Engineering “physically optimized” T cells for increased sampling of complex tumor microenvironments

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This study examined how to engineer adoptive T cells to better penetrate and sample the dense fibroinflammatory stroma of pancreatic ductal adenocarcinoma, where limited therapy distribution and required T–carcinoma interactions can impair immunotherapy. Using pharmacologic perturbations and mathematical modeling, the authors engineered T cells with constitutively activated RhoA to increase cortical contractility, activation, migration, and sampling, and in CAR T cells observed more efficient targeting with decreased sampling time and increased engagement with carcinoma cells. They report improved tumor infiltration and distribution in vivo and better tumor control, alongside decreased exhaustion markers, though the work is focused on a specific solid tumor context rather than broadly across disease types. This paper does not explicitly discuss endometriosis or adenomyosis; it was included in the corpus via a keyword match in the upstream search index.

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ABSTRACT Pancreatic ductal adenocarcinoma (PDA) remains highly lethal, in part, because its dense fibroinflammatory stroma restricts therapy distribution, including adoptive T cell immunotherapies where direct interactions between T and carcinoma cells are essential for effective therapy. While T cell function must be maintained once effector-target engagement occurs, without inducing co-localization subsequent cytotoxic function steps cannot be undertaken. We therefore developed a strategy to “physically optimize” T cells to more effectively sample complex tumor volumes. Informed by pharmacologic perturbations and mathematical modeling we shifted T cell phenotype through expression of constitutively activated RhoA to increase cortical contractility, activation, migration, and sampling in PDA, while showing decreases in exhaustion markers. In CAR T cells this results in more efficient targeting through decreased sampling time and increased engagement with carcinoma cells, consistent with modeling predictions. This significantly increases T cell infiltration and distribution in PDA, resulting in improved tumor control in vivo, suggesting that this is an effective strategy to overcome stromal constraints, improve tumor engagement, and enhance the therapeutic performance of engineered T cell therapies in solid tumors. Competing Interest Statement Dr. Provenzano declares that he is on the scientific advisory board for Incendia Therapeutics, but that role does not relate to the submitted work

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last seen: 2026-05-20T01:45:00.602351+00:00