Systematic Engineering of TROP2-Targeted CAR T-Cell Therapy Overcomes Resistance Pathways in Solid Tumors

Elliott J. Brea(Dana-Farber Cancer Institute), Simon Baldacci(Dana-Farber Cancer Institute), Neil Savage(Dana-Farber Cancer Institute), Francesco Facchinetti(Dana-Farber Cancer Institute), Conor Hinchey(Dana-Farber Cancer Institute), Sachiv Chakravarti(Dana-Farber Cancer Institute), Alexis Mottram(Dana-Farber Cancer Institute), Kenneth Ngo(Dana-Farber Cancer Institute), Ha Vo(Dana-Farber Cancer Institute), Brittaney A. Leeper(Dana-Farber Cancer Institute), Bishma Tuladhar(Dana-Farber Cancer Institute), Suthakar Ganapathy(Dana-Farber Cancer Institute), Elena V. Ivanova(Dana-Farber Cancer Institute), Aisha Saldanha(Dana-Farber Cancer Institute), Marie-Anaïs Locquet(Dana-Farber Cancer Institute), Abdulmajeed Salamah(Dana-Farber Cancer Institute), Malcolm Holterhus(Dana-Farber Cancer Institute), Evelyn B. Mesler(Dana-Farber Cancer Institute), Martina De Vizio(Dana-Farber Cancer Institute), Carla Stornante(Dana-Farber Cancer Institute), Marco Campisi(Dana-Farber Cancer Institute), Navin R. Mahadevan(Brigham and Women's Hospital), Tran C. Thai(Dana-Farber Cancer Institute), Timothy J. Haggerty(Dana-Farber Cancer Institute), Zehua Li(Dana-Farber Cancer Institute), Cui Nie(Combat Capabilities Development Command Soldier Center), Changjing Deng(Combat Capabilities Development Command Soldier Center), Xiaoxiao Wang(Combat Capabilities Development Command Soldier Center), Louis L. Liu(Combat Capabilities Development Command Soldier Center), Thanh U. Barbie(Dana-Farber Cancer Institute), Prafulla C. Gokhale(Dana-Farber Cancer Institute), Cloud P. Paweletz(Dana-Farber Cancer Institute), Anusuya Ramasubramanian(Dana-Farber Cancer Institute), Pasi A. Jänne(Dana-Farber Cancer Institute), David A. Barbie(Dana-Farber Cancer Institute), Eric L. Smith(Harvard University)
Cancer Immunology Research
September 8, 2025
10.1158/2326-6066.cir-25-0527
Cited by 1Open Access
Full Text

Abstract

Antibody-based therapies have revolutionized cancer treatment but have several limitations. These include downregulation of the target antigen, mutation of the target epitope, and, in the case of antibody-drug conjugates (ADC), resistance to the chemotherapy warhead. As TROP2-targeted therapy with ADCs yields responses in TROP2+ solid tumors, but the responses lack the durability observed with other immunotherapy-based approaches, we developed TROP2-targeting chimeric antigen receptor (CAR) T cells as an alternative. The TROP2-directed CAR T cells showed high potency against multiple solid tumor models. Moreover, TROP2-directed CAR T-cell therapy preserved high potency in models of ADC resistance and could be further engineered to prevent cell therapy resistance. This was achieved by leveraging fully human single-domain (VH-only) binder discovery to rationally engineer dual epitope binding-based (biparatopic) CARs. This work highlights the potency of CAR T-cell therapies and how rational engineering leveraging dual-VH targeting domains can overcome resistance pathways to current therapies. In future work, the CAR engineering approaches presented here can serve as a platform to be partnered with other strategies to address the suppressive tumor microenvironment.

Related Papers

No related papers found

Powered by citation graph analysis