Immune cells: plastic players along colorectal cancer progression

Inflammatory cells are involved in tumour initiation and progression. In parallel, the adaptive immune response plays a key role in fighting tumour growth and dissemination. The double‐edged role of the immune system in solid tumours is well represented in colorectal cancer (CRC). The development and progression of CRC are affected by the interactions between the tumour and the host's response, occurring in a milieu named tumour microenvironment. The role of immune cells in human CRC is being unravelled and there is a strong interest in understanding their dynamics as to tumour promotion, immunosurveillance and immunoevasion. A better definition of immune infiltration would be important not only with respect to the ‘natural history’ of CRC, but in a clinically relevant perspective in the 21st century, with respect to its post‐surgical management, including chemotherapy responsiveness. While it is becoming established that the amount of tumour‐infiltrating lymphocytes influences the post‐surgical progression of early‐stage CRC, the relevance of this immune parameter as to chemotherapy responsiveness remains to be clarified. Despite recent experimental work supporting the notion that infiltrating immune cells may influence chemotherapy‐mediated tumour cell death, tumour‐infiltrating cells are not employed to identify patients who are more likely to benefit from adjuvant treatment. This review focuses on studies addressing the role of innate and adaptive immune cells along the occurrence and the progression of potentially curable CRC.     

The pro-metastatic role of bone marrow-derived cells: a focus on MSCs and regulatory T cells

Several bone marrow-derived cells have been shown to promote tumour growth and progression. These cells can home to the primary tumour and become active components of the tumour microenvironment. Recent studies have also identified bone marrow-derived cells—such as mesenchymal stem cells and regulatory T cells—as contributors to cancer metastasis. The innate versatility of these cells provides diverse functional aid to promote malignancy, ranging from structural support to signal-mediated suppression of the host immune response. Here, we review the role of mesenchymal stem cells and regulatory T cells in cancer metastasis. A better understanding of the bipolar nature of these bone marrow-derived cells in physiological and malignant contexts could pave the way for new therapeutics against metastatic disease.     

Immunization with a GM3 ganglioside nanoparticulated vaccine confers an effector CD8<Superscript>+</Superscript> T cells-mediated protection against melanoma B16 challenge

Preventive immunotherapy is an attractive strategy for patients at a high risk of having cancer. The success of prophylactic cancer vaccines would depend on the selection of target antigens that are essential for tumour growth and progression. The overexpression of GM3 ganglioside in murine and human melanomas and its important role in tumour progression makes this self antigen a potential target for preventive immunotherapy of this neoplasm. We have previously shown that preventive administration of a GM3-based vaccine to C57BL/6 mice elicited the rejection of the GM3 positive-B16 melanoma cells in most of the animals. Despite the crucial role of cellular immune response in tumour protection, the involvement of T cells in anti-tumour immunity of ganglioside vaccines is not described. Here, we examined the mechanisms by which this immunogen confers tumour protection. We have found that induction of anti-GM3 IgG antibodies correlated with tumour protection. Surprisingly, CD8⁺ T cells, but not NK1.1⁺ cells, are required in the effector phase of the antitumour immune response. The depletion of CD4⁺ T cells during immunization phase did not affect the anti-tumour activity. In addition, T cells from surviving-immunized animals secreted IFNγ when were co-cultured with IFNα-treated B16 melanoma cells or DCs pulsed with melanoma extract. Paradoxically, in spite of the glycolipidic nature of this antigen, these findings demonstrate the direct involvement of the cellular immune response in the anti-tumour protection induced by a ganglioside-based vaccine. Grant support: Center of Molecular Immunology, Elea Laboratories and Recombio.     

