John Copier

Overview of tumor cell-based vaccines.

Whole-cell tumor vaccines have been investigated for more than 20 years for their efficacy in both preclinical models and in clinical trials in humans. There are clear advantages of whole-cell/polyepitope vaccination over those types of immunotherapy that target specific epitopes. Multiple and unknown antigens may be targeted to both the innate and adaptive immune system, and this may be further augmented by genetic modification of the vaccine cells to provide cytokines and costimulation. In this review, we give an overview of the field including the preclinical and clinical advances using unmodified and modified tumor-cell vaccines.

Mycobacteria activate γδ T-cell anti-tumour responses via cytokines from type 1 myeloid dendritic cells: a mechanism of action for cancer immunotherapy

Attenuated and heat-killed mycobacteria display demonstrable activity against cancer in the clinic; however, the induced immune response is poorly characterised and potential biomarkers of response ill-defined. We investigated whether three mycobacterial preparations currently used in the clinic (BCG and heat-killed Mycobacterium vaccae and Mycobacterium obuense) can stimulate anti-tumour effector responses in human γδ T-cells. γδ T-cell responses were characterised by measuring cytokine production, expression of granzyme B and cytotoxicity against tumour target cells. Results show that γδ T-cells are activated by these mycobacterial preparations, as indicated by upregulation of activation marker expression and proliferation. Activated γδ T-cells display enhanced effector responses, as shown by upregulated granzyme B expression, production of the TH1 cytokines IFN-γ and TNF-α, and enhanced degranulation in response to susceptible and zoledronic acid-treated resistant tumour cells. Moreover, γδ T-cell activation is induced by IL-12, IL-1β and TNF-α from circulating type 1 myeloid dendritic cells (DCs), but not from type 2 myeloid DCs or plasmacytoid DCs. Taken together, we show that BCG, M. vaccae and M. obuense induce γδ T-cell anti-tumour effector responses indirectly via a specific subset of circulating DCs and suggest a mechanism for the potential immunotherapeutic effects of BCG, M. vaccae and M. obuense in cancer.

Current status and future applications of cellular therapies for cancer

Therapies based on the use of autologous immune cells are among the best candidates for cancer immunotherapy. Dendritic cell vaccines have demonstrated very encouraging responses for some solid tumors, while in melanoma autologous T-cell therapies have exceeded 70% objective response rates in selected Phase I trials. However, it is clear that a number of barriers exist to the effective, practical application of these therapies. The aim of this article is to consider modifications to such strategies over the last 3 years and the resultant clinical research in autologous dendritic cell vaccines, T-cell therapy and γδ T-cell therapy for cancer.

Biomarkers for the development of cancer vaccines: current status.

Significant improvements in our knowledge of tumor immunology have resulted in more sophisticated vaccine approaches for the treatment of cancer. However, research into biomarkers that correlate with the clinical outcome of immunotherapy has lagged behind vaccine development. To this extent, very few immunological or other markers exist that can be used in clinical trials for immunotherapy. In this review, we discuss the current status of biomarker development specifically for the monitoring and development of cancer vaccines. This includes immunological biomarkers (measurement of T-cell and cytokine responses), autoimmunity as a correlate for treatment outcome, and the possible development of multiple biomarkers using high-throughput proteomics technologies. The generation of such biomarkers will allow us to make clinical decisions about patient treatment at an earlier stage and should aid in shortening the development time for vaccines.

Zoledronic acid causes γδ T cells to target monocytes and down-modulate inflammatory homing.

Zoledronic acid (ZA) is a potential immunotherapy for cancer because it can induce potent γδ T‐cell‐mediated anti‐tumour responses. Clinical trials are testing the efficacy of intravenous ZA in cancer patients; however, the effects of systemic ZA on the activation and migration of peripheral γδ T cells remain poorly understood. We found that γδ T cells within ZA‐treated peripheral blood mononuclear cells were degranulating, as shown by up‐regulated expression of CD107a/b. Degranulation was monocyte dependent because CD107a/b expression was markedly reduced in the absence of CD14+ cells. Consistent with monocyte‐induced degranulation, we observed γδ T‐cell‐dependent induction of monocyte apoptosis, as shown by phosphatidylserine expression on monocytes and decreased percentages of monocytes in culture. Despite the prevailing paradigm that ZA promotes tumour homing in γδ T cells, we observed down‐modulation of their tumour homing capacity, as shown by decreased expression of the inflammatory chemokine receptors CCR5 and CXCR3, and reduced migration towards the inflammatory chemokine CCL5. Taken together our data suggest that ZA causes γδ T cells to target monocytes and down‐modulate the migratory programme required for inflammatory homing. This study provides novel insight into how γδ T cells interact with monocytes and the possible implications of systemic use of ZA in cancer.

