1 / 34

Conflict of Interest Statement Anthony DeFranco

Conflict of Interest Statement Anthony DeFranco. Identified conflicts of interest

rigel-matthews
Télécharger la présentation

Conflict of Interest Statement Anthony DeFranco

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Conflict of Interest StatementAnthony DeFranco Identified conflicts of interest -I am on the Scientific Advisory Board of UCB-Pharma, a pharmaceutical company that sells anti-inflammatory drugs (one of the five approved TNF blockers) and anti-histamines. Additional immunology-related therapeutics are in late phase clinical testing -My wife and I own stock in several biotechnology companies that make anti-inflammatory drugs and/or are currently in late phases of testing such drugs Management of conflicts of interest -I will not comment on relative advantages or disadvantages of specific products or potential products made by these companies vs. competitive products of other companies

  2. Inflammation and Innate Immunity (part I) • Inflammation • Innate immunity and the initial response to infection • Cytokines that induce inflammation and direct inflammatory cells • Recognition of microbes by Toll-like receptors (TLRs) and other innate recognition elements • Inflammation and recruitment of phagocytes • Uptake and killing of bacteria by phagocytes • Innate immunity against fungi, helminths, at mucosal epithelium

  3. Inflammation Source: Wikipedia

  4. Inflammation “rubor et tumor cum calore et dolore” (redness and swelling with heat and pain) --Cornelius Celsus in De Medicina, 1st century A.D. later “functio laesa” (disturbance of function) was added

  5. Inflammation “rubor et tumor cum calore et dolore” (redness and swelling with heat and pain) --Cornelius Celsus in De Medicina, 1st century A.D. later “functio laesa” (disturbance of function) was added Inflammation is an adaptive response to noxious conditions (infection and tissue injury)--an attempt to restore homeostasis

  6. Inflammation • Inflammation can be induced by immune recognition of infection or tissue damage (usually good) • Inflammation can be induced by immune recognition that is hypersensitive to environmental components or autoinflammatory or autoimmune (=disease)

  7. Inflammation • Inflammation can be induced by immune recognition of infection or tissue damage (usually good) • Inflammation can be induced by immune recognition that is hypersensitive to environmental components or autoinflammatory or autoimmune (=disease) • Acute inflammation: influx of white blood cells and fluid from blood to fight infection and aid tissue repair • Chronic inflammation: inducer of inflammation is not removed • Leads to tissue damage and loss of tissue function (joint destruction, lung fibrosis, etc.) • Current view: aggressively fight inflammation in certain chronic diseases to decrease/delay progressive loss of function

  8. Inflammation • Inflammation can be induced by immune recognition of infection or tissue damage (usually good) • Inflammation can be induced by immune recognition that is hypersensitive to environmental components or autoinflammatory or autoimmune (=disease) • Acute inflammation: influx of white blood cells and fluid from blood to fight infection and aid tissue repair • Chronic inflammation: inducer of inflammation is not removed • Leads to tissue damage and loss of tissue function (joint destruction, lung fibrosis, etc.) • Current view: aggressively fight inflammation in certain chronic diseases to decrease/delay progressive loss of function • Current research suggests that inflammation may play an important role in common chronic diseases including atherosclerosis, type 2 diabetes, neurodegeneration, and cancer

  9. Immune sentinel cells in the tissues: dendritic cells Green= dendritic cells Blue= nuclei of all cells Langerhans cells (epidermal dendritic cells) in the skin WJ Mullholland et al. J. Invest. Dermatol. 126: 1541, 2006.

  10. Infection leads to production of inducers of inflammation or dendritic cell Inflammatory mediators: Complex and many, but include: Lipids and Proteins (cytokines/chemokines) TNF Others

  11. Cytokines • “Cytokines” are soluble protein mediators secreted by immune cells (mostly) that act on other cells to regulate their activity; many are called “interleukins” (IL-1, IL-2, etc.) (note: sometimes exist in cell-bound forms) • Cytokines have many functions, we’ll focus on a few central functions of some key cytokines (see “Cytokine primer” in syllabus) • Name of a cytokine often doesn’t reflect its most important function (example: TNF stands for “tumor necrosis factor” but main function is to induce inflammation) • A subfamily of cytokines primarily functions in directing migration of cells, these are called “chemotactic cytokines” or “chemokines” Chemokines have systematic names: CCL1, 2, … and CXCL1, 2, … (but older names sometimes used, including IL-8)

  12. The Initial Response to Infection: Innate Immunity • Recognition of types of molecules (“molecular patterns”) made by microbes or viruses but not by our cells by innate immune receptors • Alternatively, recognition of tissue damage and cell death, which are often associated with infection (“danger”). • Rapid mobilization of leukocytes to the site of infection or damage and influx of plasma into the tissue site (=inflammation) • Recruited innate immune cells kill microbes or virally infected cells. Immune cells also can promote tissue repair but when dysregulated can exacerbate tissue injury • Also, innate recognition promotes the adaptive immune response, which is slower but more powerful

