Chimeric Antigen Receptors Transmit Co-stimulatory Domain Dependent Piconewton Forces to their Target

  1. Hemakshi J. Mishra
  2. Lauren Mahoney
  3. Dominique R. Smith
  4. Luke Kalcheim
  5. Kartikey Kansal
  6. Nat Murren
  7. Myrna Chang
  8. Rebecca M. Richards
  9. Joshua M. Brockman
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Abstract

Chimeric antigen receptor (CAR) T cells promote tumor-specific cytotoxicity through engagement of a recombinant, synthetic receptor with target ligands expressed on cancer cells. Native T cells are mechanically active, both transmitting and sensing forces exceeding 19 piconewtons (pN) via transmembrane receptors, including the T cell receptor (TCR). Emerging evidence implicates mechanoactivity in CAR T cell biology, but CAR-transmitted T cell forces have not been directly measured. Here, we utilize DNA-based molecular tension probes (MTPs) conjugated to CAR target ligands, providing evidence of actin-polymerization dependent forces exceeding 4.7-19 pN borne by the CAR. We demonstrate force transmission by three clinically relevant CARs (CD123, CD33, and CD19), suggesting that these forces are generalizable across CAR targets and constructs. Additionally, we identify intracellular co-stimulatory domains as the main determinants of CAR-mediated forces, because first-generation CARs lacking co-stimulatory domains do not transmit measurable forces to their ligand. Finally, we demonstrate that CAR forces temporally precede Ca 2+ signaling and are spatially correlated with phosphorylation of classical TCR-signaling machinery, indicating a link between CAR T cell forces and early biochemical signaling. Our study introduces CAR-mediated mechanobiology as a key correlate of early CAR T cell activation events.

Significance Statement

Chimeric antigen receptor (CAR) T cell therapies have revolutionized treatment for several hematological malignancies. CARs are recombinant receptors containing domains derived from the T cell receptor complex machinery and other co-stimulatory proteins. Mechanical forces are believed to be important in T cell activation and antigen recognition. The role of mechanobiology in CAR T cell immunotherapy remains poorly understood. Here, using DNA-based molecular tension probes conjugated to CAR ligands, we provide direct evidence that CARs bear actin polymerization–dependent piconewton forces during antigen engagement that precede early signaling events. These forces depend on CAR co-stimulatory domains, and first-generation CARs lacking these domains fail to transmit detectable force. These findings suggest mechanobiology may be a key, tunable parameter for next-generation CAR T cells.

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