RETRACTED ARTICLE: Cross-HLA targeting of intracellular oncoproteins with peptide-centric CARs
The majority of oncogenic drivers are intracellular proteins, thus constraining their immunotherapeutic targeting to mutated peptides (neoantigens) presented by individual human leukocyte antigen (HLA) allotypes1. However, most cancers have a modest mutational burden that is insufficient to generate responses using neoantigen-based therapies2,3. Neuroblastoma is a paediatric cancer that harbours few mutations and is instead driven by epigenetically deregulated transcriptional networks4. Here we show that the neuroblastoma immunopeptidome is enriched with peptides derived from proteins that are essential for tumourigenesis and focus on targeting the unmutated peptide QYNPIRTTF, discovered on HLA-A*24:02, which is derived from the neuroblastoma dependency gene and master transcriptional regulator PHOX2B. To target QYNPIRTTF, we developed peptide-centric chimeric antigen receptors (CARs) using a counter-panning strategy with predicted potentially cross-reactive peptides. We further hypothesized that peptide-centric CARs could recognize peptides on additional HLA allotypes when presented in a similar manner. Informed by computational modelling, we showed that PHOX2B peptide-centric CARs also recognize QYNPIRTTF presented by HLA-A*23:01 and the highly divergent HLA-B*14:02. Finally, we demonstrated potent and specific killing of neuroblastoma cells expressing these HLAs in vitro and complete tumour regression in mice. These data suggest that peptide-centric CARs have the potential to vastly expand the pool of immunotherapeutic targets to include non-immunogenic intracellular oncoproteins and widen the population of patients who would benefit from such therapy by breaking conventional HLA restriction.
Cytokine therapy for cancer has indicated efficacy in certain diseases but is generally accompanied by severe toxicity. The field of antibody–cytokine fusion proteins (immunocytokines) arose to target these effector molecules to the tumor environment in order to expand the therapeutic window of cytokine therapy. Pre-clinical evidence has shown the increased efficacy and decreased toxicity of various immunocytokines when compared to their cognate unconjugated cytokine. These anti-tumor properties are markedly enhanced when combined with other treatments such as chemotherapy, radiotherapy, and checkpoint inhibitor antibodies. Clinical trials that have continued to explore the potential of these biologics for cancer therapy have been conducted. This review covers the in vitro, in vivo, and clinical evidence for the application of immunocytokines in immuno-oncology.
BACKGROUND High-risk neuroblastoma is a pediatric cancer arising from the developing sympathetic nervous system with a 50% relapse rate that is typically fatal. At least two subpopulations of neuroblastoma cells exist that can transdifferentiate, adrenergic and mesenchymal, the latter being more resistant to chemotherapy. Mechanisms of therapy resistance are largely unknown and the cells responsible for relapse have not been identified. METHODS We used single nucleus RNA and ATAC sequencing to identify and characterize the cells that survive chemotherapy, termed here “persister cells”, from a cohort of 20 matched diagnostic and post induction chemotherapyhigh-risk neuroblastoma patients and two patient derived xenograft (PDX) models from diagnostic tumors. Eight representative cell lines derived from neuroblastomas at diagnosis were treated with standard-of-care chemotherapy, and flow cytometry was used to sort for live cells. ML120B and CRISPR-CAS9 were used to modulate NF-kB signaling. An RNA-seq dataset of 153 high-risk neuroblastoma patients was used to determine differentially activated pathways between adrenergic and mesenchymal tumors. RESULTS Residual malignant cells in the post-chemotherapy tumor samples clustered into three main groups separated by the response to therapy. The most prevalent group of persister cells in responders (N=16/20) displayed low MYC(N) activity even in the presence of MYCN amplification. This group also demonstrated decreased expression of the adrenergic core regulatory circuit genes including PHOX2B, ISL1, HAND2, along with marked activation of TNF-alpha via NF-kB signaling. High NF-kB activity was found in a subpopulation of diagnostic cells in two chemo-refractory patients. We validated decreased expression of MYCN (2-fold decrease, p<0.0001) and PHOX2B (3.13-fold decrease, p<0.0001) in PDXs following chemotherapy. MYCN protein levels were decreased and nuclear p65 levels were increased in cell lines treated with chemotherapy. Pharmacologic inhibition of NF-kB signaling and genetic depletion of p65 resulted in increased killing (3.58-fold increase, p=0.0012) of neuroblastoma cell lines in response to chemotherapy. Finally, we classified 153 diagnostic high-risk neuroblastomas as predominantly adrenergic or mesenchymal using RNA-seq, showing that mesenchymal tumors were enriched with NF-kB pathway activation signatures. We then validated high nuclear p65 levels in 3 mesenchymal cell lines. We tested 6 adrenergic lines, 4 of which had no detectable nuclear p65. Notably, the 2 cell lines with detectable nuclear p65 were derived from diagnostic specimens that showed de novo chemotherapy resistance. CONCLUSIONS NF-kB activation is a major mediator of de novo and acquired chemotherapy resistance in high-risk neuroblastoma. We postulate that concomitant silencing of this pathway could eliminate persister cells and prevent disease relapse. Citation Format: Liron D. Grossmann, Yasin Uzun, Jarrett Lindsay, Chia-Hui Chen, Catherine Wingrove, Peng Gao, Anusha Thadi, Quinlen Marshall, Nathan M. Kendsersky, Lea Surrey, Daniel Martinez, Emily Mycek, Colleen Casey, Kateryna Krytska, Matthew Tsang, Adam Wolpaw, David N. Groff, Erin Runbeck, Jayne McDevitt, Dinh Diep, Tasleema Patel, Kathrin M. Bernt, Chi Dang, Kun Zhang, Yael P. Mosse, Kai Tan, John M. Maris. NF-kB is a master regulator of resistance to therapy in high-risk neuroblastoma [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 699.
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