Diagnostic Immunology and Serology PDF

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This document is a lecture presentation about Diagnostic Immunology and Serology, covering the revision of basic immunological concepts, including innate and adaptive immunity, and the different components and functions involved.

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Diagnostic Immunology and
Serology
LM335
Dr. Hassan Kofahi
 Part I
Revision of the basic Immunological concepts
Introduction
Immunity is the resistance to diseases

Immunity

Innate Immunity Adaptive immunity
1. Non specific 1. Specific
2. Present at birth 2. Acquired later in life
3. Always ready 3. Activated and become ready
only after the encounter with
the microbe
4. Immediate response 4. Delayed response
5. Composed of the first and 5. Humoral and cellular responses.
second lines of defense.
6. No memory 6. Has memory
1st line of
defense

2nd line of
defense

Plasma cells Antibodies

Th1
Th2
CD4+ T cells (Helper)
Th17
Tfh
CD8+ T cells (Cytotoxic /CTL)
 Innate immunity

1st line: External defenses 2nd line: Internal defenses
 1st Line of Defense: External Defenses
Composed of physical, chemical, and
biological barriers
Prevent microbes from entering the body.
Skin
Physical barrier
Lactic acid and fatty acids maintain the skin at a
pH of approximately 5.6, which inhibits the
growth of pathogens
Psoriasin, a small protein produced by skin cells,
has antibacterial effects
Lysozyme—an enzyme found in many bodily
secretions such as tears and saliva—attacks
the cell walls of microorganisms
1st Line of Defense: External Defenses (continued)
Respiratory tract
Mucous traps microbes and prevents them from
adhering to epithelial cells
Cilia: expel mucus and the trapped microbes
Coughing/sneezing moves pathogens out of
tract
Genitourinary tract:
The flushing action of urine helps to remove
many potential pathogens
Digestive tract
Stomach’s acidity (pH = 1) kills microorganism.
Intestines: Normal flora (microbiota) prevent
pathogens from establishing themselves.
2nd line of defense: Internal defenses
 The second line of defense acts if the microbe do succeed in
entering the tissues or circulation.
Main Components
Cells
Macrophages,
Dendritic cells.
Granulocytes: neutrophils, eosinophils, basophils
NK cells.
Mast cells
Proteins
Complement proteins
Acute phase proteins
Cytokines
Macrophages
Main functions:
Ingestion and destruction of microbes.
Production of inflammatory cytokines.
Clearance of dead cells and initiation of tissue repair.
Antigen-presenting cell (APC).

Dendritic cells
Main functions:
Production of inflammatory cytokines.
The most efficient antigen-presenting cell (APC).
Neutrophils
Present in the blood in high numbers.
Functions:
The first cell to respond to infection.
Phagocytose and destroy microbes.
Generate neutrophil extracellular traps (NETs) that
help in killing the bacteria
Important for the defense against bacterial
infections.

Eosinophils
Functions:
Defense against parasitic infections.
Play a role in allergic reactions
Basophils
Circulate in the blood
Very rare
Functions: Inflammation and allergy

Mast cells
Reside in the tissues
Resemble basophils
Functions: Inflammation and allergy
Natural killer Cells (NK
cells)
Lymphocyte-like cells
Functions:
A. Kill virus-infected cells
and tumor cells
B. Activate the
macrophages to kill
phagocytosed microbes
Complement system
Series of proteins that normally present in an inactive form.
Infection triggers a cascade of cleavage and activation of these proteins.
The complement system can be activated by three pathways:
1. The classical pathway:
Initiated by antibody-antigen reaction.
2. The alternative pathway:
Initiated by the cleavage and activation of complement proteins directly on the
surface of the microbe.
3. The lectin pathway:
Initiated when mannose-binding lectin (MBL: a carbohydrate binding protein) which
binds to mannose on the surface of the microbe.
Complement activation results in

Inflammation
Opsonization and phagocytosis
Lysis of the microbe
Acute phase proteins
Present normally in the serum.
Produced by the liver.
Increase rapidly after infection.
Examples:

