M Selli scite author profile

Primary cutaneous γδ T cell lymphomas (PCGDTLs) represent a heterogeneous group of uncommon but aggressive cancers. Herein, we perform genome-wide DNA, RNA, and T cell receptor (TCR) sequencing on 29 cutaneous γδ lymphomas. We find that PCGDTLs are not uniformly derived from Vδ2 cells. Instead, the cell-of-origin depends on the tissue compartment from which the lymphomas are derived. Lymphomas arising from the outer layer of skin are derived from Vδ1 cells, the predominant γδ cell in the epidermis and dermis. In contrast, panniculitic lymphomas arise from Vδ2 cells, the predominant γδ T cell in the fat. We also show that TCR chain usage is non-random, suggesting common antigens for Vδ1 and Vδ2 lymphomas respectively. In addition, Vδ1 and Vδ2 PCGDTLs harbor similar genomic landscapes with potentially targetable oncogenic mutations in the JAK/STAT, MAPK, MYC, and chromatin modification pathways. Collectively, these findings suggest a paradigm for classifying, staging, and treating these diseases.

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Costimulatory Domains Direct Distinct Fates of CAR T Cell Dysfunction

Selli¹,

Landmann²,

Lattin

et al. 2022

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Costimulatory domains direct distinct fates of CAR-driven T cell dysfunction

Selli

Landmann

Terekhova

et al. 2023

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T cells engineered to express chimeric antigen receptors (CARs) targeting CD19 have demonstrated impressive activity against relapsed or refractory B cell cancers yet fail to induce durable remissions for nearly half of patients treated. Enhancing the efficacy of this therapy requires detailed understanding of the molecular circuitry that restrains CAR-driven anti-tumor T cell function. We developed and validated an in vitro model that drives T cell dysfunction through chronic CAR activation and interrogated how CAR costimulatory domains, central components of CAR structure and function, contribute to T cell failure. We found that chronic activation of CD28-based CARs results in activation of classical T cell exhaustion programs and development of dysfunctional cells that bear the hallmarks of exhaustion. In contrast, 41BB-based CARs activate a divergent molecular program and direct differentiation of T cells into a novel cell state. Interrogation of CAR T cells from a patient with progressive lymphoma confirmed activation of this novel program in a failing clinical product. Further, we demonstrate that 41BB-dependent activation of the transcription factor FOXO3 is directly responsible for impairing CAR T cell function. These findings identify that costimulatory domains are critical regulators of CAR-driven T cell failure and that targeted interventions are required to overcome costimulation-dependent dysfunctional programs.

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Antigen glycosylation regulates efficacy of CAR T cells targeting CD19

et al. 2022

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While chimeric antigen receptor (CAR) T cells targeting CD19 can cure a subset of patients with B cell malignancies, most patients treated will not achieve durable remission. Identification of the mechanisms leading to failure is essential to broadening the efficacy of this promising platform. Several studies have demonstrated that disruption of CD19 genes and transcripts can lead to disease relapse after initial response; however, few other tumor-intrinsic drivers of CAR T cell failure have been reported. Here we identify expression of the Golgi-resident intramembrane protease Signal peptide peptidase-like 3 (SPPL3) in malignant B cells as a potent regulator of resistance to CAR therapy. Loss of SPPL3 results in hyperglycosylation of CD19, an alteration that directly inhibits CAR T cell effector function and suppresses anti-tumor cytotoxicity. Alternatively, over-expression of SPPL3 drives loss of CD19 protein, also enabling resistance. In this pre-clinical model these findings identify post-translational modification of CD19 as a mechanism of antigen escape from CAR T cell therapy.

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Inducing T cell dysfunction by chronic stimulation of CAR-engineered T cells targeting cancer cells in suspension cultures

Selli¹,

Landmann²,

Arveseth³

et al. 2023

STAR Protocols

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M Selli

Cellular origins and genetic landscape of cutaneous gamma delta T cell lymphomas

Costimulatory Domains Direct Distinct Fates of CAR T Cell Dysfunction

Costimulatory domains direct distinct fates of CAR-driven T cell dysfunction

Antigen glycosylation regulates efficacy of CAR T cells targeting CD19

Inducing T cell dysfunction by chronic stimulation of CAR-engineered T cells targeting cancer cells in suspension cultures

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