Interpretation: Malgre les progres therapeutiques et la vaccination des receveurs d'une transplantation d'organe plein, les signes de gravite accrue de la COVID-19, en particulier chez les receveurs ...d'une transplantation pulmonaire, justifient le maintien des mesures de sante publique pour proteger ces personnes a risque, et l'utilisation hative de traitements contre la COVID-19 chez les receveurs d'une transplantation d'organe plein.
Abstract
With a 2-year survival less than 20%, Diffuse Intrinsic Pontine Glioma (DIPG) is the principal cause of pediatric death. Despite recent advances in the current treatments, the outcome for ...children with DIPGs remains dismal. Since the approval of T-VEC for melanoma by the FDA, oncolytic adenoviruses have emerged as a promising therapeutic strategy for brain tumors. Thus, our group launched the first world clinical trial phase I with the oncolytic adenovirus Delta-24-RGD (DNX-2401 in the clinic) for newly diagnosed DIPG (NCT03178032), which has shown safety and feasibility. Despite DNX-2401 increases the recruitment of T cells into the tumor, they usually become inactive due to the non-responsive tumor microenvironment evidencing the urgent need to improve this strategy focusing on the generation of effective long-term immune responses. Therefore, we decided to combine the Delta-24-RGD with the targeting of the costimulatory molecule CD40 in immunocompetent mice bearing orthotopic DIPG. The activation of the CD40 receptor, which is expressed by antigen presenting cells (APC) such as microglia, macrophages, and dendritic cells, is known to increase antigen presentation and enable T-cell priming and activation. Here, we observed that in addition to Delta-24-RGD anti-tumor effects, the stimulation of CD40 (using an agonistic antibody) on the tumor APCs results in a remodeling of the tumor immune compartment towards a proinflammatory scenario and a more efficient T-cell infiltration. Of importance, the combination therapy extends survival of treated mice as compared to single treatments or non-treated mice. In addition, we observe a complete regression of tumors in more than 40% of treated mice and the development of long-term anti-tumor immunity. We believe that these results provide a translational breakthrough in the treatment of these lethal tumors and open the door for a future innovative clinical trial.
Abstract
Chimeric antigen receptor (CAR) T cells targeting the disialoganglioside GD2 have shown promise as a therapeutic for diffuse midline glioma (DMG). However, prior studies raised significant ...concerns of neurotoxicity and fatality when using virally transduced CAR T cells against midline thalamic tumors. Building upon our prior work optimizing mRNA for use in CAR T cells (Hum Gen Ther, 2019), we hypothesized repeated dosing of transient GD2-directed mRNA CAR T cells could be employed for safe and effective treatment of thalamic DMG. GD2-directed CAR T cells were created using mRNA encoding the 14G2a single chain variable fragment paired with 41BB and CD3-zeta co-stimulatory domains and transfected into human T cells. CAR T cells were tested against the murine thalamic DMG xenograft 7316-6349 via locoregional delivery with an indwelling infusion catheter for repeated dosing. The previously reported fatal neurotoxicity observed in mice using lentiviral CAR T cells could be recapitulated with aggressive dosing. Four doses of 5 x 106 mRNA CAR T cells delivered intratumorally twice a week resulted in median overall survival of 9 days for GD2-treated mice compared to >30 days for CD19-treated controls (p<0.01). This toxicity could be avoided by decreasing the dose and timing of infusions to 2 x 106 mRNA CAR T cells delivered once weekly. Bioluminescent imaging showed regression of tumor in GD2-treated mice compared to CD19-treated controls (radiance fold change -3 x106 versus +20x106 p/sec/cm2/sr, p<0.01). Notably, non-tumor bearing mice treated with GD2-directed CAR T cells quickly developed fatal neurotoxicity within 14 days, suggesting on-target/off-tumor effect of the CAR T cells and a very narrow therapeutic window in the brain. These data highlight the utility of titratable mRNA-based CAR T cell therapy for CNS tumors and establish GD2-directed mRNA CAR T cells as a safe and effective method for treating thalamic DMG.
