Tyler J. Reich

Chimeric antigen receptor (CAR) T cells have induced remarkable antitumor responses in B cell malignancies. Some patients do not respond because of T cell deficiencies that hamper the expansion, persistence, and effector function of these cells. We used longitudinal immune profiling to identify phenotypic and pharmacodynamic changes in CD19-directed CAR T cells in patients with chronic lymphocytic leukemia (CLL). CAR expression maintenance was also investigated because this can affect response durability. CAR T cell failure was accompanied by preexisting T cell-intrinsic defects or dysfunction acquired after infusion. In a small subset of patients, CAR silencing was observed coincident with leukemia relapse. Using a small molecule inhibitor, we demonstrated that the bromodomain and extra-terminal (BET) family of chromatin adapters plays a role in downregulating CAR expression. BET protein blockade also ameliorated CAR T cell exhaustion as manifested by inhibitory receptor reduction, enhanced metabolic fitness, increased proliferative capacity, and enriched transcriptomic signatures of T cell reinvigoration. BET inhibition decreased levels of the TET2 methylcytosine dioxygenase, and forced expression of the TET2 catalytic domain eliminated the potency-enhancing effects of BET protein targeting in CAR T cells, providing a mechanism linking BET proteins and T cell dysfunction. Thus, modulating BET epigenetic readers may improve the efficacy of cell-based immunotherapies.

Abstract T cells bearing a second-generation anti-CD19 chimeric antigen receptor (CAR) induce complete remission in >90% of patients with acute lymphoblastic leukemia (ALL) at our institution. However, disease may recur and we recently identified two molecular mechanisms of relapse (PMID: 26516065). We here present a novel mechanism of antigen-negative relapse in a pediatric ALL patient. A 21 year-old male patient was in third relapse at the time of enrollment onto our CTL019 trial (ClinicalTrials.Gov #NCT01626495). The patient achieved an MRD-negative complete remission 1 month after CTL019 infusion but relapsed nine months later. Quantitative PCR analysis of the transgene and flow cytometry for CAR19 protein analysis showed the expected expansion of the CART cells followed by log-normal decay following disease eradication. At relapse, however, the transgene copy numbers had increased without a concomitant rise in CAR19 protein-expressing T cells. The CAR protein was found to be expressed by the now CD19-negative CD45dimCD10+CD3negCD22+ leukemia. Molecular analysis via next-generation immunoglobulin heavy chain sequencing (NGIS) of the apheresis product, used for CTL019 manufacturing, and relapse marrow at 9 months demonstrated clonal identity of the relapsed clone, which carried two rearranged IgH alleles. Sequencing of the CD19, CD21, CD81, and CD225 loci did not reveal any mutations. The analysis of lentiviral vector integration sites (LVIS) of the infusion product and post-infusion specimens showed the following: a) the infusion product carried over 15,000 unique integration sites; b) only 7 LVIS were shared between this sample and month 9 and 20 relapse specimens, none of which were near proto-oncogenes; c) the relapsed leukemia carried two LVIS, one on chromosome 10, >50 kb distal from neuropilin (NRP1) and the second in an intron of proprionyl coenzyme A carboxylase-A (PCCA). Flow cytometric and qRT-PCR analysis of leukemic cells in the apheresis and relapse showed that NRP1 levels were indistinguishable, suggesting that the lentiviral vector did not act as an enhancer for NRP1. Furthermore, qRT-PCR demonstrated that the lentiviral integration did not affect the gene expression levels of PCCA. Investigation into the origins of the leukemic CAR transduction event showed that the patient did not exhibit replication-competent lentivirus. However, NGIS analysis of infusion product revealed the leukemic clonotypes this sample, indicating that the gene transfer occurred during the manufacturing of the CTL019 cells. A retrospective analysis of 115 aphereses from ALL patients showed that the index patient had an unusually high disease burden in the apheresis product with 63% of all cells expressing CD19; at harvest, however, the CTL019 product consisted of 99.21% T cells, highlighting the purging effect of the CD19-specific T cells during manufacturing. NGIS analysis of infusion products of 17 additional ALL patients also identified the leukemic clonotype(s) in 6 more products. Only one additional patient demonstrated CAR19 protein expression on the leukemic cells, and this clone was not dominant at relapse (0.075% of all leukemic cells expressed the CAR). Our investigation into the biology of CAR19-expressing ALL cells showed the following: 1) the in vitro analysis of BBζ-signaling CAR19 showed no evidence of cytokine secretion; 2) the infusion of the baseline leukemia and CAR19-expressing leukemic cells from the same patient in mice did not demonstrate differential pharmacodynamics, even after restimulation with human CD19-expressing murine B cells in vivo; 3) the CD19 protein was detectable using flow cytometry and confocal microscopy, but only with an antibody recognizing an intracellular epitope; 4) importantly, the relapsed clone was indeed resistant to killing by CART19 cells in a xenograft model yet retained sensitivity to anti-CD22 CAR T cells. In conclusion, our data therefore show that a single leukemic cell accidentally transduced with CAR19 survived the 10-day manufacturing process and, upon reinfusion into the patient, was the sole clone at relapse 9 months later. This leukemic clone evaded CTL019 detection via downregulation of the target antigen in a cell-autonomous fashion. Disclosures Lacey: Novartis: Research Funding. Xu:Novartis: Research Funding. Ruella:novartis: Patents & Royalties: Novartis, Research Funding. Barrett:Novartis: Research Funding. Kulikovskaya:Novartis: Research Funding. Ambrose:Novartis: Research Funding. Patel:Novartis: Research Funding. Reich:Novartis: Research Funding. Scholler:Novartis: Patents & Royalties: Royalties, Research Funding. Nazimuddin:Novartis: Research Funding. Fraietta:Novartis: Patents & Royalties: Novartis, Research Funding. Maude:Novartis: Consultancy. Gill:Novartis: Patents & Royalties, Research Funding. Levine:Novartis: Patents & Royalties, Research Funding; GE Healthcare Bio-Sciences: Consultancy. Orlando:Novartis: Employment. Grupp:Jazz Pharmaceuticals: Consultancy; Pfizer: Consultancy; Novartis: Consultancy, Research Funding. June:Tmunity: Equity Ownership, Other: Founder, stockholder ; Pfizer: Honoraria; Immune Design: Consultancy, Equity Ownership; Celldex: Consultancy, Equity Ownership; University of Pennsylvania: Patents & Royalties; Johnson & Johnson: Research Funding; Novartis: Honoraria, Patents & Royalties: Immunology, Research Funding. Melenhorst:Novartis: Patents & Royalties: Novartis, Research Funding.

