Redirecting T lymphocyte specificity using T cell receptor genes

IL-2 and Beyond in Cancer Immunotherapy

The development of the T- and natural killer (NK) cell growth factor IL-2 has been a sentinel force ushering in the era of immunotherapy in cancer. With the advent of clinical grade recombinant IL-2 in the mid-1980s, oncologists could for the first time directly manipulate lymphocyte populations with systemic therapy. By itself, recombinant IL-2 can induce clinical responses in up to 15% of patients with metastatic cancer or renal cell carcinoma. When administered with adoptively transferred tumor-reactive lymphocytes, IL-2 promotes T cell engraftment and response rates of up to 50% in metastatic melanoma patients. Importantly, these IL-2-driven responses can yield complete and durable responses in a subset of patients. However, the use of IL-2 is limited by toxicity and concern of the expansion of T regulatory cells. To overcome these limitations and improve response rates, other T cell growth factors, including IL-15 and modified forms of IL-2, are in clinical development. Administering T cell growth factors in combination with other agents, such as immune checkpoint pathway inhibitors, may also improve efficacy. In this study, we review the development of T- and NK cell growth factors and highlight current combinatorial approaches based on these reagents.

Identification of a hepatitis C virus-reactive T cell receptor that does not require CD8 for target cell recognition

Hepatitis C virus (HCV) has been reported to elicit B and T cell immunity in infected patients. Despite the presence of antiviral immunity, many patients develop chronic infections leading to cirrhosis, hepatocellular carcinoma, and liver failure that can require transplantation. We have previously described the presence of HLA-A2-restricted, HCV NS3-reactive cytotoxic T lymphocytes (CTL) in the blood of HLA-A2- liver transplantation patients that received an HLA-A2+ liver allograft. These T cells are analogous to the "allospecific" T cells that have been described in hematopoietic stem cell transplantation patients. It has been speculated that allospecific T cells express high-affinity T cell receptors (TCRs). To determine if our HCV-reactive T cells expressed TCRs with relatively high affinity for antigen, we identified and cloned a TCR from an allospecific HLA-A2-restricted, HCV:NS3:1406-1415-reactive CD8+ T cell clone and expressed this HCV TCR in Jurkat cells. Tetramer binding to HCV TCR-transduced Jurkat cells required CD8 expression, whereas antigen recognition did not. In conclusion, based on the reactivity of the TCR-transduced Jurkat cells, we have identified a TCR that transfers anti-HCV reactivity to alternate effectors. These data suggest this high affinity HCV-specific TCR might have potential new immunotherapic implications.

Differentiation of naive cord-blood T cells into CD19-specific cytolytic effectors for posttransplantation adoptive immunotherapy

Disease relapse is a barrier to achieving therapeutic success after unrelated umbilical cord-blood transplantation (UCBT) for B-lineage acute lymphoblastic leukemia (B-ALL). While adoptive transfer of donor-derived tumor-specific T cells is a conceptually attractive approach to eliminating residual disease after allogeneic hematopoietic stem cell transplantation, adoptive immunotherapy after UCBT is constrained by the difficulty of generating antigen-specific T cells from functionally naive umbilical cord-blood (UCB)-derived T cells. Therefore, to generate T cells that recognize B-ALL, we have developed a chimeric immunoreceptor to redirect the specificity of T cells for CD19, a B-lineage antigen, and expressed this transgene in UCB-derived T cells. An ex vivo process, which is compliant with current good manufacturing practice for T-cell trials, has been developed to genetically modify and numerically expand UCB-derived T cells into CD19-specific effector cells. These are capable of CD19-restricted cytokine production and cytolysis in vitro, as well as mediating regression of CD19+ tumor and being selectively eliminated in vivo. Moreover, time-lapse microscopy of the genetically modified T-cell clones revealed an ability to lyse CD19+ tumor cells specifically and repetitively. These data provide the rationale for infusing UCB-derived CD19-specific T cells after UCBT to reduce the incidence of CD19+ B-ALL relapse.

Breaking tolerance in cancer immunotherapy: time to ACT

The discovery of defined tumor antigens and their application in therapeutic cancer vaccines has not yet resulted in a successful therapy for cancer patients. Recent data suggest that this might be because most current clinical immunotherapeutic strategies rely on a tolerized tumor-reactive T-cell repertoire, resulting in a weak T-cell response that cannot induce tumor regression in the face of a multitude of normal and tumor-induced immunoregulatory mechanisms. New insights from animal models and clinical trials suggest a rationale for combination approaches in which the ineffective endogenous anti-tumor immune response is enhanced through a combination of adoptive cell transfer (ACT), specific vaccination and cytokine help for the reliable induction of a robust anti-tumor immune response and tumor regression.

Retroviral transduction of peptide stimulated t cells can generate dual t cell receptor-expressing (bifunctional) t cells reactive with two defined antigens

BACKGROUND: Tumors and viruses have developed many mechanisms to evade the immune system, including down-regulation of target antigens and MHC molecules. These immune escape mechanisms may be able to be circumvented by adoptively transferring T cells engineered to express two different T cell receptors, each specific for a different antigen or MHC restriction molecule. METHODS: PBMC from the blood of normal healthy donors were stimulated for three days with an antigenic peptide from cytomegalovirus (CMV) pp65. These CMV reactive cultures were transduced with a encoding the TIL 5 T cell receptor (TCR) that mediates recognition of the dominant epitope of the melanoma antigen MART-1. Following selection for transduced cells, the cultures were evaluated for recognition of CMV pp65 and MART-1 expressing targets. RESULTS: We were able to rapidly create bifunctional T cells capable of recognizing both CMV pp65 and MART-1 using a combination of HLA-A2 tetramer staining and intracellular staining for interferon-gamma. These bifunctional T cells were sensitive to very low levels of antigen, recognize MART-1+ tumor cells, and maintained their bifunctionality for over 40 days in culture. CONCLUSION: Bifunctional T cells can be engineered by transducing short term peptide stimulated T cell cultures. These bifunctional T cells may be more effective in treating patients with cancer or chronic virus infections because they would reduce the possibility of disease progression due to antigen and/or MHC loss variants.