Lecture 15 Cancer and the Immune System PDF
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King Saud bin Abdulaziz University for Health Sciences
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This lecture presents the fundamental principles of cancer biology and the immune system. It discusses tumor immunosurveillance, immune evasion, and current immunotherapy approaches. The lecture also explores the interactions between cancer cells and immune cells and the role of genetic mutations and epigenetic modifications in shaping immune responses.
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Lecture 15 Cancer and the immune system Objectives Explain the fundamental principles of cancer biology and the immune system. Examine how the immune system can both suppress and facilitate tumor development, including the concept of tumor immunosurveillance and immune ev...
Lecture 15 Cancer and the immune system Objectives Explain the fundamental principles of cancer biology and the immune system. Examine how the immune system can both suppress and facilitate tumor development, including the concept of tumor immunosurveillance and immune evasion by cancer cells. Provide an overview of current immunotherapy approaches in cancer treatment, such as checkpoint inhibitors, CAR T-cell therapy, and cancer vaccines, including their mechanisms of action and clinical applications. Explore the interaction between cancer cells and immune cells in the tumor microenvironment. Discuss the role of genetic mutations and epigenetic modifications in shaping immune response against tumors and their implications in personalized medicine 2 © Macmillan Learning 2023 Cancer Development and Key Characteristics ▪ Most mature cells in the body have a finite life span. ▪ Occasionally, a cell arises that does not respond to normal growth control mechanisms, leading to cancer. ▪ Cells that expand in an uncontrolled manner will produce a tumor or neoplasm. ▪ Benign tumors are incapable of indefinite growth and do not invade surrounding healthy tissue. ▪ Malignant tumors continue to grow and become progressively more invasive and spread (metastasize) to other tissues. © Macmillan Learning 2023 Mechanisms of Cancer Development ▪ Mutations in genes regulating cell division can lead to unregulated cell growth. ▪ Cells can be transformed by various chemicals (i.e., pesticides), physical agents (i.e., asbestos), ionizing radiation, or viral infections which can lead to DNA mutations. ▪ Agents that induce DNA mutations and lead to unregulated cell proliferation are carcinogens. © Macmillan Learning 2023 Cancer-Associated Genes ▪ Genes that have been associated with cancer control cell proliferation and survival. ▪ Oncogenes encourage growth and proliferation; they promote cancer when their activity is increased. ▪ Tumor-suppressor genes inhibit proliferation or mediate DNA repair; their failure allows cancer cell survival. ▪ Apoptosis genes enforce or inhibit cell death signals, thereby controlling programmed cell death. © Macmillan Learning 2023 Cancer Hallmarks Six original defining characteristics, known as cancer hallmarks, focus on essential cellular processes that distinguish cancerous and non- transformed somatic cells. Four enabling characteristics were added to describe microenvironmental influences. Fig. 20-2 © Macmillan Learning 2023 The Immune Response to Cancer ▪ Three proposed pathways for how the immune system controls or inhibits cancer: ▪ Destroying viruses that are known to transform cells ▪ Eliminating all pathogens and downregulating inflammation ▪ Identifying and eliminating pre-cancerous and transformed cells – immunosurveillance © Macmillan Learning 2023 Immunoediting ▪ The modern view is nuanced – the immune system can have tumor-inhibiting and tumor-enhancing effects. ▪ Immunoediting describes how white blood cells have pro- and anti-tumor effects that shape the tumor cell population over time. ▪ The antitumor immune