Immune System Lecture Notes PDF

Summary

These lecture notes cover the human immune system, detailing innate and adaptive immunity. It includes diagrams illustrating cellular processes.

Full Transcript

What is meant by Immunity?
Immunity means being protected from
something and being unaffected or not
bothered by it.

Immunity is the ability of the body to protect
itself from any danger whether coming from
outside or from inside.
 The Immune System
The immune system is the set of cells (mostly
WBCs) and tissues (spleen and lymph nodes)
which work to resist infection and harmful
effects induced by other living things.

The immune mechanisms help the host to
identify a pathogen, and neutralize its threat.
 The Immune System
The immune system can detect and identify
many different kinds of agents causing disease
e.g. viruses, bacteria and parasites.

The immune system can also detect a
difference between the body's own healthy
cells or tissues, and 'foreign' cells.
The Immune System
 The Innate Immunity
The innate immunity, also known as the non-
specific or in-born immunity comprises the cells
(Leukocytes) and mechanisms (Inflammation and
Phagocytosis) naturally present in all healthy
persons to defend them from infection by other
organisms.
It includes also the natural barriers of infection.
Natural Barriers of Infection
 Inflammation
Inflammation is one of the first responses of the
immune system to infection or irritation.
Inflammation is stimulated by chemical factors
released by injured cells.
Inflammation establishes a physical barrier
against the spread of infection, and promote
healing of damaged tissue following the clearance
of pathogens.
 Inflammation
The process of acute inflammation is initiated by
cells already present in all tissues, mainly
resident macrophages dendrite cells, histiocytes,
and mast cells.
At the onset of an infection, burn, or other
injuries, these cells release inflammatory
mediators (histamine, bradykinin, serotonin and
prostaglandins).
 Inflammation
Those inflammatory mediators sensitize pain
receptors, cause local vasodilatation of the blood
vessels, and attract phagocytes, especially
neutrophils.

They are causing the signs of symptoms of
inflammation including : pain, swelling, redness,
hotness and altered function.
 The Innate Immune cells
The innate immune cells (leukocytes) differ from
other cells of the body in that they are acting as
independent, single-cells not tightly associated
with a particular organ or tissue.
 The Innate Immune cells
Leukocytes are able to move and interact with
and capture cellular debris, foreign particles,
and invading microorganisms.

Within the immune system, leukocytes are
identifying and eliminating pathogens that
might cause infection.
 The Innate Immune cells
The innate leukocytes include:
1. Natural killer cells,
2. Mast cells,
3. Eosinophils,
4. Basophils; and
5. The phagocytes which include macrophages,
neutrophils, and dendritic cells.
 Mast Cells
They reside in connective tissue and in the
mucous membranes.
They are associated with wound healing and
defense against pathogens, but are also often
associated with allergy.
When activated, mast cells release histamine.
Histamine dilates blood vessels, causing the
characteristic signs of inflammation, and recruits
neutrophils and macrophages.
 Phagocytes
These are immune cells that engulf, or 'phagocytose',
pathogens or particles.

Phagocytes patrol the body searching for pathogens.

Phagocytes are able to react to a group of mediators
produced by other cells, called cytokines and
chemokines that attract and activate phagocytes.

The phagocytic cells of the immune system
include macrophages, neutrophils, and dendritic cells.
 Phagocytosis
1. To engulf a particle or pathogen, a phagocyte extends
portions of its plasma membrane, wrapping the
membrane around the particle until it is enveloped
(becoming inside the cell).
2. Once inside the cell, the invading pathogen is contained
inside an phagosome, which merges with a lysosome.
3. The lysosome contains enzymes and acids that kill and
digest the particle or organism.
Phagocytosis
 Phagocytosis
Phagocytosis of the hosts’ own cells is a part of
regular tissue development and maintenance.
When host cells die, phagocytes are responsible
for their removal from the affected site.
After that growth and development of new
healthy cells starts, thus phagocytosis is an
important part of the healing process following
tissue injury.
 Immunity
Immunity may be classified into:
A. Innate (non specific) immunity and
B. Adaptive (specific Immunity).
 Acquired (Adaptive) Immunity
It is a status of immunity against specific
agents to which the body has been exposed.

