Overcoming T cell tolerance to tumor self-antigens through catch-bond engineering
Summary
T cells are often weakly responsive to tumor self-antigens because of central tolerance, constraining their ability to eliminate tumors. We exploited mechanical force to engineer a weakly reactive T cell receptor (TCR) specific for a nonmutated tumor-associated antigen (TAA), prostatic acid phosphatase (PAP). We identified a catch-bonding "hotspot" whose mutation enhanced T cell activity by increasing TCR-pMHC (peptide-major histocompatibility complex) bond lifetime while preserving physio
Content
# Overcoming T cell tolerance to tumor self-antigens through catch-bond engineering
*Published: 2026 Mar 19*
T cells are often weakly responsive to tumor self-antigens because of central
tolerance, constraining their ability to eliminate tumors. We exploited
mechanical force to engineer a weakly reactive T cell receptor (TCR) specific
for a nonmutated tumor-associated antigen (TAA), prostatic acid phosphatase
(PAP). We identified a catch-bonding "hotspot" whose mutation enhanced T cell
activity by increasing TCR-pMHC (peptide-major histocompatibility complex) bond
lifetime while preserving physiological affinities and antigen fine
specificities. T cells expressing these engineered TCRs showed vastly superior
expansion in the tumor, effector phenotypes, and tumor elimination. Crystal
structures and molecular dynamics simulations revealed a single amino acid
mutation at the catch-bond hotspot primes the TCR for peptide interaction
through water reorganization at the TCR-pMHC interface. Catch-bond engineering
is a viable biophysically based strategy for transforming tolerized antitumor T
cells into potent TCR-T cell therapy killers.
DOI: 10.1126/science.adx3162