William R. Burns

Both CD4 and CD8 T Cells Mediate Equally Effective In Vivo Tumor Treatment When Engineered with a Highly Avid TCR Targeting Tyrosinase

Tyrosinase, an enzyme involved in melanin synthesis, is expressed in nearly all primary and metastatic melanoma lesions and thus is an attractive target for TCR-based gene therapy using adoptive cell transfer. The TCR α- and β-chain genes from a tumor-infiltrating lymphocyte, which recognized the tyrosinase 368–376 peptide in the context of HLA-A2, were cloned into a γ-retroviral vector. Following transduction of PBL, specific reactivity was confirmed by cytokine production following coculture with tumor targets. Experiments using Ab blockade and CD4/CD8 sorting of the transduced PBLs demonstrated that this antityrosinase TCR was CD4/CD8 independent. The introduction of a second disulfide bond between the TCR constant regions and/or creation of a chimeric protein in which the human constant regions were replaced by murine homologs resulted in enhanced TCR expression as demonstrated by tetramer staining and improved tumor reactivity that was comparable to PBL transduced with either anti-melanoma Ag recognized by T cells-1 or anti-gp100 TCR vectors currently used in clinical trials. The chimeric TCR also allowed us to test antitumor function of in HLA-A2/Kb–transgenic mice. Transfer of the antityrosinase TCR into mouse splenocytes conferred CD4/CD8-independent, HLA-A2–restricted Ag reactivity against B16/A2Kb murine melanoma in vitro. Furthermore, adoptive transfer of transduced splenocytes mediated B16/A2Kb melanoma tumor regression in lymphodepleted mice, and, surprisingly, both CD8 and CD4 T cells were equally effective in mediating tumor regression. These results suggest that this highly active tyrosinase-specific TCR could be of value in adoptive cell transfer for melanoma.

A High Molecular Weight Melanoma-Associated Antigen–Specific Chimeric Antigen Receptor Redirects Lymphocytes to Target Human Melanomas

Immunotherapy, particularly the adoptive cell transfer (ACT) of tumor-infiltrating lymphocytes (TIL), is a very promising therapy for metastatic melanoma. Some patients unable to receive TIL have been successfully treated with autologous peripheral blood lymphocytes (PBL), genetically modified to express human leukocyte antigen (HLA) class I antigen-restricted, melanoma antigen-reactive T-cell receptors; however, substantial numbers of patients remain ineligible due to the lack of expression of the restricting HLA class I allele. We sought to overcome this limitation by designing a non-MHC-restricted, chimeric antigen receptor (CAR) targeting the high molecular weight melanoma-associated antigen (HMW-MAA), which is highly expressed on more than 90% of human melanomas but has a restricted distribution in normal tissues. HMW-MAA-specific CARs containing an antigen recognition domain based on variations of the HMW-MAA-specific monoclonal antibody 225.28S and a T-cell activation domain based on combinations of CD28, 4-1BB, and CD3zeta activation motifs were constructed within a retroviral vector to allow stable gene transfer into cells and their progeny. Following optimization of the HMW-MAA-specific CAR for expression and function in human PBL, these gene-modified T cells secreted cytokines, were cytolytic, and proliferated in response to HMW-MAA-expressing cell lines. Furthermore, the receptor functioned in both CD4(+) and CD8(+) cells, was non-MHC restricted, and reacted against explanted human melanomas. To evaluate this HMW-MAA-specific CAR in patients with metastatic melanoma, we developed a clinical-grade retroviral packaging line. This may represent a novel means to treat the majority of patients with advanced melanoma, most notably those unable to receive current ACT therapies.

Lack of specific γ-retroviral vector long terminal repeat promoter silencing in patients receiving genetically engineered lymphocytes and activation upon lymphocyte restimulation

Retroviral transduction of tumor antigen-specific T-cell receptor (TCR) genes into lymphocytes redirects T cells to lyse tumors. Furthermore, adoptive transfer of these lymphocytes has mediated objective responses in patients with metastatic cancer. From 2004 to 2006, more than 40 patients were treated with autologous gene-modified lymphocytes expressing a melanoma antigen-specific TCR at the National Cancer Institute. Eighteen such patients were analyzed for persistence and gene expression in vivo. In addition, the impact of epigenetic silencing and of lymphocyte restimulation was studied. Although gene-modified lymphocytes persisted in vivo, the shutdown of TCR transgene expression was observed. Bisulfite sequencing analysis and ex vivo DNA methyltransferase inhibition demonstrated that the decrease in gene expression did not result from DNA methylation. Surprisingly, down-regulation of vector-driven transgene transcriptional activity was not vector specific but mimicked that of endogenous genes. The decrease in TCR transgene expression, however, was reversed upon lymphocyte stimulation. These data demonstrate a lack of gamma-retroviral promoter-specific gene silencing in adoptively transferred human lymphocytes and support that transgene expression is largely affected by global cellular mechanisms. The use of immunomodulatory adjuvants, eg, vaccination or cytokine therapy, for in vivo T-cell activation may help overcome this metabolic quiescence and thus augment cellular immunotherapy-based cancer therapy.