Mammalian cells are thought to protect themselves and their host organisms from DNA double strand breaks (DSBs) through universal mechanisms that restrain cellular proliferation until DNA is repaired. The Cyclin D3 protein drives G1-to-S cell cycle progression and is required for proliferation of immature T and B cells and of mature B cells during a T cell-dependent immune response. We demonstrate that mouse thymocytes and pre-B cells, but not mature B cells, repress Cyclin D3 protein levels in response to DSBs. This response requires the ATM protein kinase that is activated by DSBs. Cyclin D3 protein loss in thymocytes coincides with decreased association of Cyclin D3 mRNA with the HuR RNA binding protein that ATM regulates. HuR inactivation reduces basal Cyclin D3 protein levels without affecting Cyclin D3 mRNA levels, indicating that thymocytes repress Cyclin D3 expression via ATM-dependent inhibition of Cyclin D3 mRNA translation. In contrast, ATM-dependent transcriptional repression of the Cyclin D3 gene represses Cyclin D3 protein levels in pre-B cells. Retrovirus-driven Cyclin D3 expression is resistant to transcriptional repression by DSBs; this prevents pre-B cells from suppressing Cyclin D3 protein levels and from inhibiting DNA synthesis to the normal extent following DSBs. Our data indicate that immature B and T cells use lymphocyte lineage- and developmental stage-specific mechanisms to inhibit Cyclin D3 protein levels and thereby help prevent cellular proliferation in response to DSBs. We discuss the relevance of these cellular context-dependent DSB response mechanisms in restraining proliferation, maintaining genomic integrity, and suppressing malignant transformation of lymphocytes.