OX40L). We quantified the cytotoxic capacity of Delta-24-RGDOX and its ability to achieve immunogenic cell death (ICD) in vitro along with cerebral organoid co-culture models. Additionally, we used a series of syngeneic murine melanoma models to explore local and systemic antitumor immunity following Delta-24-RGDOX infection. Delta-24-RGDOX inoculation achieved viral infection, OX40L cell surface expression, tumor cell cytotoxicity, and ICD in vitro. Viral oncolysis was recapitulated in a cerebral organoid melanoma co-culture model with concomitant alterations in microglia activation and detection of viral transcripts within microglia using single cell RNA sequencing, suggesting a viral-clearing role of microglia within the TME. Local tumor clearance was achieved in orthotopic intracranial models following direct intracranial viral inoculation alone, and in combination with ICI. Lastly, we demonstrated improvement in overall survival in a synchronous subcutaneous/intracranial B16F10 model where the subcutaneous tumor was treated with Delta-24-RGDOX in combination with ICI. In summary, Delta-24-RGDOX achieves viral infection, oncolysis, and ICD following infection of melanoma cell lines. These findings translated in multiple in vivo models including immune cell activation and systemic antitumor immunity against uninfected MBM. Future studies are needed to explore the role of immune cell trafficking, myeloid cell modulation, T cell priming, and clonal expansion withing locally infected and the distant melanoma TME.

IMMU-48. CRACKING THE ROLE OF ONCOMETABOLITES IN VIROIMMUNOTHERAPY FOR PEDIATRIC MALIGNANT BRAIN TUMORS

Abstract Diffuse midline gliomas (DMGs) are among the most frequent and lethal pediatric tumors. The standard of care for DMGs is palliative, resulting in a median survival of 12 months. Viroimmunotherapy is an emerging alternative treatment for these tumors. Our group developed a platform of oncolytic adenoviruses that was translated to the clinic. Specifically, Delta-24-RGD was recently tested in a Phase I clinical trial for patients with newly diagnosed DMG (NCT03178032) with encouraging results. To further stimulate the immune arm of this therapy, we developed Delta-24-RGDOX, expressing the T-cell activator OX40L (NCT03714334, NCT04714983). Using bulk RNAseq, we showed that treatment with Delta-24-RGDOX upregulated the immunosuppressive immunometabolic IDO-AhR pathway. Of importance, treatment with Th1-related cytokine IFNg resulted in the upregulation of IDO1 expression in a panel of human and murine DMG cells. In agreement with these data, we showed synergy between the oncolytic virus and several IDO1-AhR inhibitors in tumor and immune cell co-cultures, as indicated by T-cell activation and proliferation. To further dissect the reshaping of the TME in clinically relevant DMG models treated with Delta-24-RGD or Delta-24-RGDOX, we performed scRNA seq analysis. We showed a pronounced T-cell infiltration in virus-treated animals versus control-treated mice, further confirmed by flow cytometry. Additionally, Th1 and CD8 effector memory subsets were preferentially enriched in the Delta-24-RGDOX group, indicating an enhanced proinflammatory shift. Importantly, we detected, for the first time, upregulation of IDO-AhR downstream effectors in the myeloid compartment in the virus-treated groups. Interestingly, we detected IL4I1 in myeloid cells, a recently discovered checkpoint upstream of AhR never described in the context of virotherapy. Preliminary data using a combination of Delta-24-RGDOX and AhR inhibitors prolongs the survival of glioma-bearing mice. Collectively, our in vivo and in vitro data support the rationale to propel a future clinical trial combining Delta-24-RGDOX with AhR inhibitors for DMG.

EXTH-67. ONCOLYTIC ADENOVIRAL INFECTION OF CHORDOMA ACHIEVES TREATMENT EFFICACY THROUGH IMMUNOGENIC CELL DEATH AND TUMOR MICROENVIRONMENT ALTERATION

