1 / 62

Humoral Responses to Infection

Humoral Responses to Infection. https://www.facebook.com/pages/Tsunoda-laboratory/406138889435131?fref=nf. 2015 MICROBIOLOGY & INFECTIOUS DISEASES Lecture 10 Ikuo Tsunoda, MD, PhD Associate Professor Department of Microbiology and Immunology

bowersc
Download Presentation

Humoral Responses to Infection

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. Humoral Responses to Infection https://www.facebook.com/pages/Tsunoda-laboratory/406138889435131?fref=nf 2015 MICROBIOLOGY & INFECTIOUS DISEASES Lecture 10 Ikuo Tsunoda, MD, PhD Associate Professor Department of Microbiology and Immunology itsunoda@hotmail.com, http://tsunodalaboratory.web.fc2.com/ July 22, 2015

  2. Objectives To understand; Structures of immunoglobulins and their proteolytic digestion Difference in biologic properties among antibody classes VDJ recombination and class switching of immunoglobulin Transfer of IgG from mother to fetus (via FcRn) Mucosal secretion of IgA (via poly-Ig receptor) Primary and secondary immunoglobulin responses Effector functions of antibody

  3. Humoral immune responses “Antibody” = immunoglobulin is the primary component of the humoral immunity “Antigen” = a molecule recognized by antibody or T cell “Epitope” is the molecular structure in an antigen that interacts with antibody or T cell Proteins (best antigen) >> carbohydrates (weak) >> lipids, nucleic acids (poor antigen)

  4. Hinge Antibodies are composed of polypeptides with both variable and constant regions Note: 2 identical heavy chains (green) 2 identical light chains (yellow) The immunoglobulin G (IgG) molecule Note: Location of the variable (red) and constant (blue) regions in the antibody molecule.

  5. The immunoglobulin constant (C) regions The constant (C) regions have little variability in amino acid sequence. Two different kinds of C regions for light chains : kappa (κ) lambda (λ) k k g g Any of two identical light chains can pair with any two identical heavy chains to make a complete immunoglobulin molecule.

  6. Five antibody classes (isotypes), determined by the constant region of the heavy chain The Structural Organization of the Human Immunoglobulin Classes Five different kinds of C regions for H chains : gamma (γ) chains, IgG mu (µ) chains, IgM delta (δ) chains, IgD alpha (α) chains, IgA epsilon (ε) chains, IgE

  7. Each chain is folded into multiple ‘Ig’ domains Both H and L chains contain multiple loops of around 110 amino acids each. The heavy chain constant domains (CH) : The “biological activity” region Responsible for interactions with other proteins (eg, complement), cells (eg, mast cells), and tissues that result in the effector functions of immunoglobulins

  8. Each chain is folded into multiple ‘Ig’ domains Both H and L chains contain multiple loops of around 110 amino acids each. The variable domains (VH, VL) : The “antigen-binding” region Together, these domains compose the sole antigen-binding region of the immunoglobulin molecule. The V regions are the first 110 amino acids at the N-terminus of both H and L chains. This is the region that gives antibody specificity for a given antigen.

  9. Proteolytic digestion of IgG • Papain treatment produces Fab fragments and Fc fragment • Fab, antigen-binding; Fc, crystalizable or constant region • Fc portion interacts with host systems • Complement activation • Binding to Fc receptor (FcR) on macrophages and other cells

  10. Immunoglobulins • Basic structure • 2 identical heavy chains • 2 identical light chains • Heavy and Light chains • variable (V) and constant (C) regions • disulfide bonds link the chains together • light chains have 2 domains, 1V and 1C • heavy chains have 4-5 domains, 1V and 3-4 C • heavy chains: 5 classes, μ, γ, α, δ, ε • light chains: 2 classes, κ and λ • Membrane bound (mIg) or secreted (sIg)

  11. Antibody recognizes only a small region (epitope) on the surface of a large molecule • Antibody binds an epitope formed by a specific sequence (linear epitope) or a three-dimensional structure (conformational epitope)