It is different in different persons and in the
same person in different times or conditions.

It is specific to certain agents not acting against
other agents.
 Acquired (Adaptive) Immunity
Adaptive immunity creates immunological
memory after an initial response to a specific
pathogen, and leads to an enhanced response to
re-infection with that pathogen.
It is acquired during life (in utero or after birth).
It is classified into passive and active acquired
immunity.
 Acquired (Adaptive) Immunity
 Passive acquired immunity is prepared in a host and
transmitted to another one (no active role played by the
immune system of the acquiring host).

 Active acquired immunity is made by the immune
system of a host after stimulation by an infecting or
harmful agent.

 Both passive and active immunity may be acquired
naturally or artificially induced.
 Acquired Passive Immunity
 Acquired passive natural immunity is
represented by immune reactions (antibodies)
passing from mother to infant during pregnancy
and through lactation.
 Acquired passive artificial immunity is
represented by antibodies prepared in horse
and given to human to protect against tetanus.
 Acquired Active Immunity
Acquired active natural immunity is represented
by immunity acquired against measles after
natural exposure to infection.

Acquired active artificial immunity is
represented by immunity acquired against HBV
after vaccination.
 What is the first step in phagocytosis?
A. Fusion between the lysosome and the vacuole
B. Killing the bacteria
C. Making a vacuole around the bacteria
D. Pseudopodia formation.

The Natural barriers of infections include all the
following Except:
A. Gastric acidity
B. Phagocytosis
C. Saliva
D. Skin.
 Passive acquired natural immunity is usually
acquired:
A. After getting infection
B. After vaccination
C. By giving antiserum after infection
D. From mother to her baby.
The Natural barriers of infections include all the
following Except:
A. Gastric acidity
B. Phagocytosis
C. Saliva
D. Skin.
 Skin and mucous surfaces are the only natural
barriers of immunity.

Cortisone is one of the Chemical mediators of
inflammation.

Signs and symptoms of inflammation include: pain,
hotness and swelling.

The last step of phagocytosis is the release of
microbial debris.
 Skin and mucous surfaces are the only natural
barriers of immunity.

Cortisone is one of the Chemical mediators of
inflammation.

Signs and symptoms of inflammation include: pain,
hotness and swelling.

The last step of phagocytosis is the release of
microbial debris.
Cells of the Immune System
 Cells Involved in Acquired
Immunity
Acquired immunity needs 2 main types of
immune cells:

1.The B lymphocytes or B cells: responsible about
antibody production ( Humoral immunity)

2.The T lymphocytes or T cells: responsible about
cell-mediated immunity (Cellular immunity).
Cells Involved in Acquired Immunity
Both cells are produced in bone marrow but
they complete their activation and education
in different parts: B cells are activated in
bone marrow (B) and T cells are activated in
the thymus gland (T).
 Cluster Designation (CDs)
 Each lymphocyte is carrying a molecule indicating its
cluster. This molecule is called CD (cluster designation)
and is marked by numbers e.g. CD4 or CD8.

 CD4 cells are generally having a helper function for
other B or T immune cells.