Abstract Chordomas are locally aggressive neoplasms of the axial skeleton with recurrence rates approaching 40%. Moreover, recurrent chordomas are nearly impossible to eradicate—highlighting an unmet clinical need. Immunotherapeutic approaches, such as immune checkpoint inhibition (ICI), has been a successful tool to modulate the tumor microenvironment (TME) towards a pro-inflammatory, antitumor state. There is emerging interest in exploring immunomodulatory agents for chordomas. Oncolytic viral (OV) therapy uses genetically modified viruses which selectively replicate in tumor cells, mediate tumor cell lysis, and initiate a pro-inflammatory response within the infected TME. These findings suggest that OV therapy may be a clinically relevant, novel immunotherapeutic approach for chordoma. Using the replicating oncolytic adenovirus Delta-24-RGD, we investigate the efficacy of chordoma treatment using in vitro approaches, ex vivo bone scaffolds, and in vivo murine models. Additionally, we explore the underlying mechanism of OV cytotoxicity, immunogenic cell death, Brachyury modulation, and reshaping of the TME towards a pro-inflammatory state. Across a panel of human chordoma cell lines, Delta-24-RGD achieved viral infectivity, oncolysis and immunogenic cell death. This treatment response was similarly demonstrated in chordoma cultured in bone scaffold models. Delta-24-RGD infection was associated with concomitant Brachyury downregulation within both infected and uninfected chordoma cells in vitro, suggesting a pleiotropic effect following oncolytic viral infection. In vivo models of CH22 chordoma treated with Delta-24-RGD demonstrated shrinkage in tumor volume and enhanced overall survival. Utilizing a human chordoma tissue microarray, the immunosuppressive macrophage marker CD163 was associated with shortened recurrence free survival. Using macrophage/chordoma co-culture, Delta-24-RGD infection achieved a reduction in macrophage expression of CD163. Taken together, Delta-24-RGD demonstrated efficacy in multiple models of chordoma including mice bearing CH22 tumors. The chordoma TME is associated with clinical outcomes and Delta-24-RGD infection reverses a deleterious immunosuppressive immune profile. These studies provide a framework for future clinical trial implementation for patients with metastatic or recurrent chordoma.

EXTH-34. ACETYLATION SUPPRESSION MEETS ONCOLYTIC VIRUSES FOR THE TREATMENT OF PEDIATRIC DIFFUSE MIDLINE GLIOMA

Abstract Diffuse midline glioma (DMG) remains a devastating pediatric brain tumor without effective treatment. In a recent clinical trial, we demonstrated the feasibility and efficacy of Delta-24-RGD oncolytic virus combined with radiation therapy in patients with newly diagnosed diffuse intrinsic pontine gliomas (NCT03178032). Because the adenoviral protein E1A binds to P300 and redirects acetylation upon virus infection, we hypothesized that combining oncolytic adenoviruses with P300 inhibitors will cause a remarkable shifting in acetylation and the post-translational landscape of DMG, ultimately enhancing the anti-glioma effect of oncolytic viruses. Western blot analyses showed a longitudinal reduction in H3K27ac (89%) and H3K18ac (99%) in a panel of human (TP54 and SF8628) and murine (24B_1 and 26C_7) DMG cells after Delta-24-RGD infection. In addition, using histone fractionation by high-performance liquid chromatography, we detected an increase in total H3 upon adenovirus infection. Mass spectrometry of histones in the human DIPG cell line, TP54 using middle-down approach illustrated post-translational changes across histones, including hypoacetylation of the H3.2K14 mark. To further modify histone acetylation in DMG during Delta-24-RGD infection, we combined virotherapy with C646, a selective and competitive histone acetyltransferase inhibitor of the E1A-binding p300/CBP complex of proteins. In vitro, the combination of Delta-24-RGD with C646 synergistically increased cell death in a panel of human and murine DIPG cell lines (zip-scores ranging from 6.3-11.3 with zip-scores above 10 being indicative of synergy). Ongoing experiments using a panel of adenoviruses expressing E1A with defective P300 binding or expressing a dominant-negative form of P300 or wild-type P300 are designed to test the extent to which E1A binding of P300 drives hypoacetylation in DMG upon virus infection. In addition, we are performing in vivo experiments to establish the anti-cancer effect of the combination of Delta-24-RGD and P300 inhibitors in clinically relevant animal models of DMG, with a feasible translation to the clinic.

