Interleukin-2 mastering regulation in cancer and autoimmunity

Livan Bladimir Alonso Sarduy, Ricardo Pérez Suárez
2007
Article

Résumé

Autoimmunity and tumor immunity evolved as two distinct arenas in immunological research. However, the identification of self-antigens as the major components of malignant cells may define a central role for autoimmunity in cancer control tuned by peripheral immunoregulatory mechanisms avoiding self-aggression. Emerging evidence documents a triple antagonistic role of interleukin-2 (IL-2) in vivo promoting survival, apoptosis, and the generation of regulatory T cells. We have found that IL-2 administration reduces the clinical course of experimental autoimmune encephalomyelitis and enhances immunoregulation in tumor-bearing mice. However, actively induced anti-IL-2 antibodies restore the response to nominal antigens in tumor-induced immunosuppressed host and induced therapeutic effect in transplantable and chemically induced tumors. It is suggested that IL-2 may contribute dynamically to the maintenance of natural immunological tolerance, preventing pathological autoimmunity, but may affect antitumor immunity. Cancer research has gained from autoimmunity understanding that tumor escape strategies include the natural mechanisms of immune tolerance and the ways to imbalance the peripheral regulatory mechanisms. Interestingly, therapeutic manipulations of immunoregulation have limited antitumor effects, although promoting collaterally infrequent autoimmune diseases. It may suggest that tumors may reinforce tolerance to protect themselves from the immune attack, a process that may involve dynamically various mechanisms including IL-2. Understanding this acquired experience from tumors may help utilize them to revert the immunopathology in autoimmune diseases.

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https://infoscience.epfl.ch/record/169404?ln=fr

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Livan Bladimir Alonso Sarduy, Ricardo Pérez Suárez
2007
Article

Résumé

Official source

https://infoscience.epfl.ch/record/169404?ln=fr

À propos de ce résultat

Concepts associés (13)

Concepts associés

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Publications associées (9)

Publications associées

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An autonomous microfluidic device for identification and analysis of individual clinically-relevant mammalian cells

Fabien Louis Claude Robert Jammes

Cancer represents one of the major public health challenges worldwide, representing more than 25% of all deaths in the European Union in 2014. It affects a large and growing part of the general population, with the National Cancer Institute (NCI) estimating that nearly 40% of men and women will be diagnosed with cancer at some point in their lifetimes.Cancer presents an enormous intrinsic complexity and diversity as well as a pronounced resistance to interventions. Current treatments are composed primarily of chemotherapy, surgery, radiotherapy and drug therapy. Each of these approaches has been met with restrained successes and limitations. One growing field of cancer treatments that is showing promising results is immunotherapy. An improved understanding of the cancer biology and microenvironment over the years, particularly the interactions between a tumor and the immune system, has demonstrated the capability of the host immune system to detect and eliminate malignant cells through the process of immune surveillance. However, by various mechanisms, malignant cells can stochastically "hide" from the immune system and transform into tumors. Immunotherapies intend to use the immune system to fight the tumor progression. Different kinds of immunotherapies exist: from immune checkpoint inhibitors (PD-1), to monoclonal antibody treatments and cancer vaccines. One interesting approach of immunotherapy is called adoptive cell transfer therapy (ACT), wherein immune cells, and more precisely, T cells, from the cancer-affected patient are extracted, allowing tumor-specific and effective T cells to be isolated, expanded, activated and re-injected into the patient's body. This type of treatment has already demonstrated great tumor clearance potential as well as the ability to induce long-term cancer immunity. However, one of the major challenges in this type of treatment is the recognition, isolation and expansion of high-affinity, effective T cells that are able to eliminate cancer cells. Several key advances in the field of genetics, sequencing, and personalized medicine have allowed for the identification of tumor-specific antigens, the unique cancer signature for a given patient and a specific tumor. But there is a growing need for novel tools and platforms enabling the screening, selection and isolation of rare, naturally-occurring, high-affinity, tumor-specific T cells. In this thesis we present a novel approach to study the affinity of CD8+ lymphocytes at the single-cell level using microfluidics technology. We demonstrate the ability of our platform to isolate single cells and evaluate their affinities towards a given antigen by using the reversible pMHC NTAmers technology developed by Julien Schmidt et al. at the Ludwig Institute for Cancer Research in Lausanne, Switzerland. The innovative platform developed here effectively alleviates some of the bottlenecks of current technologies, like flow cytometry, for affinity studies of lymphocytes at the single-cell level. This thesis represents the development from idea to proof-of-concept of this novel platform and we herein describe the origins and characterization of this technology as well as the first applications towards a personalized-medicine tool for clinical research uses.

EPFL2021

Chargement

Role of lymphatic vessels in tumor immunity: passive conduits or active participants?