Abstract
Molecular profiling of pediatric ependymoma (EPN) has previously identified discrete neoplastic subpopulations, of which Mesenchymal EPN Cells (MEC) characterize Posterior Fossa A tumors ...(PFA). MECs are associated with tumor immunosuppression. Here we further characterize the EPN immune environment using single-cell sequencing, spatial phenotyping and cytokine analyses to better define infiltrating myeloid subpopulations. We hypothesize that neoplastic and myeloid cells interact to propagate an immune suppressive environment conferring resistance to traditional therapies. We delineated myeloid cell subpopulations from single-cell RNA-seq of 26 pediatric EPNs and validated them through deconvolution of bulk gene expression profiling (n=299). To define subpopulation spatial distribution, we interrogated a range of tumor and myeloid markers using multiplex immunofluorescence (mIF). Finally, using single-cell cytokine analyses, we gained further insight into myeloid subpopulation function. Eight distinct myeloid subpopulations were identified, relating to macrophages, microglia and monocytes. A subpopulation of cells with wound healing ontologies and characterized by TREM1 expression, demonstrated features of myeloid derived suppressor cells, including IL6/STAT3 pathway activation. We called these hypoxia-M. Like MEC neoplastic cells, hypoxia-M was associated specifically with PFA1 subgroup EPN in both single-cell and bulk tumor gene expression profiling (p<0.001). Additionally, the presence of MEC and hypoxia-M correlated strongly in gene expression (r2=0.92, p<0.001) and IHC analyses, where they co-located to borders between necrosis, blood vessels and viable tumor. Analysis using mIF (n=54) confirmed MEC/hypoxia-M co-location and highlighted that all types of immune cell corralled in significant numbers around areas of vasculature and necrosis. Single cell cytokine analyses demonstrated that hypoxia-M secrete IL-8 which, we hypothesize, amplify the pro-tumor phenotype in PFA1 tumor microenvironment. EPN is characterized by discrete myeloid cell subpopulations which contribute to the tumor microenvironment. Treatment strategies must focus on modifying this pro-tumor, immunosuppressive microenvironment to deliver more effective treatment for childhood ependymoma.
Abstract
BACKGROUND: The development of effective chimeric antigen receptor (CAR) T-cell therapies for malignant pediatric brain tumors remains a challenge due to multiple barriers, including ...antigenic heterogeneity, on-target off-tumor toxicities, and T cell exhaustion. We have adopted a novel synthetic Notch “synNotch” receptor system and developed innovative T-cell circuits that recognize tumor cells based on the “prime-and-kill” strategy.
METHODS: We created a novel synNotch-CAR circuit in which the brain/glioma-specific antigen Brevican (BCAN) primes the T cells to induce expression of a CAR that recognizes interleukin-13 receptor α2 (IL-13Rα2) and ephrin type A receptor (EphA2), thereby eradicating glioma cells expressing either antigen. Immunocompromised mice bearing the SF8628 DIPG cell line in the frontal lobe or brain stem received a single intravenous (IV) infusion of synNotch CAR T-cells (2.5 x 106 each of CD4+ and CD8+ T cells) on day 6 following the tumor inoculation. Mice were monitored for toxicity and tumor growth.
RESULTS: Following this synNotch CAR T-cell dose, although tumors in the brainstem did not regress, 3 of the 5 mice with frontal lobe tumors demonstrated complete and sustained remission. Our histological analyses revealed primed CAR T-cells both within and surrounding the tumor in both settings. By flow cytometry, we confirmed the CAR T-cells in the CNS were primed and mostly did not express an exhaustive phenotype. In the spleen, we also found the CAR T-cells in a more naïve and central memory state.
CONCLUSIONS: Our work so far has demonstrated that synNotch-CAR T-cells are able to traffic to the tumor microenvironment even in the brainstem, are primed to express the CAR, and most do not express an exhaustive phenotype. Future work will include CAR T-cell dose optimization, continued assessments of the tumor microenvironment, and investigating for antigen escape.
Abstract
INTRODUCTION: Recent clinical trials of immune checkpoint inhibitors indicated 5-11% response rate in pediatric patients depending on cancer type and expression of target proteins. ...Currently, a systematic analysis characterizing the immune microenvironment of childhood tumors is lacking. The main objective of this study is to uncover the features of immune microenvironment in pediatric nervous system tumors (pedNST). METHODS: We compiled transcriptomes of 925 tumors from three initiatives, Therapeutically Applicable Research To Generate Effective Treatments (TARGET, n = 149), International Cancer Genome Consortium (ICGC, n = 195) and Children Brain Tumor Tissue Network (CBTN, n = 581). We analyzed the performance of immune deconvolution tools and used publicly available datasets to define immune genesets. We conducted a consensus analysis to assign genes to cell-types and identify immunological groups. RESULTS: We found wide variability in immune infiltration across and within cancer types ranging from cold tumors such as medulloblastoma (2.7% infiltrate) to infiltrated entities such as neurofibroma (22.6%). Consensus clustering revealed four distinct immune clusters. The pediatric inflamed group (10%) included MYCN non-amplified neuroblastoma and ATRT. The myeloid-predominant group (30%) showed decreased infiltration of lymphoid cells but enrichment of myeloid cell genesets. The pediatric-cold group (42%) harbored no enrichment of immune genesets and included 72% of ependymomas and 65% of medulloblastomas. The immune excluded group (18%) showed depletion of immune cell-types and included sonic-hedgehog medulloblastoma. 71% of pedNST belonged to the lymphocyte depleted or immunologically quiet clusters, indicating the cold immune microenvironment in pedNST compared to adult cancers. CONCLUSION: We report characteristics of the immune microenvironment in pedNST. We found an overall cold microenvironment with low lymphocyte infiltration in this population compared to common adult cancers. We identified ~10% of tumors harboring a relatively inflamed microenvironment. Our data uncover characteristics of immune infiltration in pediatric tumors with potential implications to guide therapy.