IMMU-11. GUARDIANS OF INNATE IMMUNE ACTIVATION: CRUCIAL ROLES OF NONO AND CGAMP IN GLIOMA VIROTHERAPY

Abstract Despite aggressive therapeutic interventions, glioblastoma patients face a median survival of seven months after tumor recurrence. Alarmingly, there has been no improvement to the standard of care for two decades, and patients still receive toxic doses of radiation and chemotherapy, rendering many unable to perform daily functions. An emerging approach, oncolytic virotherapy (OV) using Delta-24-RGD, is gaining traction due to recent clinical trials (NCT00805376, NCT03178032, and NCT02798406) exhibiting robust responses in subsets of patients. While these studies demonstrated the therapeutic potential of OV, findings also indicate the early clearance of the virus, hindering the establishment of an effective anti-tumor immune response in most patients. We propose that mitigating the innate immune response against the therapeutic virus should result in improved intratumoral persistence, increasing the window of opportunity for developing an anti-tumor immune response. RNA-sequencing identified the non-POU domain containing octamer-binding (NONO) pathway as highly upregulated in syngenic glioma models and further amplified by OV treatment. In-vitro RNA sequencing and comparative analysis complemented these results to define a unique transcriptomic profile induced by adenovirus infection. LC-MS/MS identified host cGAS and adenoviral capsid proteins as candidate binding partners of NONO, which were validated using co-immunoprecipitation. Although the type I interferon cluster is deleted in most gliomas, tumor cells have a profound influence on their microenvironment through the secretion of the second messenger cGAMP. We show that NONO is required for cGAMP production, providing a mechanism to modulate antiviral responses in the tumor microenvironment during OV. Our findings underscore the significance of cGAMP shed from tumor cells in response to OV, and how NONO interacts with cGAS in the nucleus to sensor adenovirus infection. These findings uncover novel innate immunity mechanisms in gliomas and will inform the design of more efficacious oncolytic adenoviruses for glioma therapy.

Non-secreting IL12 expressing oncolytic adenovirus Ad-TD-nsIL12 in recurrent high-grade glioma: a phase I trial

Malignant glioma is a highly fatal central nervous system malignancy with high recurrence rates. Oncolytic viruses offer potential treatment but need improvement in efficacy and safety. Here we describe a phase I, dose-escalating, single arm trial (ChiCTR2000032402) to study the safety of Ad-TD-nsIL12, an oncolytic adenovirus expressing non-secreting interleukin-12, in patients with recurrent high-grade glioma that connects with the ventricular system. Eight patients received intratumoral treatment via stereotaxis or an Ommaya reservoir, with doses ranging from 5 × 109 to 5 × 1010vp. The primary end point was to determine the maximal tolerated dose. Secondary endpoints included toxicity and anti-tumour ability. Minimal adverse events were observed at doses of 5 × 109 and 1 × 1010vp. Grade 3 seizure was observed in two patients from Cohort 3 (5 × 1010vp). Therefore, the maximum tolerated dose was determined to be 1 × 1010vp. Four patients developed hydrocephalus during follow-up. Among them, symptoms in two patients were relieved after placement of a ventriculo-peritoneal shunt, and the other two only showed ventriculomegaly on MRI scan without neurological deterioration. Complete response (according to Response Assessment in Neuro-Oncology Criteria) in one patient, a partial response in one patient and post-treatment infiltrations of CD4+ and CD8 + T cells into the tumour were documented during this trial. In conclusion, Ad-TD-nsIL12 has demonstrated safety and preliminary efficacy in patients with recurrent high-grade glioma.

Single intravenous administration of oncolytic adenovirus TILT-123 results in systemic tumor transduction and immune response in patients with advanced solid tumors

BackgroundA limitation of approved oncolytic viruses is their requirement for intratumoral (i.t.) injection. TILT-123 (igrelimogene litadenorepvec, Ad5/3-E2F-D24-hTNFα-IRES-hIL-2) is a chimeric oncolytic adenovirus suitable for intravenous (i.v.) delivery due to its capsid modification and dual selectivity devices. It is armed with tumor necrosis alpha and interleukin-2 for promoting T-cell activation and lymphocyte trafficking to tumors, thereby enhancing the antitumor immune response. Here, we present the findings after a single i.v. administration of TILT-123 in three phase I dose escalation clinical trials.MethodsPatients with advanced solid tumors initially received a single i.v. dose of TILT-123 ranging from 3 × 109 to 4 × 1012 viral particles (VP). Blood was collected at baseline, 1, 16, and 192 h (7 days) post-treatment for bioavailability and serum analysis. Tumor biopsies were collected prior to treatment and 7 days post-treatment for analysis of viral presence and immunological effects. Patients did not receive any other cancer therapies during this period.ResultsAcross all three trials (TUNIMO, TUNINTIL, and PROTA), 52 total patients were treated with i.v. TILT-123. Overall, TILT-123 was found to be well-tolerated, with no dose-limiting toxicities observed. Post-treatment tumor biopsies showed expression of viral genes, presence of TILT-123 adenovirus proteins or DNA, and changes in immune cell infiltration from baseline. Increased virus dose did not lead to increased virus detection in tumors. Median overall survival was longer in patients with confirmed presence of TILT-123 in post-treatment biopsies (280 versus 190 days, p = 0.0405).ConclusionTILT-123 demonstrated safety and significant intratumoral immunomodulation following a single i.v. administration, warranting further investigation.Trial registrationsTUNIMO—NCT04695327. Registered 4 January 2021, https://clinicaltrials.gov/study/NCT04695327. TUNINTIL—NCT04217473. Registered 19 December 2019, https://clinicaltrials.gov/study/NCT04217473. PROTA—NCT05271318. Registered 4 February 2022, https://clinicaltrials.gov/study/NCT05271318.