Challenges facing adjuvants for cancer immunotherapy

An adjuvant is defined as a product that increases or modulates the immune response against an antigen (Ag). Based on this general definition many authors have postulated that the ideal adjuvant should increase the potency of the immune response, while being non-toxic and safe. Although dozens of different adjuvants have been shown to be effective in preclinical and clinical studies, only aluminium-based salts (Alum) and squalene-oil-water emulsion (MF59) have been approved for human use. However, for the development of therapeutic vaccines to treat cancer patients, the prerequisites for an ideal cancer adjuvant differ from conventional adjuvants for many reasons. First, the patients that will receive the vaccines are immuno-compromised because of, for example, impaired mechanisms of antigen presentation, non-responsiveness of activated T cells and enhanced inhibition of self-reactivity by regulatory T cells. Second, the tumour Ag are usually self-derived and are, therefore, poorly immunogenic. Third, tumours develop escape mechanisms to avoid the immune system, such as tumour editing, low or non-expression of MHC class I molecules or secretion of suppressive cytokines. Thus, adjuvants for cancer vaccines need to be more potent than for prophylactic vaccines and consequently may be more toxic and may even induce autoimmune reactions. In summary, the ideal cancer adjuvant should rescue and increase the immune response against tumours in immuno-compromised patients, with acceptable profiles of toxicity and safety. The present review discusses the role of cancer adjuvants at the different phases of the generation of antitumour immunity following vaccination.     

In situ vaccination against a non-immunogenic tumour using intratumoural injections of liposomal interleukin 2

Cancers appear to escape surveillance by the immune system at least in part because they fail to induce a protective immune response. Therapeutic vaccines based on specific tumour antigens and tumour cells modified ex vivo by genetic techniques are but two strategies being used to circumvent this problem. In this report, we describe a simple, yet effective alternative in which tumour-specific responses are induced by in situ administration of a well-characterized liposomal formulation of the cytokine interleukin 2 (IL-2). Using the non-immunogenic B16 melanoma model, intratumoural injections of liposomal IL-2 L(IL2), were shown to induce a long-lived immune response specific for the injected tumour. In conjunction with subsequent removal of the primary tumours by surgery, the injections increased mean survival to 57 days from a control value of 32 days and partially protected surviving mice against re-challenge with B16. L(IL2) induced an early infiltration of inflammatory cells within the tumours which was followed several days later by an influx of CD3+ T cells. The cellular influx and a coincident decrease in tumour growth were noted in both injected tumours and a second non-injected tumour on the same animal, thereby demonstrating the systemic nature of the immune response. Intratumoural injections of soluble IL-2 at the same dose failed to induce B16-specific cellular immunity or to prolong survival of the mice. Thus, liposomal formulation of the cytokine was fundamental to successful induction of immunity by this in situ vaccination regimen.     

Role of the CCL2‐CCR2 signalling axis in cancer: Mechanisms and therapeutic targeting

The chemokine ligand CCL2 and its receptor CCR2 are implicated in the initiation and progression of various cancers. CCL2 can activate tumour cell growth and proliferation through a variety of mechanisms. By interacting with CCR2, CCL2 promotes cancer cell migration and recruits immunosuppressive cells to the tumour microenvironment, favouring cancer development. Over the last several decades, a series of studies have been conducted to explore the CCL2‐CCR2 signalling axis function in malignancies. Therapeutic strategies targeting the CCL2‐ CCR2 axis have also shown promising effects, enriching our approaches for fighting against cancer. In this review, we summarize the role of the CCL2‐CCR2 signalling axis in tumorigenesis and highlight recent studies on CCL2‐CCR2 targeted therapy, focusing on preclinical studies and clinical trials.

The chemokine ligand CCL2 and its receptor CCR2 are implicated in the initiation and progression of various cancers. The CCL2‐CCR2 signalling axis plays a critical role in the promotion of pathological angiogenesis, the survival and invasion of tumour cells, and the recruitment of immune inhibitory cells. Therefore, CCL2 and CCR2 enable us to explore the sophisticated mechanisms underlying cancer development and provide potential options for treating malignant tumours.     