  12. Antigens can bind in pockets, grooves, extended surface, or protruding surfaces in the binding sites of antibodies

  13. During B cell development, V, D, and J gene segments rearrange, creating functional genes that encode immunoglobulin transcripts. The process of rearrangement of the Ig locus – called VDJ recombination. Genetic recombination at the DNA level and processing at the RNA level to produce functional mRNA

  14. variable genes constant gene 51 27 6 During B cell maturation, V, D, and J gene segments rearrange, creating functional genes that encode immunoglobulin transcripts. For example, a rearranged heavy chain locus is composed of : • one V gene segment (from 51) • one D gene segment (from 27) • one J gene segment (from 6) • one C gene segment V23 D14 J3 *After maturation, the variable gene segment rearrangment (and therefore the epitope specificity) does not change.

  15. 8262 x (200 + 120) = 2.64 x 106 Thus, 2.64 x 106 DIFFERENT specificities are possible from the process of VDJ recombination alone 8262 x (200 + 120) = 2643840 = 2.64 x 106 A given immunoglobulin has either κ chains or λ chains, never one of each

  16. Note – There are several other forms of antibody diversification (eg, somatic hypermutation) that greatly increase the number of distinct antibodies that the immune system can generate. Thus, 2.64 x 106 DIFFERENT specificities are possible from the process of VDJ recombination alone (more than 1011 different specificities in total) No two B cells are likely to secrete the same Ig (unless they are clonal progeny), due to the number of different rearrangements that are possible within the variable region of the immunoglobulin locus

  17. Murray textbook, p75 Number of gene segment, wrong information: κ chain: 300 V, 5J H chain: 300-1000 V, 12D, 9J

  18. The Life of a B cell Naïve B cells die if they do not see antigen (Ag)Naïve B cells that encounter antigen (plus T cell help) : 1. become activated 2. undergo class switching 3. differentiate into either : plasma cells [antibody (Ab) secreting]or memory cells (non-secreting)

  19. When membrane-bound Ig (mIg) on the B cell surface binds to it’s specific antigen, the B cell becomes activated.

  20. Proper activation of the B cell typically requires contact with CD4 helper T (TH) cells.

  21. Activated B cells differentiate into : plasma cells (Ab secreting) or memory cells (non-secreting)

  22. Class switching (IgM to IgG, IgE, or IgA) occurs in response to different cytokines produced by CD4 helper T cells Class switching does not change the variable region

  23. 1 2 3 4 5 The usage of heavy chain constant gene segments changes with B cell activation in a process termed class switching but ...... epitope specificity does not change !

  24. Structures of the five major classes of secreted antibody Important because antibody classes differ with regard to biological properties

  25. IgG and IgA are divided into subclasses Subclasses differ in the number and arrangement of the interchain disulfide bonds.

  26. The principal immunoglobulins in plasma are IgG >> IgA > IgM vs. 0.0003 mg/ml 13.5 mg/ml

  27. Biological properties of antibody classes differ

  28. IgG levels are low from the age of 3 months to 1 year • IgG is the only isotype to cross the placenta • The transfer of IgG from mother to fetus (placental transfer) is mediated by an IgG transport protein in the placenta, FcRn, which binds to the Fc portion of IgG • Infant produces its own IgG at 6 months

  29. Endothelial cells of fetal capillary Villi Syncytio-trophoblast to the fetal circulation Maternal blood

  30. FcRn: neonatal Fc receptor for IgG

  31. Syncytiotrophoblasts are bathed in maternal blood and internalize serum containing maternal IgG. FcRn is expressed in the internal vesicles of the syncytiotrophoblast. On acidification in the endosome, FcRn binds to maternal IgG and transcytoses it to the fetal circulation where it is released at physiological pH.

  32. Dimeric IgA is the predominant in mucosal secretions The delivery of antibody to mucosal surfaces requires their movement across epithelial cell layers Transport is mediated by the polymeric immunoglobulin receptor (pIgR) IgA in colostrum, intestinal and respiratory tracts, saliva, tears Some pathogens produce proteolytic enzymes that can cleave IgA Haemophilus influenzae (respiratory), Neisseria gonorrhoeae (genital mucosa) Secretory component: part of the cleaved pIgR associated with the IgA

  33. Immunoglobulin isotypes are selectively distributed • IgE is found associated with mast cells beneath epithelial surface, including respiratroy tract, gastrointesitnal tract, and skin • IgD exists as membrane IgD, which serves with IgM as an antigen receptor on B cells, and activate B cell growth • In healthy individuals the Ig concentration in the central nervous system (CNS) is low.