Dendritic cell maturation is induced by p53-armed oncolytic adenovirus via tumor-derived exosomes enhancing systemic antitumor immunity.

Dendritic cells (DCs) are crucial in cancer immunity, because they activate cytotoxic T cells by presenting tumor antigens. Recently, oncolytic virus therapy has been recognized as a systemic immune stimulator. We previously developed a telomerase-specific oncolytic adenovirus (OBP-301) and a p53-armed OBP-301 (OBP-702), demonstrating that these viruses strongly activate systemic antitumor immunity. However, their effects on DCs remained unclear. In the present study, the aim was to elucidate the mechanisms of DC activation by OBP-702, focusing particularly on tumor-derived exosomes. Exosomes (Exo53, Exo301, or Exo702) were isolated from conditioned media of human or murine pancreatic cancer cell lines (Panc-1, MiaPaCa-2, and PAN02) after treatment with Ad-p53, OBP-301, or OBP-702. Exo702 derived from Panc-1 and MiaPaCa-2 cells significantly upregulated CD86, CD80, CD83 (markers of DC maturation), and IFN-γ in DCs in vitro. Similarly, Exo702 derived from PAN02 cells upregulated CD86 and IFN-γ in bone marrow-derived DCs in a bilateral PAN02 subcutaneous tumor model. This DC maturation was inhibited by GW4869, an inhibitor of exosome release, and anti-CD63, an antibody targeting the exosome marker. Intratumoral injection of OBP-702 into PAN02 subcutaneous tumors significantly increased the presence of mature DCs and CD8-positive T cells in draining lymph nodes, leading to long-lasting antitumor effects through the durable activation of systemic antitumor immunity. In conclusion, tumor-derived exosomes play a significant role in DC maturation following OBP-702 treatment and are critical for the systemic activation of antitumor immunity, leading to the abscopal effect.

An in silico approach uncovering the competency of oncolytic human adenovirus 52 for targeted breast cancer virotherapy

Breast cancer remains a major health threat throughout the world specifically in women above 30 years of age however, it is rarely known to affect men as well. It is characterized by the abnormal division of cells in the breast tissue resulting in the development of breast malignancies. Various risk factors contributing to breast cancer include age, family history, genetic mutations (chiefly in BRCA1 and BRCA2 genes) along with hormonal imbalances (oestrogen, progesterone, HER2). Early detection which can be obtained through frequent rounds of self-examination, mammographic scanning, and clinical assessment plays a crucial role in the prevention of the disease. In addition, appropriate diagnosis assists in better therapeutic responses. This study highlights the considerable health risks associated with the conventional treatment procedures which arise and increased demand of advanced, secure, and risk-free treatment alternatives. Oncolytic viruses are potentially apparent for the aim of improving cancer therapeutics with reduced side effects. These viruses act as the fundamental therapeutic agent themselves that selectively target and kill malignant cells without harm to healthy tissues. The key objective of the research is to provide evidence that Human Adenovirus 52 is a potent oncolytic virus and to highlight its capacity to target and eliminate cancer cells with precision while causing the least amount of harm to healthy tissues. Validating the in-silico method entails evaluating the precision and dependability of the computational modelling by contrasting the in-silico predictions with the findings from the experiments rank as the secondary objective. The workflow of this research utilized in-silico computational drug designing approaches including retrieval of tertiary structures of both the target Breast Cancer Type 1 Susceptibility Protein (BRCA1) and the viral Human Adenovirus 52 protein, their validation generating Ramachandran Plots determining favoured amino acid residue angles and prediction of their active residues. Furthermore, the study focused on the molecular dynamics docking of proteins, interpretation of molecular interactions between the docked complex, as well as the assessment of the molecular dynamic simulations (MD) in addition to their MMGBSA binding energy calculations. A successful docking between BRCA1 and Adenovirus protein provided a significant score of 329.2 +/- 24.3, furthermore, MD simulations showed a high RMSD peak at 2.8 Å, RMSF were maximum at 3.5 Å with highest protein–protein interaction, the radius of gyration was stable throughout the simulation representing elastic stability along with a high energy interaction value of - 7882 kCal/mol. Moreover, the MMGBSA calculation results showed a notable release of binding free energy of - 68.96 kCal/mol demonstrating effective bond formation between the docked complex. These findings propose the effectiveness of Human Adenovirus 52 to treat cancer. The selected oncolytic Human Adenovirus 52 is a potential candidate for the target specific treatment of breast cancer through virotherapy. This computer-aided drug discovery presents significant potential in targeting cancer cells and would assist in the development of potent drug reagents for the cancer therapy.

