Intrinsic Immunosuppressive Features of Monocytes Suppress CART19 through IL-1 Pathway Modulation in Mantle Cell Lymphoma

Brexucabtagene autoleucel (brexu-cel), a CD28-costimulated CD19-targeted chimeric antigen receptor T cell (CART19) product, was FDA-approved in 2020 after demonstrating remarkable efficacy in the pivotal ZUMA-2 trial of patients with mantle cell lymphoma (MCL).

However, despite the impressive initial activity of CART19 cell therapy in MCL, most patients relapse within the first 3 years following treatment. Myeloid cells, such as monocytes and macrophages, have been demonstrated to be major inhibitors of other immune cells, including T cells. Growing evidence shows that monocytes and macrophages contribute to CART cell failure, although the exact mechanisms are not fully understood.

To better understand the mechanisms contributing to CART treatment resistance in MCL, we first utilized brexu-cel products from patients with MCL on the ZUMA-2 trial to uncover their transcriptomic features by single cell RNA sequencing (scRNAseq) analysis. To understand if myeloid cells had negative impacts on clinical outcomes, we then analyzed autologous baseline peripheral blood mononuclear cell (PBMC) samples by scRNAseq. Our analyses of the brexu-cel samples revealed reduced response to IL-1β and its downstream signaling pathway as well as impaired T cell functions in non-responders. Transcriptomic analyses of the autologous baseline monocyte populations showed downregulation of IL-1β production and its associated pathways as well as upregulation of M2 phenotype-associated genes and IL-1 receptor antagonist (IL-1ra) in non-responder monocytes, implying a potential role of myeloid cells in CART resistance through impairment of IL-1 signaling in brexu-cel products.

To validate our findings from the ZUMA-2 samples, we further studied the interactions between macrophages, MCL cells, and CART19 cells in preclinical models.

First, CD28-costimulated CART19 cells generated from healthy donors were cocultured with JeKo-1, a CD19+ MCL cell line, and freshly isolated monocytes or ex vivo differentiated M2-like macrophages. M2-like macrophages were generated by incubating fresh monocytes with rhGM-CSF followed by coculturing with JeKo-1. CART19 antigen-specific proliferation was significantly inhibited by M2-like macrophages but not fresh monocytes (JeKo-1+CART19 vs JeKo-1+M2+CART19, p=0.00503). Transwell assays indicated that suppression by M2-like macrophages was contact-independent. Cytokine profile analysis of coculture supernatants showed significant elevation of IL-1ra in M2-like macrophage cocultures (JeKo-1+Mono+CART19 vs JeKo-1+M2+CART19, p=0.0292). This led us to hypothesize that M2-like macrophages inhibit CART19 by secreting IL-1ra to block IL-1 signaling in CART19.

To test this hypothesis, we interrogated the role of IL-1ra in CART19. CART19 + JeKo-1 cocultures were supplemented with IL-1β + IL-1ra or IL-1β + IL-1ra + IL-1ra neutralizing antibody (neuAb). CART19 proliferation was improved by IL-1β (vehicle control vs IL-1β, p<0.0001). IL-1ra inhibited IL-1β-dependent CART19 proliferation (IL-1β vs IL-1β+IL1ra, p=0.0006), which was restored by IL-1ra neutralization (IL-1β+IL-1ra vs IL-1β+IL-1ra+IL-1ra neuAb, p=0.0215). Next, we assessed the impact of IL-1ra on CART functions in mouse MCL xenografts in the presence of M2-like macrophages. NOD-SCID-γ-/- (NSG) mice were subcutaneously injected with 0.5 million of human macrophages and 1 million of luciferase⁺ JeKo-1. Mice were then randomized once tumor engraftment was confirmed by bioluminescence imaging (BLI), followed by treatment with 2 million CART19 with 10 mg/kg IL-1ra neuAb or control IgG for 3 weeks. Combination of CART19 cells and IL-1ra neuAb led to improved antitumor activity based on BLI measurements compared to control IgG (IL-1ra neuAb vs control IgG, p=0.0058). Additionally, expression of IL-1RI, receptor of IL-1β and IL-1ra, was measured on T cells after coculturing CART19, JeKo-1, and M2-like macrophages. M2-like macrophages downregulated IL-1RI expression on CART cells, which might potentially desensitize CART response to IL-1β, resulting in further suppression in CART proliferation (JeKo-1+M2+CART19 vs JeKo-1+CART19, p=0.001).

Overall, our study elucidates a potential mechanism of IL-1 pathway modulation mediated by myeloid cells in contributing to CART19 failure in MCL.