responses select for the toughest cells. ▪ Three sequential phases are proposed: ▪ Elimination – identifying and attacking the cells that can be targeted ▪ Equilibrium – a state of balance between the destruction of some tumor cells, and the survival of the “best” tumor cells ▪ Escape – the most aggressive and least immunogenic cells thrive and spread © Macmillan Learning 2023 Phases of Immunoediting © Macmillan Learning 2023 Fig. 20-4 The Role of Cytokines in Cancer Immunity ▪ Cytokines play an important role in cancer immunity. ▪ IFN-γ ▪ All interferon types enhance tumor-cell removal activities of immune cells. ▪ IL-12 ▪ Encourages DCs to activate strong TH1 and CTL responses. ▪ IL-12 deficiency results in more papillomas in animals. ▪ Administration of IL-12 protects mice from chemically induced tumors. ▪ TNF-α may promote or inhibit anticancer effects; its role in cancer immunity is complex. © Macmillan Learning 2023 Evasion of Immune Recognition Some tumor cells evade immune recognition and activation. ▪ One way is via reduced MHC expression in tumor cells. ▪ Tumor cells with mutations in genes for MHC class I expression make poor CTL targets. ▪ Decreased expression of NK-activating receptor ligands makes cells with low MHC class I expression poor targets for NK cells. ▪ Expression of immune inhibitory proteins (like CD80/86 and PD-L1/L2) © Macmillan Learning 2023 Immunosuppression in the Tumor Microenvironment ▪ Active immunosuppression in tumor microenvironments ▪ Soluble factors (e.g., TGF-β, IL-10, and IDO) can suppress immunity to form a tumor (immune) microenvironment (TME or TIME). ▪ Immunosuppressive cell types like TREG cells can also be found in tumor areas. ▪ Suppression prevents antitumor activities of immune cells creating a tumor-protective microenvironment. © Macmillan Learning 2023 Microenvironment during the escape phase of immunoediting Pro-Tumor Down- regulation of MHC class I and/or Expression of immune inhibitory proteins (like CD80/86 and PD-L1/L2) Immunosuppressive Secreting anti-inflammatory cytokines and other compounds (e.g., TGF-β, IL-10, and IDO) Microenvironment anti-inflammatory/tumor-protective. Fig. 20-5 © Macmillan Learning 2023 Tumor-Cell Resistance to Apoptosis Some tumor cells evade immune recognition and activation. ▪ Tumor-cell resistance to apoptosis can occur by: ▪ expression of mutated or absent death receptors, for example, Fas and TRAILR ▪ upregulation of anti-apoptotic mediators ▪ downregulation of pro-apoptotic mediators © Macmillan Learning 2023 Co-inhibitory and Immunosuppressive Tumor Signals Some tumor cells evade immune recognition and activation. ▪ Tumor cells provide poor costimulatory signals. ▪ There may be mutations in or downregulation of second signal molecules. CD80/86 (B7) on APCs CD28 on T cells ▪ Lack of a proper second signal may lead to clonal anergy in T cells and immune tolerance to cancer cells. Some recently approved therapies are aimed at enhancing costimulation to antitumor T cells. © Macmillan Learning 2023 Cancer Therapies ▪ Surgical removal (resection) and radiation are commonly used for solid tumors. ▪ Drug therapies generally fall into four loosely organized categories: ▪ Chemotherapies – aimed at blocking DNA synthesis and cell division ▪ Adjuvant cancer therapy adds drugs or small molecule inhibitors. ▪ Neoadjuvant cancer therapy starts with drugs and follows with surgery. ▪ Hormonal therapies – interfere with tumor-cell growth ▪ targeted therapies – small molecule inhibitors for tumors that are sensitive to the drugs ▪ immunotherapies – induce or enhance the antitumor immune response © Macmillan Learning 2023 Cancer Immunotherapies Fig. 20-7 © Macmillan Learning 2023 Monoclonal Antibodies ▪ Monoclonal antibodies (mAbs) can be targeted to tumor cells. ▪ Initially intended to deliver toxin or activate immune pathways (e.g., complement, ADCC, ADCP) ▪ Names are complicated, but include the suffix –mab. ▪ Successes include: ▪ Treatment