Interplay between inflammation and cancer

Tumor-promoting inflammation is one of the hallmarks of cancer. It has been shown that cancer development is strongly influenced by both chronic and acute inflammation process. Progress in research on inflammation revealed a connection between inflammatory processes and neoplastic transformation, the progression of tumour, and the development of metastases and recurrences. Moreover, the tumour invasive procedures (both surgery and biopsy) affect the remaining tumour cells by increasing their survival, proliferation and migration. One of the concepts explaining this phenomena is an induction of a wound healing response. While in normal tissue it is necessary for tissue repair, in tumour tissue, induction of adaptive and innate immune response related to wound healing, stimulates tumour cell survival, angiogenesis and extravasation of circulating tumour cells. It has become evident that certain types of immune response and immune cells can promote tumour progression more than others. In this review, we focus on current knowledge on carcinogenesis and promotion of cancer growth induced by inflammatory processes.     

Immunoediting: evidence of the multifaceted role of the immune system in self-metastatic tumor growth

ABSTRACT: BACKGROUND: The role of the immune system in tumor progression has been subject to discussion for many decades. Numerous studies suggest that a low immune response might be beneficial, if not necessary, for tumor growth, and only a strong immune response can counter tumor growth and thus inhibit progression. METHODS: We implement a cellular automaton model previously described that captures the dynamical interactions between the cancer stem and non-stem cell populations of a tumor through a process of self-metastasis. By overlaying on this model the diffusion of immune reactants into the tumor from a peripheral source to target cells, we simulate the process of immune-system-induced cell kill on tumor progression. RESULTS: A low cytotoxic immune reaction continuously kills cancer cells and, although at a low rate, thereby causes the liberation of space-constrained cancer stem cells to drive self-metastatic progression and continued tumor growth. With increasing immune system strength, however, tumor growth peaks, and then eventually falls below the intrinsic tumor sizes observed without an immune response. With this increasing immune response the number and proportion of cancer stem cells monotonically increases, implicating an additional unexpected consequence, that of cancer stem cell selection, to the immune response. CONCLUSIONS: Cancer stem cells and immune cytotoxicity alone are sufficient to explain the three-step "immunoediting" concept - the modulation of tumor growth through inhibition, selection and promotion.     

Highly glycosylated tumour antigens: interactions with the immune system

A common phenotypic change in cancer is a dramatic transformation of cellular glycosylation. Functional studies of particular tumour-associated oligosaccharides are difficult to interpret conclusively, but carbohydrate-binding proteins are likely to contribute to progression of the tumour. This review discusses the potential role of CLRs (C-type lectin receptors), expressed by antigen-presenting cells of the immune system, in tumour recognition and immune modulation. Studies in recent years have provided significant insight into the immunomodulatory function of CLR during infections, but their role in cancer remains elusive; some strongly bind tumour cells and antigens, indicating participation in malignancy. The potential to use recombinant CLR as diagnostic tools will also be discussed.     

The effect of anti-lymphocyte and anti-thymocyte serum on the pathogenesis of Rauscher leukaemia in inbred mouse strains.

Rauscher virus causes in inbred Balb/c mice a rapidly progressing hyperacute, in C57B1/10Sn mice an incipient, spontaneously healing leukaemia. In DBA/1 and DBA/2 mice the appearance of leukaemia is followed by a partial remissions then by an exacerbation of the disease. The infection in C57B1/10Sn, DBA/1 and DBA/2 mice results in a significant tumour-specific immune response. Inhibition of the immune response is followed by an increased progression of leukaemia in DBA/1 and DBA/2 mice only. It is assumed that in C57B1/10Sn mice the remission of incipient leukaemia is associated with a resistance determined in the target cells, whereas in DBA/1 and DBA/2 mice the remission is due to a tumour-specific immune response. As in animals treated with anti-lymphocyte and anti-thymocyte serum the course of the disease runs proportionally to the degree of the inhibition of the immune response, the tumour-specific antibodies play a decisive role in the elimination of the tumour cells. In Balb/c, DBA/1 and DBA/2 mouse strains failing to exhibit a spontaneous reversion of the tumour cells, the appearance of a significant tumour-specific immune response depends on the resistance against the helper component of the Rauscher virus complex.     

