On March 22, 2021 ImmunityBio, Inc. (NASDAQ: IBRX), a clinical-stage immunotherapy company, reported the publication of preclinical data in the Journal for ImmunoTherapy of Cancer (JITC) highlighting efficacy of ImmunityBio’s PD-L1 t-haNK natural killer cell-based therapy in combination with T cell-based immunotherapy against heterogeneous tumors (Press release, NantKwest, MAR 22, 2021, View Source [SID1234576948]). ImmunityBio’s novel PD-L1 t-haNKs are derived from a human, allogeneic NK cell line (NK-92) that has been engineered to express IL-2, CD16, and a chimeric antigen receptor (CAR) that recognizes PD-L1.

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Human solid tumors are made of multiple clones of tumor cells, some of which harbor genomic alterations that make them invisible to T cells. These resistant clones accomplish this "cloaking ability" by preventing the presentation of the tumor antigens on MHC-I receptors, thus "hiding" from killer T cells. For these patients, maximum activation of T cells with immunotherapy is unlikely to lead to durable tumor control or a cure. However, when NK cells are activated, tumor recognition and targeting is restored. The study shows that when subpopulations of tumors cells escape T cell detection or killing, they upregulate PD-L1 in the process because of interferon in the tumor microenvironment. This increase in tumor cell PD-L1 expression sensitizes them to killing by PD-L1 t-haNKs.

"Our results suggest that sequential treatment, first with T cell immunotherapy to kill the sensitive tumor cells and upregulate PD-L1 on the remaining cells, followed by PD-L1 t-haNK treatment, may overcome the issue of tumor heterogeneity and enhance rates of durable tumor control in patients with relapsed solid cancers," said Clint T. Allen, M.D., Principal Investigator, Section on Translational Tumor Immunology in the National Institute on Deafness and Other Communication Disorders (NIH) and corresponding author of the publication.

The publication by first author Maxwell Lee et al., "Chimeric antigen receptor engineered NK cellular immunotherapy overcomes the selection of T cell escape variant cancer cells," describes the development of preclinical models with heterogenous cancers containing T cell escape variant tumor cells. T cell-based immunotherapy administered in these preclinical models resulted in IFNγ production that in turn upregulated PD-L1 expression in T cell escape variants. Subsequent administration of irradiated PD-L1 t-haNKs targeted and eliminated the tumor cell populations that had evolved to be resistant to T-cell immunotherapy alone, resulting in synergistic anti-tumor activity.

"We are excited to see this preclinical study that affirms our hypothesis of ‘Quantum Oncotherapeutics,’ which is currently being studied in Phase1/2 QUILT trials across multiple tumor types. The theory we hold is that our treatment itself induces changes in the tumor immune microenvironment. By anticipating these dynamic cellular changes, we can administer and activate NK cells at the optimal time and, ultimately, outsmart the tumor. These spatial-temporal insights informing treatment, have the potential to change the paradigm of cancer care with modernized immunotherapy protocols, beyond the standard-of-care therapy and beyond checkpoint therapy alone. Late-stage, randomized controlled trials in pancreatic and lung cancers that orchestrate NK cells and T cells are underway at ImmunityBio to confirm this hypothesis," said Patrick Soon-Shiong, M.D. Founder and Executive Chairman of ImmunityBio.