Abstract
Immunotherapy with chimeric antibody receptor (CAR) T cells is effective for previously incurable hematologic cancers and may transform treatment for refractory brain tumors. However, CAR-T ...cell therapy for solid tumors has not yet been as successful as for leukemias, and animal models are needed to improve implementation. At present, preclinical studies of CAR-T cell therapy for brain tumors have typically used exogenous tumors, xenografted into immunocompromised mice, because primary mouse brain tumors do not express antigens that match brain tumor-specific antigens in humans. To advance preclinical development of CAR-T brain tumor therapy, we engineered mice to develop medulloblastomas that express B7-H3, an antigen specifically expressed on human medulloblastomas and other pediatric brain tumors. We show that treating these tumors with B7-H3-directed CAR-T cells provokes anti-tumor responses both in vitro and in vivo. Administering B7-H3 CAR-T cells by intracranial injection increased the event-free survival time of mice with medulloblastoma, in a dose-dependent manner. CAR-T cell treatment was not curative as an isolated intervention, suggesting that cure will require pairing with surgical resection and additional adjuvant therapy. Our model presents new opportunities to study the mechanisms of CAR-T cell efficacy and recurrence in an immunocompetent host with intact vasculature and blood-brain barrier. Our ongoing studies using scRNA-seq will allow us to define therapy-induced changes in tumor cells, CAR-T cells and cells of the tumor microenvironment and to test new T-cell modifications and combinations of therapeutic modalities, toward a goal of optimizing CAR-T cell therapy for pediatric brain tumors.
Abstract
BACKGROUND: High-grade gliomas (HGG) with replication-repair deficiency (RRD) harbour high mutation burden (TMB) and are rapidly fatal following chemo-radiation approaches. Although ...hypermutation results in objective responses and prolonged survival in >30% of patients undergoing PD1-blockade, salvage following failure of PD1-inhibition remains a challenge. METHODS: We performed a real-world study of Ipilimumab (anti-CTLA4) in combination with Nivolumab/Pembrolizumab for patients failing single-agent PD1-inhibition. RESULTS: Among 68 consortium patients with relapsed HGG treated with single-agent PD1-inhibitors, progression was observed in 43 (63%). Ipilimumab was added to 20/43 (46.5%), 14 (32.5%) received best supportive care (BSC), and 9 (21%) received miscellaneous therapies. For patients receiving CTLA4/PD1-inhibition, median age at progression was 12.3-years (IQR: 9; 15.6). Time from anti-PD1 initiation to progression was 8-months (IQR: 3.8; 18.5). Germline predisposition was observed in all patients (CMMRD: 70%, Lynch: 25%, polymerase-proofreading deficiency: 5%). All HGG were hypermutant (median TMB: 182 mutations/Mb; IQR: 15.6; 369.4). Centralized radiology review revealed objective responses in 3/20 (15%, all ultra-hypermutant: 320, 496, 834 mutations/Mb), stable disease in 5 (25%), and 12 (60%) eventually progressed (iRANO). Following failure of PD1-blockade, estimated progression-free and overall survival at 18-months for patients receiving CTLA4/PD1-inhibition were 11% and 25%, respectively. Importantly, survival was superior to patients receiving BSC (median OS <1-month versus 12-months on CTLA4/PD1-inhibition; p<0.001). All patients receiving BSC died within 3.5-months, while 4/8 survivors were alive for >1-year on the anti-CTLA4/PD1combination (range:1-48 months). The combinational immunotherapy resulted in significant autoimmune toxicity in 11/20 (55%), warranting immunosuppressive therapy in all, and treatment abandonment in 6 patients. CONCLUSION: Combined CTLA4/PD1-blockade after failure of single-agent PD1-inhibition revealed objective responses and prolonged survival in an otherwise rapidly-fatal disease. This needs to be assessed in the context of significant autoimmunity, supporting the need for the current prospective trial (NCT04500548), and novel strategies to limit treatment-related toxicity.