of terminal B-cell lymphoma with anti-idiotype mAb ▪ mAb against CD20 B-cell marker for non-Hodgkin’s lymphoma and chronic lymphocytic leukemia (CLL) ▪ Antibody-drug conjugates that couple toxic molecules with mAb ▪ can include immunotoxins (e.g., diphtheria toxin) ▪ mAb against receptors example cetuximab against EGFR © Macmillan Learning 2023 Bispecific T-Cell Engagers (BiTEs) ▪ Bispecific T-cell engagers (BiTEs) ▪ recognize two target epitopes ▪ activate T cells ▪ are made by combining light- and heavy-chain variable regions of two antibodies into a single chain Fig. 20-8 © Macmillan Learning 2023 Monoclonal Antibodies Approved by the FDA for Cancer Treatment First mAb name Trade name Target Used to treat approved Rituximab RITUXAN® CD20 Non-Hodgkin’s lymphoma 1997 Chronic lymphocytic leukemia (CLL) Trastuzumab Herceptin® HER2 Breast and stomach cancer 1998 and 2010 Gemtuzumab Mylotarg™ CD33 Acute myelogenous leukemia (AML) 2000† ozogamicin* Alemtuzumab Campath® CD52 CLL 2001 Ibritumomab tiuxetan* Zevalin® CD20 Non-Hodgkin’s lymphoma 2002 131 I-Tositumomab* BEXXAR® CD20 Non-Hodgkin’s lymphoma 2003 Bevacizumab Avastin® VEGF Colorectal, non–small cell lung, 2004 breast, glioblastoma, and kidney cancer Table 20-4 © Macmillan Learning 2023 Monoclonal Antibodies Approved by the FDA for Cancer Treatment, Continued mAb name Trade name Target Used to treat First approved Panitumumab Vectibix® EGFR Colorectal cancer 2006 Ofatumumab Arzerra® CD20 CLL 2009 Denosumab XGEVA® RANK ligand Bone metastases 2010 Ipilimumab YERVOY® CTLA-4 Melanoma 2011 Brentuximab vedotin* ADCETRIS® CD30 Hodgkin’s lymphoma and 2011 one type of non–Hodgkin’s lymphoma Pembrolizumab KEYTRUDA® PD-1 Melanoma, non–small cell 2014 lung, and kidney cancers, as well as Hodgkin’s lymphoma‡ Atezolizumab TECENTRIQ® PD-L1 Bladder, non–small cell lung, 2016 Merkel cell carcinoma, and triple-negative breast cancers Table 20-4 © Macmillan Learning 2023 Immune Checkpoint Blockades ▪ Ipilimumab is a monoclonal antibody against CTLA-4. ▪ It is an immune checkpoint inhibitor (ICI) that employs immune checkpoint blockage (ICB). ▪ Originally licensed for use against malignant melanoma. Fig. 20-9 © Macmillan Learning 2023 Adoptive Cell Transfers ▪ Tumor-specific T cells can be expanded and reintroduced into patients. ▪ In 1998, tumor-infiltrating lymphocytes (TILs) were obtained from patients with metastatic melanoma. ▪ Immune cell-transfer therapies now use peripheral cells and are called adoptive cell transfers. © Macmillan Learning 2023 CAR T Therapies ▪ The newest T-cell therapy for cancer are chimeric antigen-receptor (CAR) T cells or CARs; ▪ They are part immunoglobulin and part TCR. Box 20-2 Figure 1 © Macmillan Learning 2023 CAR T Therapies ▪ CAR T cells can be modified with specific accessory molecules. © Macmillan Learning 2023 Box 20-2 Figure 2 Cancer Vaccines ▪ Vaccines are commonly prophylactic and designed to initiate an immune response before the onset of disease or an antigen encounter. ▪ New therapeutic vaccines may enhance the antitumor immune response. ▪ Are intended to enhance or redirect the immune response after disease has occurred. ▪ Antigens in prophylactic vaccines do not always work in a therapeutic approach (e.g., the vaccine against HPV). Fig. 20-10 © Macmillan Learning 2023 The NeoVax Cancer Vaccine Platform ▪ Scientists at Dana Farber Cancer Institute have been using the NeoVax system to produce personalized, neoantigen-based vaccines based on unique mutations from the patient’s own cancer cells. Fig. 20-11 © Macmillan Learning 2023 Oncolytic Viruses ▪ Oncolytic viruses (OVs) can infect healthy and cancerous cells. ▪ They are only cytolytic in cancerous cells. ▪ Cancer cells are more susceptible to viral infection. ▪ Several viruses are being investigated to manipulate tumor cells. ▪ T-VEC (Imlygic™) was the first OV approved to treat chemotherapy- resistant melanoma. Fig. 20-11 © Macmillan Learning 2023 Thank you PRESENTATION TITLE 29