Amanda Waite Lund, Melody Swartz

Research in lymphatic biology and cancer immunology may soon intersect as emerging evidence implicates the lymphatics in the progression of chronic inflammation and autoimmunity as well as in tumor metastasis and immune escape. Like the blood vasculature, the lymphatic system comprises a highly dynamic conduit system that regulates fluid homeostasis, antigen transport and immune cell trafficking, which all play important roles in the progression and resolution of inflammation, autoimmune diseases, and cancer. This review presents emerging evidence that lymphatic vessels are active modulators of immunity, perhaps fine-tuning the response to adjust the balance between peripheral tolerance and immunity. This suggests that the tumor-associated lymphatic vessels and draining lymph node may be important in tumor immunity which in turn governs metastasis.

Springer Verlag2010

Chargement

Cancer is a global disease and a leading cause of death worldwide. While surgery, radiotherapy and chemotherapy comprise the classical tools to eradicate tumors, they do not cure cancer, cannot prevent metastases, lead to side effects, and most importantly they do not instruct the patientʼs immune system to recognize and fight tumor cells. Since the discovery of the immune systemʼs implication in cancer, immunotherapies, which aim at using and educating the immune system to fight and reject cancer, have come to complement classical tumor-debulking methods. A major goal of immunotherapy is to induce or activate effector cytotoxic CD8+ T lymphocytes that can infiltrate and kill the tumor while overcoming immune suppressive mechanisms, which impede their efficacy. Moreover, cancer immunotherapies aim at inducing memory to tumor antigens to prevent relapse or metastases, which traditional therapies cannot do. Dendritic cell (DC) targeting and activation are key for inducing adaptive immunity. Our laboratory has developed synthetic nanoparticles (NPs) capable of draining through lymphatics to target skin-draining lymph nodes (LNs) and being phagocytosed by resident antigen-presenting cells (APCs) upon intradermal injection. We developed a reproducible method to conjugate tumor antigens to NPs and co-delivered them with CpG-conjugated NPs. We found that a NP vaccine composed of a single melanoma-derived peptide (TRP- 2180-188) led to dramatic tumor growth delay in melanoma and was more efficient than a NP vaccine containing several tumor antigens from whole tumor cell lysate (TL). These findings contradicted our hypothesis that immunization with TL might lead to a broader T cell response and hence improved therapeutic outcomes. Additionally, we found that the dose of CpG could modulate the magnitude of the therapeutic outcomes in both single epitope and multiple antigen based NP-vaccines. Considering the efficacy of the developed NP vaccines, we used them as a tool to ask a fundamental and extremely relevant question regarding the influence of vaccine administration site on clinical efficacy: is it therapeutically more beneficial to target a tumor- draining lymph node (tdLN), which is immune suppressed but tumor antigen-primed, or a non-tdLN, which is neither suppressed nor primed by the tumor? We found that targeting the tdLN with NP vaccines led to significantly enhanced therapeutic outcomes in two different tumor models over targeting a non-tdLN, and that efficacy relied on NP conjugation of antigen and adjuvant. This suggested that antigen drainage from the tumor might be available to APCs in the tdLN and we further hypothesized that therapies that lead to immunogenic tumor cell death might synergize with a tdLN-targeted adjuvant approach. While cytotoxic modalities, such as chemotherapy and radiotherapy, have traditionally been used for their ability to kill tumor cells, tumor cells shed antigens and debris upon cell death that drain to the tdLN. Consistent with our hypothesis, targeting an adjuvant to the tdLN enhanced therapeutic benefits of chemo- and radio- therapy, while targeting a non-tdLN did not. We hypothesized that targeting the tdLN with NP vaccines might switch the tdLN microenvironment from a suppressive to an immunogenic one. This suggested that direct targeting of active suppressive mechanisms in the tumor might further improve immunotherapy. We thus engineered a nano-sized micellar carrier loaded with 6-thioguanine (MC-6TG), a cytotoxic drug used in leukemia, and explored its use in targeting T cell- impairing myeloid-derived suppressor cells (MDSCs) in order to enhance the efficacy of therapeutic vaccines. MC-6TG entirely eradicated both Ly6c+ monocytic and Ly6g+ granulocytic MDSCs for up to 7 d in the blood, tumor and tdLN of tumor-bearing mice. Since MC-6TG also targeted certain subsets of macrophages and DCs, depleting MDSCs did not have an impact on the efficacy of a NP vaccine, which relies on APCs for efficacy. However, MC-6TG synergized with adoptively transferred CD8+ T cells, significantly delaying tumor growth and enhancing survival in a murine model of implantable melanoma. Overall, this thesis describes the design and implementation of a novel approach to immunotherapy: we engineered NP-based therapeutic vaccines, optimized their delivery route to enhance efficacy, and simultaneously tackled immune suppressive cells in the tumor microenvironment to allow optimal therapeutic outcomes. The technologies and methods developed in this work are particularly relevant to clinical oncology and have the potential to benefit cancer patients by improving cancer therapy efficacy.

EPFL2013

Chargement

An autonomous microfluidic device for identification and analysis of individual clinically-relevant mammalian cells

Fabien Louis Claude Robert Jammes

EPFL2021

EPFL2013