Determinants of Response and Resistance to CD19 Chimeric Antigen Receptor (CAR) T Cell Therapy of Chronic Lymphocytic Leukemia

Overview

Journal Nat Med

Specialties General Medicine
Molecular Biology

Date 2018 May 2

PMID 29713085

Citations 833

Authors

Joseph A Fraietta

Simon F Lacey

Elena J Orlando

Iulian Pruteanu-Malinici

Mercy Gohil

Stefan Lundh

Alina C Boesteanu

Yan Wang

Roddy S OConnor

Wei-Ting Hwang

Edward Pequignot

David E Ambrose

Changfeng Zhang

Nicholas Wilcox

Felipe Bedoya

Corin Dorfmeier

Fang Chen

Lifeng Tian

Harit Parakandi

Minnal Gupta

Regina M Young

F Brad Johnson

Irina Kulikovskaya

Li Liu

Jun Xu

Sadik H Kassim

Megan M Davis

Bruce L Levine

Noelle V Frey

Donald L Siegel

Alexander C Huang

E John Wherry

Hans Bitter

Jennifer L Brogdon

David L Porter

Carl H June

J Joseph Melenhorst

Affiliations

Soon will be listed here.

Abstract

Tolerance to self-antigens prevents the elimination of cancer by the immune system. We used synthetic chimeric antigen receptors (CARs) to overcome immunological tolerance and mediate tumor rejection in patients with chronic lymphocytic leukemia (CLL). Remission was induced in a subset of subjects, but most did not respond. Comprehensive assessment of patient-derived CAR T cells to identify mechanisms of therapeutic success and failure has not been explored. We performed genomic, phenotypic and functional evaluations to identify determinants of response. Transcriptomic profiling revealed that CAR T cells from complete-responding patients with CLL were enriched in memory-related genes, including IL-6/STAT3 signatures, whereas T cells from nonresponders upregulated programs involved in effector differentiation, glycolysis, exhaustion and apoptosis. Sustained remission was associated with an elevated frequency of CD27CD45ROCD8 T cells before CAR T cell generation, and these lymphocytes possessed memory-like characteristics. Highly functional CAR T cells from patients produced STAT3-related cytokines, and serum IL-6 correlated with CAR T cell expansion. IL-6/STAT3 blockade diminished CAR T cell proliferation. Furthermore, a mechanistically relevant population of CD27PD-1CD8 CAR T cells expressing high levels of the IL-6 receptor predicts therapeutic response and is responsible for tumor control. These findings uncover new features of CAR T cell biology and underscore the potential of using pretreatment biomarkers of response to advance immunotherapies.

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