Tumor-infiltrating lymphocytes genetically engineered with an inducible gene encoding interleukin-12 for the immunotherapy of metastatic melanoma.

PURPOSE: Infusion of interleukin-12 (IL12) can mediate antitumor immunity in animal models, yet its systemic administration to patients with cancer results in minimal efficacy and severe toxicity. Here, we evaluated the antitumor activity of adoptively transferred human tumor-infiltrating lymphocytes (TILs) genetically engineered to secrete single-chain IL12 selectively at the tumor site. EXPERIMENTAL DESIGN: Thirty-three patients with metastatic melanoma were treated in a cell dose-escalation trial of autologous TILs transduced with a gene encoding a single-chain IL12 driven by a nuclear factor of the activated T cells promoter (NFAT.IL12). No IL2 was administered. RESULTS: The administration of 0.001 to 0.1 × 10(9) NFAT.IL12-transduced TILs to 17 patients resulted in a single, objective response (5.9%). However, at doses between 0.3 and 3 × 10(9) cells, 10 of 16 patients (63%) exhibited objective clinical responses. The responses tended to be short, and the administered IL12-producing cells rarely persisted at 1 month. Increasing cell doses were associated with high serum levels of IL12 and IFNγ as well as clinical toxicities, including liver dysfunction, high fevers, and sporadic life-threatening hemodynamic instability. CONCLUSIONS: In this first-in-man trial, administration of TILs transduced with an inducible IL12 gene mediated tumor responses in the absence of IL2 administration using cell doses 10- to 100-fold lower than conventional TILs. However, due to toxicities, likely attributable to the secreted IL12, further refinement will be necessary before this approach can be safely used in the treatment of cancer patients.

Evaluation of γ-retroviral vectors that mediate the inducible expression of IL-12 for clinical application.

The clinical application of interleukin-12 (IL-12) has been hindered by the toxicity associated with its systemic administration. To potentially overcome this problem, we developed a promoter designed to direct IL-12 expression within the tumor environment using an inducible composite promoter containing binding motifs for the nuclear factor of activated T cells (NFAT) linked to a minimal IL-2 promoter. In this study, the NFAT promoter was coupled to a single-chain human IL-12 gene and inserted into 2 γ-retroviral self-inactivating vectors (SERS.NFAT.hIL12 and SERS.NFAT.hIL12.PA2) and 1 γ-retroviral vector (MSGV1.NFAT.hIL.12 PA2). Peripheral blood lymphocytes (PBLs) were double transduced with an antigen-specific T-cell receptor and the 3 NFAT.hIL12 vectors. Evaluation of inducible IL-12 expression, transduction efficiency, and vector production considerations led to the choice of the MSGV1.NFAT.hIL12.PA2 vector for clinical application. MSGV1.NFAT.hIL12.PA2 PG13 retroviral vector producer cell clones were screened by transduction of tumor antigen-specific PBLs. On the basis of expression studies in PBL, clone D3 was chosen to produce clinical-grade viral vector supernatant and was demonstrated to efficiently transduce young tumor-infiltrating lymphocytes (TIL). The vector-transduced young TIL with known tumor recognition demonstrated specific inducible IL-12 production after coculture with HLA-matched tumor targets and had augmented effector function as demonstrated by increased IFN-γ secretion. These results support the clinical application of adoptive transfer of young TIL engineered with the NFAT.hIL12 vector as a new approach for cancer immunotherapy.

Tumor regression in patients with metastatic synovial cell sarcoma and melanoma using genetically engineered lymphocytes reactive with NY-ESO-1.

PURPOSE: Adoptive immunotherapy using tumor-infiltrating lymphocytes represents an effective cancer treatment for patients with metastatic melanoma. The NY-ESO-1 cancer/testis antigen, which is expressed in 80% of patients with synovial cell sarcoma and approximately 25% of patients with melanoma and common epithelial tumors, represents an attractive target for immune-based therapies. The current trial was carried out to evaluate the ability of adoptively transferred autologous T cells transduced with a T-cell receptor (TCR) directed against NY-ESO-1 to mediate tumor regression in patients with metastatic melanoma and synovial cell sarcoma. PATIENTS AND METHODS: A clinical trial was performed in patients with metastatic melanoma or metastatic synovial cell sarcoma refractory to all standard treatments. Patients with NY-ESO-1-positive tumors were treated with autologous TCR-transduced T cells plus 720,000 iU/kg of interleukin-2 to tolerance after preparative chemotherapy. Objective clinical responses were evaluated using Response Evaluation Criteria in Solid Tumors (RECIST). RESULTS: Objective clinical responses were observed in four of six patients with synovial cell sarcoma and five of 11 patients with melanoma bearing tumors expressing NY-ESO-1. Two of 11 patients with melanoma demonstrated complete regressions that persisted after 1 year. A partial response lasting 18 months was observed in one patient with synovial cell sarcoma. CONCLUSION: These observations indicate that TCR-based gene therapies directed against NY-ESO-1 represent a new and effective therapeutic approach for patients with melanoma and synovial cell sarcoma. To our knowledge, this represents the first demonstration of the successful treatment of a nonmelanoma tumor using TCR-transduced T cells.

Relationship of p53 overexpression on cancers and recognition by anti-p53 T cell receptor-transduced T cells.

Tumor suppressor p53 is reported to be an attractive immunotherapy target because it is mutated in approximately half of human cancers, resulting in inactivation and often an accumulation of the protein in the tumor cells. Only low amounts of protein are detectable in normal tissues. The differential display of antigen in normal versus tumor tissues has been reported to create an opportunity to target p53 by immunotherapy. We sought to determine the relationship between p53 expression and its recognition by cognate T cells in human tumors including common epithelial malignancies. Inasmuch as nonsense or missense p53 mutations may disrupt processing and presentation, we studied tumors with either identified wild-type or mutated p53, based on our gene-sequencing studies or published data. T cells transduced with a high-affinity, p53(264-272)-reactive T cell receptor (TCR) derived from HLA-A2.1 transgenic mice recognized a wide panel of human tumor lines. There was no significant correlation between p53 expression in tumors and recognition by the anti-p53 TCR-transduced T cells. This conclusion was based on the study of 48 cell lines and is in contrast to several prior studies that used only a limited number of selected cell lines. A panel of normal cells was evaluated for recognition, and some of these populations were capable of stimulating anti-p53 T cells, albeit at low levels. These studies raise doubts concerning the suitability of targeting p53 in the immunotherapy of cancer patients.