Engineering an oncolytic adenoviral platform for precise delivery of antisense peptide nucleic acid to modulate PD-L1 overexpression in cancer cells

Cancer immunotherapy is focused on stimulating the immune system against cancer cells by exploiting immune checkpoint mechanisms. PD-1/PD-L1 is one of the most known immune checkpoints due to the widespread upregulation of the Programmed Death Ligand 1 (PD-L1) transmembrane protein in cancer tissues. Accordingly, taking advantage of the ability of oncolytic adenoviruses (OAd) to specifically infect and kill tumor cells over healthy ones, here, we developed a targeted delivery platform based on OAd to selectively deliver in cancer cells an antisense peptide nucleic acid (PNA) targeting the PD-L1 mRNA. The antisense PNA was modified with a six-lysine tail to improve water solubility and binding affinity to the polyanionic surface of the OAd carrier. Dynamic light scattering measurements confirmed the effective binding of the PNA cargo to OAd. Flow cytometry analysis evaluated the impact on PD-L1 protein expression in A549 and SK-OV3 cancer cell lines post-incubation with the OAd/PNA system. Statistically significant PD-L1 downregulation was observed in SK-OV3 cells treated with OAd-delivered PNA, surpassing the effect of free PNA. Confocal microscopy showed the cytoplasmic localization of OAd-delivered PNA, supporting the proposed antisense mechanism for PD-L1 downregulation. This targeted delivery system holds potential for enhancing the effectiveness of cancer immunotherapy.

Decorin-armed oncolytic adenovirus promotes natural killers (NKs) activation and infiltration to enhance NK therapy in CRC model

Colorectal cancer (CRC) is a prevalent malignant tumor of the gastrointestinal system, with the third and second highest incidence and mortality rates globally in 2020, respectively. Immunotherapy has developed rapidly in recent years. Natural killer (NK) cells have received increasing attention in the field of tumor immunotherapy due to their recognition and killing tumor cells without the limitations of major histocompatibility complexes. However, constraints within the tumor microenvironment that impede the infiltration and proliferation of NK cells result in poor efficacy of NK cell therapy for solid tumors. Oncolytic viral therapy is an immunogenic treatment with the potential to enhance anti-tumour immune responses and promote immune cell infiltration. In this study, we synergistically combine NK cells with an oncolytic adenovirus carrying Decorin (rAd.DCN) for the treatment of colorectal cancer (CRC) in a xenograft mouse model. By using Flow cytometry, real-time quantitative PCR and Calcein-AM release assay, we found that rAd.DCN could effectively promote proliferation, activation and degranulation of NK cells, up-regulate expression and secretion of NK cell killing activity-related factors, and enhance their killing activity. The efficacy is better than that of the blank control oncolytic virus rAd.Null. Combined treatment significantly inhibited tumor growth, increased the number of NK cells in peripheral blood, promoted the killing function of NK cells, and increased the expression levels of perforin and IFN-γ. At the same time, more NK cells were recruited to infiltrate tumor tissue. Our study established the feasibility of combination NK cells and oncolytic adenovirus application, thus expanding the scope of potentially curative treatments for NK cells in CRC.