Current understanding of the role of tyrosine kinase 2 signaling in immune responses

Immune system is a complex network that clears pathogens,toxic substrates,and cancer cells.Distinguishing self-antigens from non-self-antigens is critical for the immune cell-mediated response against foreign antigens.The innate immune system elicits an early-phase response to various stimuli,whereas the adaptive immune response is tailored to previously encountered antigens.During immune responses,B cells differentiate into antibody-secreting cells,while na?ve T cells differentiate into functionally specific effector cells[T helper 1(Th1),Th2,Th17,and regulatory T cells].However,enhanced or prolonged immune responses can result in autoimmune disorders,which are characterized by lymphocytemediated immune responses against self-antigens.Signal transduction of cytokines,which regulate the inflammatory cascades,is dependent on the members of the Janus family of protein kinases.Tyrosine kinase 2(Tyk2)is associated with receptor subunits of immune-related cytokines,such as type I interferon,interleukin(IL)-6,IL-10,IL-12,and IL-23.Clinical studies on the therapeutic effects and the underlying mechanisms of Tyk2 inhibitors in autoimmune or chronic inflammatory diseases are currently ongoing.This review summarizes the findings of studies examining the role of Tyk2 in immune and/or inflammatory responses using Tyk2-deficient cells and mice.     

Immunotherapeutic potential of whole tumour cells

Despite the identification of tumour antigens and their subsequent generation in subunit form for use as cancer vaccines, whole tumour cells remain a potent vehicle for generating anti-tumour immunity. This is because tumour cells express an array of target antigens for the immune system to react against, avoiding problems associated with major histocompatibility complex (MHC)-restricted epitope identification for individual patients. Furthermore, whole cells are relatively simple to propagate and are potentially efficient at contributing to the process of T cell priming. However, whole cells can also possess properties that allow for immune evasion, and so the question remains of how to enhance the immune response against tumour cells so that they are rejected. Scenarios where whole tumour cells may be utilised in immunotherapy include autologous tumour cell vaccines generated from resected primary tumour, allogeneic (MHC-disparate) cross-reactive tumour cell line vaccines, and immunotherapy of tumours in situ. Since tumour cells are considered poorly immunogenic, mainly because they express self-antigens in a non-stimulatory context, the environment of the tumour cells may have to be modified to become stimulatory by using immunological adjuvants. Recent studies have re-evaluated the relative roles of direct and cross-priming in generating anti-tumour immunity and have highlighted the need to circumvent immune evasion.     

Crosstalk between cancer‐associated fibroblasts and immune cells in cancer

Multiple studies have shown that cancer‐associated fibroblasts (CAFs) play an important role in tumour progression, including carcinogenesis, invasion, metastasis and the chemoresistance of cancer cells. Immune cells, including macrophages, natural killer cells, dendritic cells and T cells, play a dual role in the tumour microenvironment. Although increasing research has focused on studying interactions between distinct cells in the tumour microenvironment, the complex relationships between CAFs and immune cells remain unclear and need further study. Here, we summarize our current understanding of crosstalk between CAFs and immune cells, which may help clarify their diagnostic and therapeutic value in tumour progression.     

Induction of cytotoxicity against autologous tumour cells by interleukin-12: evidence for intrinsic anti-tumor immune capacity in curatively resected gastrointestinal tumour patients