A Novel Chimeric Antigen Receptor Against Prostate Stem Cell Antigen Mediates Tumor Destruction in a Humanized Mouse Model of Pancreatic Cancer

Despite advances in the understanding of its molecular pathophysiology, pancreatic cancer remains largely incurable, highlighting the need for novel therapies. We developed a chimeric antigen receptor (CAR) specific for prostate stem cell antigen (PSCA), a glycoprotein that is overexpressed in pancreatic cancer starting at early stages of malignant transformation. To optimize the CAR design, we used antigen-recognition domains derived from mouse or human antibodies, and intracellular signaling domains containing one or two T cell costimulatory elements, in addition to CD3zeta. Comparing multiple constructs established that the CAR based on human monoclonal antibody Ha1-4.117 had the greatest reactivity in vitro. To further analyze this CAR, we developed a human pancreatic cancer xenograft model and adoptively transferred CAR-engineered T cells into animals with established tumors. CAR-engineered human lymphocytes induced significant antitumor activity, and unlike what has been described for other CARs, a second-generation CAR (containing CD28 cosignaling domain) induced a more potent antitumor effect than a third-generation CAR (containing CD28 and 41BB cosignaling domains). While our results provide evidence to support PSCA as a target antigen for CAR-based immunotherapy of pancreatic cancer, the expression of PSCA on selected normal tissues could be a source of limiting toxicity.

Multiple chimeric antigen receptors successfully target chondroitin sulfate proteoglycan 4 in several different cancer histologies and cancer stem cells

BackgroundThe development of immunotherapy has led to significant progress in the treatment of metastatic cancer, including the development of genetic engineering technologies that redirect lymphocytes to recognize and target a wide variety of tumor antigens. Chimeric antigen receptors (CARs) are hybrid proteins combining antibody recognition domains linked to T cell signaling elements. Clinical trials of CAR-transduced peripheral blood lymphocytes (PBL) have induced remission of both solid organ and hematologic malignancies. Chondroitin sulfate proteoglycan 4 (CSPG4) is a promising target antigen that is overexpressed in multiple cancer histologies including melanoma, triple-negative breast cancer, glioblastoma, mesothelioma and sarcoma.MethodsCSPG4 expression in cancer cell lines was assayed using flow cytometry (FACS) and reverse-transcription PCR (RT-PCR). Immunohistochemistry was utilized to assay resected melanomas and normal human tissues (n = 30) for CSPG4 expression and a reverse-phase protein array comprising 94 normal tissue samples was also interrogated for CSPG4 expression. CARs were successfully constructed from multiple murine antibodies (225.28S, TP41.2, 149.53) using second generation (CD28.CD3ζ) signaling domains. CAR sequences were cloned into a gamma-retroviral vector with subsequent successful production of retroviral supernatant and PBL transduction. CAR efficacy was assayed by cytokine release and cytolysis following coculture with target cell lines. Additionally, glioblastoma stem cells were generated from resected human tumors, and CSPG4 expression was determined by RT-PCR and FACS.ResultsImmunohistochemistry demonstrated prominent CSPG4 expression in melanoma tumors, but failed to demonstrate expression in any of the 30 normal human tissues studied. Two of 94 normal tissue protein lysates were positive by protein array. CAR constructs demonstrated cytokine secretion and cytolytic function after co-culture with tumor cell lines from multiple different histologies, including melanoma, breast cancer, mesothelioma, glioblastoma and osteosarcoma. Furthermore, we report for the first time that CSPG4 is expressed on glioblastoma cancer stem cells (GSC) and demonstrate that anti-CSPG4 CAR-transduced T cells recognize and kill these GSC.ConclusionsThe functionality of multiple different CARs, with the widespread expression of CSPG4 on multiple malignancies, suggests that CSPG4 may be an attractive candidate tumor antigen for CAR-based immunotherapies using appropriate technology to limit possible off-tumor toxicity.

Identification and characterization of a tumor infiltrating CD56+/CD16- NK cell subset with specificity for pancreatic and prostate cancer cell lines

In a recent clinical trial, a patient exhibited regression of several pancreatic cancer metastases following the administration of the immune modulator Ipilimumab (anti-CTLA-4 antibody). We sought to characterize the immune cells responsible for this regression. Tumor infiltrating lymphocytes (TIL-2742) and an autologous tumor line (TC-2742) were expanded from a regressing metastatic lesion excised from this patient. Natural killer (NK) cells predominated in the TIL (92% CD56+) with few T cells (12% CD3+). A majority (88%) of the NK cells were CD56brightCD16−. TIL-2742 secreted IFN-γ and GM-CSF following co-culture with TC-2742 and major histocompatibility complex mismatched pancreatic tumor lines. After sorting TIL-2742, the purified CD56+CD16−CD3− subset showed reactivity similar to TIL-2742 while the CD56−CD16−CD3+ cells exhibited no tumor recognition. In co-culture assays, TIL-2742 and the NK subset expressed high reactivity to several pancreatic and prostate cancer cell lines and could lyse the autologous tumor as well as pancreas and prostate cancer lines. Reactivity was partially abrogated by blockade of TRAIL. We thus identified a unique subset of NK cells (CD56brightCD16dim) isolated from a regressing metastatic pancreatic cancer in a patient responding to Ipilimumab. This represents the first report of CD56+CD16− NK cells with apparent specificity for pancreatic and prostate cancer cell lines and associated with tumor regression following the treatment with an immune modulating agent.

The position of the AUG start codon in MFG-based γ-retroviral vectors has a dramatic effect on translation-dependent protein expression

In the past three decades, much advancement has been made in γ‐retroviral vector mediated gene transfer. One widely used vector design is based on the MFG vector, which uses the Moloney murine leukemia virus (MoMLV) transcriptional unit with extended packaging signals and insertion of the native MoMLV envelope splice acceptor region immediate 5′ to the gene of interest inserted at an NcoI restriction site, which contains a translation start codon. Little is known about the impact of variations in start codon location within MFG‐based vectors on protein expression.