  34. The humoral immune response to infectious pathogens

  35. The primary response to an initial antigen exposure • long lag phase • IgM is the first reponder • gradual switch to IgG • low affinity antibodies

  36. The secondary response to antigen exposure reflects immunological memory. • short lag phase • very rapid rise in titer • IgG predominates • high affinity antibodies

  37. EFFECTOR FUNCTIONS OF ANTIBODIES • Opsonization – the promotion of phagocytosis of antigens by macrophages and neutrophils. Protein molecules called Fc receptors (FcR), which bind the constant region of antibody, are present on the surfaces of phagocytes. • Activation of complement – IgM (most effective) and most subclasses of IgG can activate the classical complement pathway • Antibody-dependent cell-mediated cytotoxicity (ADCC) – The linking of antibody bound to target cells (virus infected cells, or some tumor cells) with FcR of natural killer cells (NK cells), neutrophils, macrophages, or eosinophils can result in killing of the target cell. • Neutralization of viruses and bacteria– Prevent attachment to cell receptors. • Neutralization of toxins

  38. Antibody-dependent opsonization of bacteria facilitates phagocytosis of the pathogen FcγR IgG opsonization     (op´sŏn-ī-zā´shŭn) The process by which bacteria and other cells are altered in such a manner that they are more readily and more efficiently engulfed by phagocytes. opsonin     (op´sŏ-nin) Any blood serum protein that binds to antigens, enhancing phagocytosis (e.g., C3b of the complement system, specific antibodies). [G. opson, boiled meat, opsonin: to prepare for a meal]

  39. Antibody-dependent activation of the complement pathway Potential outcomes : - lysis of bacteria via MAC - induction of inflammatory response - phagocytosis of bacteria IgM is the most efficient immunoglobulin for fixing (binding) complement (Murray p 102) “Complement fixation” = “Complement activation”

  40. Antibody-dependent cellular (cell-mediated) cytotoxicity (ADCC) kills the infected target cell =FcγR

  41. Infection of cells can be blocked byneutralizing antibodies

  42. Infection of cells can be blocked by neutralizing antibodies

  43. Antibody can prevent the attachment of bacteria to cell surface

  44. Many common diseases are caused by bacterial toxins

  45. Neutralization by IgG antibodies can protect cells from toxins

  46. Neutralization by IgG antibodies can protect cells from toxins

  47. Biological properties of antibody classes differ helminth killing Murray p73, Table 9-4 is inaccurate

  48. Effector functions of antibodies http://www.studentconsult.com/content/9780323054706/abbas_sped-up_animations/index.html https://www.facebook.com/406138889435131/videos/vb.406138889435131/866119870103695/?type=2&theater

  49. Questions (Murray p78) What is wrong with each of the following statements, and why? The laboratory tested a baby for IgM maternal antibodies. An investigator attempted to use fluorescent-labeled F(ab')2fragments to locate class II major histocompatibility complex molecules on the cell surface of antigen-presenting cells without cross-linking (binding two molecules together) these cell surface molecules. A patient is diagnosed as having been infected with a specific strain of influenza A (A/Bangkok/1/79/H3N2) on the basis of the presence of anti-influenza IgG in serum taken from the patient at the initial visit (within 2 days of symptoms). A patient was considered unable to use the complement systems because of a T-cell deficiency, which precluded the ability to promote class switching of B cells. Analysis of immunoglobulin genes from B cells taken from the patient described in statement 4 did not contain recombined VDJ variable-region gene sequences. A patient was considered to have a B-cell deficiency because serum levels of IgE and IgD were undetectable despite proper concentrations of IgG and IgM.

  50. Example of cross-linking by antibody Anti-HLA (MHC, major histocompatibility complex) antibody cross-link two HLA molecules, activating PI3K and mTOR

More Related