Apolipoprotein A1-encoding recombinant adenovirus remodels cholesterol metabolism in tumors and the tumor microenvironment to inhibit hepatocellular carcinoma

Hepatocellular carcinoma (HCC) is a prevalent malignant tumor requiring effective treatments. Oncolytic viruses induce anti-tumor responses but have limited efficacy. Apolipoprotein A1 (ApoA1) inhibits inflammation, modulates immunity, and promotes anti-oxidation. This study aims to construct an oncolytic adenovirus (Ad5)-ApoA1 for superior anti-tumor effects.We analyzed ApoA1 expression in tumors and its prognostic significance using public databases. Subsequently, we engineered a recombinant oncolytic adenovirus Ad5-ApoA1 and assessed its replication and oncolytic efficacy in vitro and in nude mice. The impact of Ad5-ApoA1 on the tumor microenvironment of HCC was evaluated through flow cytometry, transcriptome sequencing, single-cell sequencing, and other methodologies. Additionally, mechanisms of immune microenvironment modulation by Ad5-ApoA1 were explored. ApoA1 expression was down-regulated with HCC progression and significantly positively correlated with the prognosis of HCC patients. Ad5-ApoA1 exhibited robust oncolytic activity but showed no therapeutic effect on nude mice. However, it significantly inhibited HCC growth and prolonged the survival period of both healthy-immune and humanized immune-reconstituted NCG mice. Furthermore, Ad5-ApoA1 significantly promoted the expression of IFN-γ and GzmB in CD8+ T cells while inhibiting the expression of PD-1 and LAG-3. Notably, the cholesterol content in the CD8+ T cells studied was significantly correlated with the expression of PD-1 and LAG-3, with ApoA1 promoting cholesterol efflux and reducing cholesterol levels. Ad5-ApoA1 activates CD8+ T cells by promoting large-scale viral replication. High levels of ApoA1 protein expression promote cholesterol efflux, inhibit CD8+ T cell depletion, and reduce inflammatory factors, ultimately leading to superior therapeutic effects on hepatocellular carcinoma.

Extracellular vesicles powered cancer immunotherapy: Targeted delivery of adenovirus-based cancer vaccine in humanized melanoma model.

Malignant melanoma, a rapidly spreading form of skin cancer, is becoming more prevalent worldwide. While surgery is successful in treating early-stage melanoma, patients with advanced disease have only a 20% chance of surviving beyond five years. Melanomas with mutations in the NRAS gene are characterized for a more aggressive tumor biology, poorer prognosis and shorter survival. Hence, new therapeutic strategies are needed, especially for this specific group of patients. Novel approaches, such as cancer vaccines, offer promising solutions by stimulating the anti-tumor immune response. Nevertheless, their clinical efficacy is still modest and more effective approaches are required. Herein, we propose the systemic administration of the adenovirus-based cancer vaccine complexed in extracellular vesicles (EVs) with the aim of achieving a targeted therapeutic effect. The vaccine was based on previously tested oncolytic adenovirus Ad5/3-D24-ICOSL-CD40L in combination with melanoma-specific antigens targeting NRAS mutations to enhance the anticancer effect. The antineoplastic properties of the oncolytic vaccine were evaluated in xenograft MUG Mel-2 melanoma BALB/c nude mice. Moreover, to mimic the tumor microenvironment, while investigating at the same time immune cell infiltration and drug penetration, we established a 3D co-culture model based on human NRAS mutated MUG Mel-2 spheroids and PBMCs (HLA matched), which displayed a synergistic effect when treated with the cancer vaccine compared to relative controls. Subsequently, we investigated the systemic delivery of the vaccine in EV formulations in a humanized NSG MUG Mel-2 melanoma mouse model. Our study provides a promising strategy for a tumor-targeted vaccine delivery by EVs, resulting in improved anticancer efficacy and increased infiltration of tumor-infiltrating lymphocytes. This study explores the potential of EVs for the selective delivery of cancer vaccines against malignancies, such as NRAS melanoma. Overall, this research could pave the way for applying autologous EVs as a safe and efficacious tool for targeted cancer therapy.