  13. Cytokines and Inflammation • Macrophages or DCs stimulated via innate immune receptors make pro-inflammatory cytokines, especially TNF (Tumor necrosis factor), IL-1, and IL-6 • TNF and IL-1 signal to endothelial cells to make them: • Leaky to fluid (influx of plasma; containing antibodies, complement components, etc.) • Sticky for leukocytes, leading to influx of first neutrophils, later monocytes, lymphocytes • IL-6 promotes adaptive immune responses and has systemic effects (“acute phase response” of liver, including C-reactive protein or CRP; levels used clinically as an indication of systemic inflammation)

  14. Leukocyte recruitment to sites of inflammation or DC See Abbas and Lichtman Fig. 2-7 Note: molecular details of leukocyte extravasation will be covered in lecture Thursday

  15. Inflammation: Neutrophils vs. Monocytes • Acute inflammation is initially characterized as rich in neutrophils; later it is more monocytes and lymphocytes. This is controlled by which chemokines are expressed by the endothelial cells. • Neutrophils are dedicated to killing microbes and are short-lived. They often damage host tissue as a byproduct. • Monocytes are multi-potential, depending on cytokine signals: +IFN-g: assume a vigorous killing phenotype similar to neutrophils +IL-4: “alternatively activated macrophages”; tissue repair, barrier immunity +IL-10: assume a wound-healing type phenotype (to clean up after infection is cleared)

  16. Anti-Inflammatory Therapeutics • NSAIDs: inhibitors of inflammation and fever (block prostaglandin synthesis) • Glucocorticoids are also potent anti-inflammatory drugs; natural systemic anti-inflammatory mechanism • Agents that block TNF are effective in treating rheumatoid arthritis, Crohn’s disease, etc. • Agents that block IL-1 are less effective for these diseases but are useful for some genetic inflammatory diseases

  17. How is infection first recognized by the immune system? • What is seen by innate immunity? • Types of molecules made by microbes, but not by our cells “Pathogen-associated molecular patterns” PAMPs • Molecules released from necrotic cells, tissue damage (“damage-associated molecular patterns” DAMPs). (Note: tissue damage can also be recognized by pain neurons, which can promote inflammation) • What mediates the recognition? • Diverse recognition elements; 4 key families of cellular receptors: • Toll-like receptors (TLRs) • C-type lectin receptors (CLRs) • RigI-like receptors (RLRs) • NOD-like receptors (NLRs)

  18. Innate recognition outside the cell or in endosomes:TLRs and CLRs Surface CLRs carbohydrates TLRs induce inflammatory cytokines (+ interferon) Endosomal TLRs recognize nucleic acids (mostly from virus particles). Localization in endosomes is thought to aid discrimination between virus-derived and endogenous nucleic acids TLR4 recognizes LPS CLRs detect mostly carbohydrates (fungi especially); also recognize dead host cells; induce cytokines Modified from Abbas and Lichtman Fig. 2-2

  19. Sepsis Syndrome: very bad(too much of a good thing) • Bacterial septicemia leads to activation of TLRs on monocytes in the blood, DCs in spleen • Systemic release of TNF and IL-1 leads to “inflammation” all over the body • Shock from loss of blood pressure (vasodilation and leakage of fluid into tissues) • TLRs also induce coagulation (via tissue factor) • Current therapy with some efficacy: “activated protein C”: promotes fibrinolysis, breaks down thrombi • The combination of effects frequently leads to multi-organ failure and death

  20. Innate recognition in the cytoplasm:NLRs and RLRs Modified from Abbas and Lichtman Fig. 2-2 Inflammatory cytokines Secrete anti-microbial peptides into lumen of crypts of sm. intest. Peptidoglycan Engulfment of bacteria invading the cytoplasm (autophagy) (RLRs)

  21. Common alleles of NOD2 are a genetic risk factor for Crohn’s disease • Several moderately common alleles of the NOD2 gene (7% of total alleles) increase susceptibility to Crohn’s disease (a form of inflammatory bowel disease) • Two copies of these alleles increase susceptibility by 40X • Mechanism: most evidence indicates these are loss-of-function alleles; unknown which function of NOD2 is most relevant

  22. Processing of IL-1 and related cytokines: an important regulatory step • Some “NLRs” assemble to form the “inflammasome” which proteolytically processes IL-1 and related cytokines (IL-18) to their active, secreted forms. • Inflammasome in activated by cellular stress or recognition of microbial components in the cytoplasm