Tripartite immune cell co-operation in the Bacillus Calmette Guérin-induced activation of γδ T cells

γδ T cells contribute to immunosurveillance of pathogenic infections and malignant transformations; however, mechanisms of activation have yet to be fully defined. In this study we demonstrate a novel mechanism by which human Vδ2+ γδ T cells are activated by the model pathogen Bacillus Calmette Guérin (BCG). We show in vitro that Vδ2 cell cytokine production and cytotoxic activity in response to BCG are dependent on both dendritic cells (DCs) and memory CD4+ αβ T cells (CD4 T cells). We found that Vδ2 cells are indirectly activated by BCG in an interleukin (IL)‐12p70‐dependent manner, and that DC production of the IL‐12p70 responsible for Vδ2 cell activation requires Toll‐like receptor 2/4 ligands from BCG and interferon (IFN)‐γ from memory CD4 T cells. Our data suggest that Vδ2 cell responses to BCG are dependent on the activation of IFN‐γ‐producing memory CD4 T cells, and provide novel insight into the complex interplay between cells of the innate and adaptive immune response.

Gemcitabine alters the proteasome composition and immunopeptidome of tumour cells

ABSTRACT The antigenic makeup of tumour cells can have a profound effect on the progression of cancer and success of immunotherapies. Therefore, one strategy to improve the efficacy of cancer treatments is to augment the antigens displayed by tumours. The present study explores how the recognition of tumour cells may be altered by non-cytotoxic concentrations of gemcitabine (GEM). Testing a panel of chemotherapeutics in human cancer cell lines in vitro, it was found that GEM increased surface expression of HLA-A,B,C and that underlying this were specific increases in β-2-microglobulin and immunoproteasome subunit proteins. Furthermore, the peptide antigen repertoire displayed on HLA class I was altered, revealing a number of novel antigens, many of which that were derived from proteins involved in the DNA-damage response. Changes in the nature of the peptide antigens eluted from HLA-A,B,C after GEM treatment consisted of amino acid anchor-residue modifications and changes in peptide length which rendered peptides likely to favour alternative HLA-alleles and increased their predicted immunogenicity. Signalling through the MAPK/ERK and NFκB/RelB pathways was associated with these changes. These data may explain observations made in previous in vivo studies, advise as to which antigens should be used in future vaccination protocols and reinforce the idea that chemotherapy and immunotherapy could be used in combination.

Abstract B38: Non-cytotoxic effects of the chemotherapeutic agent gemcitabine can alter the immunophenotype of tumor cells in in vitro culture

In addition to their cytotoxic/cytostatic properties, some chemotherapeutics have shown a remarkable capacity to modulate immune response. One such chemotherapy is the antimetabolite, gemcitabine (GEM). GEM has been shown to influence the quantity and activation of certain immune cell subsets when used in vivo. It has also been demonstrated that administration of GEM in conjunction with immunotherapy, such as dendritic cell vaccination, is beneficial in terms of overall survival and progression-free survival. The purpose of this study is to investigate if GEM can influence the way that tumor cells surviving treatment are regarded by the immune system. Our group has found that short-term in vitro culture with GEM enhances expression of human leukocyte antigen (HLA) class I, CD95, NKG2D ligands and TRAIL receptors on tumor cell lines. These molecules are all cell surface proteins important for the efficient surveillance and effector function of the immune system. The HLA class I increase is beta-2-microglobulin dependent and changes are underpinned by ERK, JNK and RelB-NFkB signalling pathways. Furthermore, culture with GEM induces immunoproteasomal components LMP2 and MECL-1 in tumor cells and, subsequently, the peptide antigen repertoire displayed on HLA class I is altered. The changes in peptide characteristics include amino acid anchor residue modifications which render the peptides likely to favor binding alternative HLA-allotypes. The renovation of the peptidome displayed by HLA class I may reveal sub-dominant immunogens to T-cells. Taken together, these changes may render tumor cells more sensitive to immune cell-mediated lysis. These data help explain observations made in previous in vivo studies, advise as to which novel antigens could be utilised in future vaccination protocols and lend further credence to the idea that chemotherapy and immunotherapy could be used in combination. Citation Format: Andrew M. Gravett, John P. Copier, Wai M. Liu, Martin P. Cranage, Angus G. Dalgleish. Non-cytotoxic effects of the chemotherapeutic agent gemcitabine can alter the immunophenotype of tumor cells in in vitro culture. [abstract]. In: Proceedings of the AACR Special Conference on Tumor Immunology and Immunotherapy; 2016 Oct 20-23; Boston, MA. Philadelphia (PA): AACR; Cancer Immunol Res 2017;5(3 Suppl):Abstract nr B38.