Rationally designed modular STAT-activating scaffolds enforce cell-intrinsic transcriptional programs augmenting the anti-tumor potency of CAR T cells

Abstract

AbstractChimeric antigen receptor (CAR)-expressing T cells can mediate anti-tumor responses in a variety of preclinical models and clinical settings, however, strategies to enhance anti-tumor potency is the subject of intense investigation. Signals emanating from gamma-c cytokine receptors modulate the transcriptional state of activated T cells impacting proliferation, survival, differentiation, and effector functioning through the STAT family of transcription factors. Design of ligand-independent cell-intrinsic cytokine STAT activation scaffolds is a conceptually attractive strategy to provide CAR T cells with a surrogate for exogenous cytokine support. Here, we designed a series of ligand-autonomous STAT inducer (LASI) scaffolds comprised of an extracellular identification tag, a homodimerizing transmembrane domain, and a membrane proximal IL7R Box1 domain followed by STAT5 and/or STAT3 docking sequences derived from IL7R and IL21R, respectively. We constructed LASI scaffolds having STAT5 (LASI-5), STAT3 (LASI-3), and combined STAT5 and STAT3 (LASI-5+3) docking domains and then interrogated their impact in primary human CD8+anti-CD19 (4-1BB:zeta) CAR T cells. While LASI-5 expression had limited effects on CAR T cells, LASI-3 transcriptional programming was found to be indispensable to achieving anti-tumor functional enhancement associated with limited terminal differentiation, heightened T cell proliferation in response to antigen, and dampened expression of exhaustion-associated genes. Moreover, CAR T cells supplemented with LASI-3 or 5+3 displayed superior potency against human leukemia tumors in NSG mice. LASI-5+3 mediated the highest magnitude of CAR T cell engraftmentin vivothat evolved into a fatal lymphoproliferative syndrome. However, the same efficacy enhancement was achieved with LASI-3 without the lymphoproliferative complication. Our findings provide a rationale for utilization of constitutively expressed LASI-3 to enhance the anti-tumor potency of CAR T cells, the need to regulate the activity of LASI-5+3, and a generalizable scaffold design for studying additional combinations of STAT family transcription factors.