Abstract B054: Enhanced Antitumor Efficacy of Oncolytic Adenovirus Co-Expressing IL-12 and shVEGF Combined with Anti-PD-1 in Renal Cell Carcinoma

Abstract B054: Enhanced Antitumor Efficacy of Oncolytic Adenovirus Co-Expressing IL-12 and shVEGF Combined with Anti-PD-1 in Renal Cell Carcinoma

Novel combination therapy using recombinant oncolytic adenovirus silk hydrogel and PD-L1 inhibitor for bladder cancer treatment

Recombinant oncolytic adenovirus offers a novel and promising cancer treatment approach, but its standalone efficacy remains limited. This study investigates a combination treatment strategy by co-administering recombinant oncolytic Adv-loaded silk hydrogel with a PD-L1 inhibitor for patients with bladder cancer to enhance treatment outcomes. Bladder cancer tissues from mice were collected and subjected to single-cell sequencing, identifying CRB3 as a key gene in malignant cells. Differential expression and functional enrichment analyses were performed, validating CRB3’s inhibitory role through in vitro experiments showing suppression of bladder cancer cell proliferation, migration, and invasion. Recombinant oncolytic adenoviruses encoding CRB3 and GM-CSF were constructed and encapsulated in silk hydrogel to enhance drug loading and release efficiency. In vivo experiments demonstrated that the nano-composite hydrogel significantly inhibited tumor growth and increased immune infiltration in tumor tissues. Co-administration of adenovirus silk hydrogel (Adv-CRB3@gel) with a PD-L1 inhibitor significantly enhanced T-cell infiltration and tumor killing. The combination of recombinant oncolytic Adv-loaded nano-composite hydrogel encoding CRB3 and GM-CSF with a PD-L1 inhibitor improves bladder cancer treatment outcomes by effectively recruiting T cells, providing a novel therapeutic strategy.

Interleukin-12 Delivery Strategies and Advances in Tumor Immunotherapy.

Interleukin-12 (IL-12) is considered to be a promising cytokine for enhancing an antitumor immune response; however, recombinant IL-12 has shown significant toxicity and limited efficacy in early clinical trials. Recently, many strategies for delivering IL-12 to tumor tissues have been developed, such as modifying IL-12, utilizing viral vectors, non-viral vectors, and cellular vectors. Previous studies have found that the fusion of IL-12 with extracellular matrix proteins, collagen, and immune factors is a way to enhance its therapeutic potential. In addition, studies have demonstrated that viral vectors are a good platform, and a variety of viruses such as oncolytic viruses, adenoviruses, and poxviruses have been used to deliver IL-12-with testing previously conducted in various cancer models. The local expression of IL-12 in tumors based on viral delivery avoids systemic toxicity while inducing effective antitumor immunity and acting synergistically with other therapies without compromising safety. In addition, lipid nanoparticles are currently considered to be the most mature drug delivery system. Moreover, cells are also considered to be drug carriers because they can effectively deliver therapeutic substances to tumors. In this article, we will systematically discuss the anti-tumor effects of IL-12 on its own or in combination with other therapies based on different delivery strategies.

Systemic delivery of tannic acid-ferric-masked oncolytic adenovirus reprograms tumor microenvironment for improved therapeutic efficacy in glioblastoma.

Glioblastoma (GBM) represents the most aggressive primary brain tumor, and urgently requires effective treatments. Oncolytic adenovirus (OA) shows promise as a potential candidate for clinical antitumor therapy, including in the treatment of GBM. Nevertheless, the systemic delivery of OA continues to face challenges, leading to significantly compromised antitumor efficacy. In this study, we developed an innovative approach by encapsulating CXCL11-armed OA with tannic acid and Fe3+ (TA-Fe3+) to realize the systemic delivery of OA. The nanocarrier's ability to protect the OA from elimination by host immune response was evaluated in vitro and in vivo. We evaluated the antitumor effect and safety profile of OA@TA-Fe3+ in a GBM-bearing mice model. OA@TA-Fe3+ effectively safeguarded the virus from host immune clearance and extended its circulation in vivo. After targeting tumor sites, TA-Fe3+ could dissolve and release Fe3+ and OA. Fe3+-induced O2 production from H2O2 relieved the hypoxic state, and promoted OA replication, leading to a remarkable alteration of tumor immune microenvironment and enhancement in antitumor efficacy. Moreover, the systemic delivery of OA@TA-Fe3+ was safe without inflammation or organ damage. Our findings demonstrated the promising potential of systemically delivering the engineered OA for effective oncolytic virotherapy against GBM.