The aim of this study was to investigate the cell-mediated immune response in 14 patients undergoing curative resection for a gastrointestinal tumor by the induction of peripheral blood mononuclear cell (PBMC)-mediated immune activity against autologous tumour cells. PBMC were stimulated by interleukin-12 (IL-12; 100 IU/ml) and IL-2 (1,000 IU/ml) without contact with tumour cells for 36 h. Specific cytotoxic activity against autologous tumour cells (auTu), natural killer (NK)-sensitive cells (K562) and allogeneic tumour cells (RF48/HT29) was determined by fluorescence cytotoxicity assay. Additionally, inhibition experiments using the mononuclear antibodies (mAb) FMC16 and W6/32 against major histocompatibility complex I (MHC I) on autologous tumour cells were performed in order to determine the involvement of specific T lymphocytes. The cytotoxic activity of unstimulated PBMC did not differ between the three target cells. IL-12 caused a 3.2-fold increase in activity against auTu ( P=0.002). In contrast, after stimulation with IL-2, only a slight increase in activity was observed. After IL-12 stimulation, cytotoxic activity against auTu was 2.5- to 2.7-fold higher than the corresponding activity against K562/allogeneic tumour cells ( P=0.002/ P=0.006). After blocking of the MHC I complex on auTu by FMC 16 or W6/32 mAb, a 62.9%/74.4% reduction in the specific cytotoxicity of IL-12-stimulated PBMC was found. In summary, IL-12 induced an effective immune response against auTu, which was partly mediated by specific cytotoxic T lymphocytes (CTL). It was considered that de novo generation of this activity during 36 h incubation without antigen contact was hardly possible, but that the observed induction of effective anti-tumor cytotoxicity was rather based on the re-activation of a pre-existing immune potential from the tumour-host interaction. These findings indicate the existence of an autologous anti-tumor immune response following curative resection in patients undergoing surgery for solid tumours, which might influence the development of tumour recurrence from disseminated tumour cells. Making use of this capacity could constitute an attractive immunotherapeutical approach for curatively operated tumour patients.     

Impact of tumour associated macrophages in pancreatic cancer

During cancer progression, bone marrow derived myeloid cells, including immature myeloid cells and macrophages, progressively accumulate at the primary tumour site where they contribute to the establishment of a tumour promoting microenvironment. A marked infiltration of macrophages into the stromal compartment and the generation of a desmoplastic stromal reaction is a particular characteristic of pancreatic ductal adenocarcinoma (PDA) and is thought to play a key role in disease progression and its response to therapy. Tumour associated macrophages (TAMs) foster PDA tumour progression by promoting angiogenesis, metastasis, and by suppressing an anti-tumourigenic immune response. Recent work also suggests that TAMs contribute to resistance to chemotherapy and to the emergence of cancer stem-like cells. Here we will review the current understanding of the biology and the pro-tumourigenic functions of TAMs in cancer and specifically in PDA, and highlight potential therapeutic strategies to target TAMs and to improve current therapies for pancreatic cancer. [BMB Reports 2013; 46(3): 131-138]     

MYCN as a target for cancer immunotherapy

MYCN is a potential target for cancer immunotherapy by virtue of its overexpression in numerous human malignancies and its functional role in tumour progression. Here we show limited expression of MYCN in normal human tissues indicating that anti-MYCN immune responses are unlikely to cross react with self tissues. An HLA-A2 restricted ten amino acid peptide epitope from MYCN, VILKKATEYV, was used to stimulate cytotoxic T cell lines from the peripheral blood of normal blood donors, and from a patient with MYCN amplified neuroblastoma. Strong and specific activity was seen against each MYCN overexpressing cell line and against autologous tumour cells. We generated two CTL clones capable of killing cells pulsed with as low as 0.5 nM of VIL peptide. Therefore strong and specific immune responses against MYCN expressing tumours are possible in patients with the most common HLA class 1 type in the Caucasian population.     

Immunotherapy and immunoselection -- tumour escape as the final hurdle

Tumours are immunogenic and are commonly infiltrated by anti-cancer effector cells. Why, then, are they not completely rejected by the host? Unfortunately, tumours are Darwinian paragons, winning the battle against the forces of natural immune selection. Some of the latter can even act as double-edged swords, actually being subverted to become pro-tumorigenic. Prevention or reversal of tumour escape from the immune response therefore offers the possibility of reconstituting effective anti-tumour immunity and remains the major challenge for 21st century tumour immunology.     

Adenovirus subversion of immune surveillance, apoptotic and growth regulatory pathways: a model for tumorigenesis

The adenovirus system provides a novel model for evaluating the roles of multiple factors involved in tumour progression. In common with other DNA tumour viruses, adenovirus employs a variety of strategies to evade immune surveillance and perturbs cellular apoptotic and growth regulatory pathways to ensure efficient replication of progeny virions. Such subversion of cellular networks is also found in tumour cells. The mechanism behind the avoidance of immune surveillance and the extent of cellular network interference achieved by adenovirus is still being uncovered and is predicted to have ramifications for the design of cancer therapeutics.