Protein Functions

C-reactive protein Opsonization, complement activation

Complement C3 Opsonization, lysis of the microbe

Mannose binding lectin Complement activation

Fibrinogen Clot formation
Inflammation
Inflammation is a tissue response
to infection or damage.
The purpose of inflammation is to
bring the mediators of host
defenses (cells & proteins) to the
site of infection or tissue damage.
Events:
Capillary widening (vasodilation)
which increases the blood supply to
the infected area
Increased capillary permeability
Extravasation and migration of the
white blood cells to the site of
infection.
Systemic responses: Fever and
increasing the proliferation of WBCs.
Signs: Heat, Redness, Swelling and
pain.
 Adaptive immunity

Humoral Cell-mediated

Antibodies T-lymphocytes
Cell-mediated immunity
Mediated by T lymphocytes.
CD4+ T lymphocytes (helper T cells)
Recognize peptide antigens displayed by MHC class II molecules.
Have several subsets, each perform distinct functions
Th1 activate the macrophages to kill the ingested microbe.
Th2 important in the defense against helminths.
Th17 induce inflammatory reactions to destroy extracellular bacteria.
Tfh Help in antibody production.

CD8+ T lymphocytes (Cytotoxic T lymphocytes, CTLs)
Recognize peptide antigens displayed by MHC class I molecules.
Main functions: Kill virus-infected and tumor cells.
Humoral immunity: Antibodies
Antibodies form the immunoglobulin family of proteins.
Produced by B-lymphocytes and plasma cells.
Antibodies exist in two forms:
Membrane-bound form act as B cell receptors.
Secreted form  effector molecules of the humoral immunity.
5 isotypes/classes: IgM, IgG, IgA, IgE and IgD.
Each isotype/class performs distinct effector functions.
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Antibody structure
Y-shaped molecule
Composed of 2 identical light chains and
two identical heavy chains.
Each monomeric antibody molecule has
two identical antigen-binding sites.
Regions:
Fab region: the arms of the Y shape.
Contains the antigen binding site.
Fc region: the stem of the Y shape.
Responsible for most of the effector
functions (e.g. complement activation).
Antigen, immunogen, hapten and epitope
Antigen: any substance that binds specifically
to an antibody or a T-cell receptor.
Immunogen: any substance capable of
inducing an immune response.
All immunogens are antigens but not all
antigens are immunogens.
Haptens are small molecules that are antigens
(i.e. can bind to the antibody) but are not
immunogenic unless they are attached to a
carrier protein.
Epitope: The part of the antigen that is
recognized by the antibody.
Antibody production for the lab use
The majority of the tests in the immunology/serology Lab
uses antibodies as one of the reagents.
Two types of Abs are used in the immunology/serology lab
Polyclonal antibodies
A collection of antibodies from different B cell clones that recognize
multiple epitopes on the same antigen.

Monoclonal antibodies
Antibodies produced by a single B cell clone. Recognize a single
epitope on the antigen.
Production of polyclonal antibodies

Other types of
animals are also
used including
goats, hoarses
and mice.
Production of monoclonal antibodies
Steps:

1. A mouse is immunized with a certain antigen (antigen X).
2. After a time, the mouse’s spleen cells are harvested.
Some of these cells are B cells that produces anti-X
antibodies.
3. Spleen cells are fused with myeloma cells in the presence
of polyethylene glycol (PEG) to produce hybridomas (i.e.
cells that resulted from the fusion between spleen cells
and myeloma cells).
 The myeloma cell are immortal (can grow
indefinitely).
 The fused hybridoma cells have the ability to:
A. Grow indefinitely in culture (acquired from the
myeloma cell).
B. Produce antibodies (acquired from the spleen B
cells).
Production of monoclonal antibodies
(continued)
4. All cells are placed in selection culture
medium.
This medium separates out the hybridoma cells by
allowing them to grow selectively and not allowing
unfused myeloma cells or spleen cells to survive.
5. Single hybridoma cells are placed in separate
wells of a microtiter plate and each is allowed
to grow to generate a clone, each derived
from a single hybridoma cell.
6. The supernatant of each clone is screened for
the presence of the desired antibody. Once
identified, a hybridoma is maintained in cell
culture indefinitely and produces a
permanent and uniform supply of
monoclonal antibody that reacts with a single
epitope.
 Polyclonal antibodies Monoclonal antibodies
Advantages Inexpensive Large quantities of
Quick to produce antibody can be produced
Recognize multiple Batch to batch
epitopes on the antigen. homogeneity
High specificity and less
cross-reaction
Disadvantages Limited quantities Expensive
Batch to batch variation Require more time to
Less specificity and produce
higher cross-reaction Recognize only one
epitope on the antigen.