  23. Processing of IL-1 and related cytokines: an important regulatory step • Some “NLRs” assemble to form the “inflammasome” which proteolytically processes IL-1 and related cytokines (IL-18) to their active, secreted forms. • Inflammasome in activated by cellular stress or recognition of microbial components in the cytoplasm • Genetic periodic fever syndromes are due to activating mutations in the inflammasome (active when it shouldn’t be) • Inflammasome is activated by some types of small crystals that can be phagocytosed by macrophages, important role in Gout

  24. The Inflammasome activates caspase 1 in response to cellular insults Phagocytosed crystals Bacterial pore-forming toxins Efflux of K+ Bacterial flagellin Other insults/stresses Several different NLRs can form inflammasomes (shown is NLRP3/NALP3)

  25. Inducers of Inflammation • Microbe PAMPs recognized by TLRs, NOD1/2 or CLRs: DCs, macrophages makeTNF and IL-1 • Virus infections: infected cells, pDCs make IFN/ (type 1) • Tissue damage (cell necrosis etc.): “DAMPs” activate DCs, macrophages via TLRs, CLRs, inflammasomes (other receptors?) • Complement fragments (innate activators or IgM or IgG + antigen) • Mast cell activation (IgE+allergen or innate mechanisms: release histamine, leukotrienes, cytokines): eosinophil-rich inflammation (“type 2 immunity”) • Effector T cells responding to antigen (TNF + other cytokines; chemokines)

  26. Negative Regulation of Inflammation • Cells responding to innate stimuli stop making inflammatory mediators after short time period and convert to making anti-inflammatory lipids (resolvins, etc.) and anti-inflammatory cytokines (IL-10, TGF-) • Killing the infectious agent and removal of the dead cells, debris, crystals, etc. will stop stimulation of incoming inflammatory cells • Systemic elevation of inflammatory cytokines (esp. IL-1) in severe infections induce production of glucocorticoids, which are anti-inflammatory (also increased by stress) • Regulatory T cells are also anti-inflammatory, both by blocking effector T cells and by inhibiting innate cells

  27. Phagocytosis and Killing of Microbes Abbas and Lichtman Fig. 2-9

  28. Phagocytosis and Killing of Microbes Key Concepts related to phagocytosis: Opsonization: soluble immune recognition elements tag a particle for phagocytosis (opsonins include: Mannose-binding lectin, C3b, IgG, etc.) Interferon- from NK cell or Th1 cell promotes killing of internalized microbes by monocytes/macrophages Killing mechanisms: ROI, NO, proteases, anti-microbial peptides Abbas and Lichtman Fig. 2-9

  29. Phagocytosis and Killing of Microbes Key Concepts related to phagocytosis: Opsonization: soluble immune recognition elements tag a particle for phagocytosis (opsonins include: Mannose-binding lectin, C3b, IgG, etc.) Interferon- from NK cell or Th1 cell promotes killing of internalized microbes by monocytes/macrophages Killing mechanisms: ROI, NO, proteases, anti-microbial peptides Genetic defects in phagocyte oxidase components: “chronic granulomatous disease” Abbas and Lichtman Fig. 2-9

  30. Innate Immunity against fungal pathogens • CLRs are key innate recognition elements for fungi/yeast (TLRs can also play a role) • Neutrophils are important for killing most fungal pathogens • Some fungal pathogens can establish intracellular infections (like some bacterial pathogens): interferon- is important for defense; often also NO

  31. Innate Immunity against helminths • Often multicellular parasites induce a “type 2” inflammation characterized by influx of eosinophils and basophils instead of neutrophils and monocytes • This type of inflammation is also seen in asthma and allergies, as will be discussed later in the course and can be propagated by Th2 adaptive immunity and/or IgE • Innate recognition is not yet understood, may include foreign polysaccharides (chitin), proteases, tissue damage • In some parasitic worm infections inside tissue, bacteria in the gut/feces of the worm stimulate TLRs and neutrophil-rich inflammation, which can cause pathology (African river blindness)

  32. Innate Immunity and Mucosal Epithelium • Microbes are tolerated outside mucosal epithelium when consistent with its function (colon; upper airways) • Efforts to keep microbes out of some mucosal epithelial regions (small intestines and small airways) • Mechanisms include: actions of some surfactant proteins in lungs (bind to foreign polysaccharides); secretion of anti-microbial peptides by Paneth cells in crypts of small intestines; secretion of mucus by goblet cells;  T cells in epithelial tissue; IgA • IL-13 is an important cytokine promoting mucus secretion

  33. Tomorrow: Innate Immunity to Viruses

  34. REMINDER:The 1PM session is a live patient interview session, so be here promptly by 1:10 and no electronics or eating food when patient is on stagePatient Confidentiality must be maintained

More Related