 CD8 cells are generally considered cytotoxic cells
capable of killing infected or harmful cells.
 Cytokines
 Cytokines (cyto, from Greek cell" + kines, from
Greek "movement") are a group of small proteins
(~5–20 kDa) that are important in cell signaling.
 Their release has an effect on the behavior of cells
around them.
 Cytokines are increasing or decreasing some cell
count and activity so they are considered immune-
modulating agents.
 Cytokines
Cytokines include interferon, interleukins, lymphokines,
and tumor necrosis factors.
Cytokines are produced by a broad range of cells,
including immune cells like macrophages, B
lymphocytes T lymphocytes and mast cells, as well
as endothelial cells, fibroblasts. A given cytokine may be
produced by more than one type of cell.
They act through receptors, and are especially
important in the immune system.
 Cytokines
Cytokines are named according to their functions
e.g. interleukins working in communication
between leukocytes (IL-1 to IL-28), TNF (tumor
necrosis factor) causing necrosis of malignant
cells, GCF (granulocyte colony stimulating factor)
increasing granulocyte production and IFN
(interferon) interfering with viral infections.
 Chemokines
Chemokines are a family of small cytokines
secreted by cells.

Their name is derived from their ability to
induce directed chemotaxis in nearby
responsive cells; they are chemotactic
cytokines.
 Chemokines
Types of cells attracted:
1. Monocytes / macrophages
2. T-lymphocytes

3. Mast cells

4. Eosinophils
5. Neutrophils
 T helper Cells
According to cytokines and chemokines T cells
may be sub grouped into Th-1 (T helper type 1)
and Th-2 (T helper type 2).
Th-1 cells are created by IL-12, IL-2 and they
produce IFN-γ.
Th-2 cells are created by IL-4 and they produce
IL-4, IL-5, IL-9, IL-10 and IL-13.
 Major Histocompatibility Complex
(MHC)
The major histocompatibility complex (MHC) is
a set of cell surface proteins essential for the
immune system to recognize foreign molecules.
The main function of MHC molecules is to bind
to antigens derived from pathogens and display
them on the cell surface for recognition by the
appropriate T-cells.
 MHC
The MHC determines compatibility of donors
for organ transplant, as well as one's
susceptibility to an autoimmune disease.

The human MHC is also called the HLA
(human leukocyte antigen) complex (often just
the HLA).
 MHC
The MHC family is divided into 2 subgroups:
MHC-I (class I) and MHCII (class II).
Class I MHC molecules have β2 subunits so can
only be recognized by CD8 co-receptors.
Class II MHC molecules have β1 and β2
subunits and can be recognized by CD4 co-
receptors.
 T-helper lymphocytes are:
A. Produced in the bone marrow and maturated in
the bone marrow
B. Produced in the bone marrow and maturated in
the Thymus gland
C. Produced in the bone marrow and maturated in
the thyroid gland
D. Produced in the Thymus gland and maturated
in the bone marrow
 To which of the following cells MHC-
II presents antigen?
A. B lymphocytes
B. Cytotoxic T- lymphocytes
C. Helper T-lymphocytes
D. Phagocytes

B lymphocytes are produced in the bone marrow
while T lymphocytes are produced from the thymus
gland.

CD8 cells are generally considered cytotoxic cells
capable of killing infected or harmful cells.

Th-1 cells are triggered by IL-12, IL-2 and their
effectors cytokine is IFN-γ.

MHC class II is found on virtually every cell except
RBCs.
Antigens and Immunogens
Antigens were first defined as foreign materials
capable of generating antibodies (Antibody-
generating substance).

After knowing that immunity is not only
antibodies the definition was changed to
substance generating immune response and the
word used became immunogen.
 Antigens and Immunogens
An antigen should be:
1. Foreign (non self): If self antigens are changed
by infection or degeneration they may become
antigenic.
2. Protein in nature: Proteins are potent antigenic
substances while lipids or carbohydrates are not.
3. Of big molecular size
Antigens and Immunogens
The healthy immune system should only react
against non-self antigens and the reaction is
dependent on the nature of the inducing agent.

Foreign antigens should come in an optimal
amount: If an antigen is coming in a very low
dose it may be neglected and if it is coming in a
very large dose it may be tolerated.
 Haptens
Haptens are small molecular size foreign
substances that may be neglected by the immune
system unless they are combined to a self protein
or being carried by a large molecular size lipid
or polysaccharides.

The immune reaction will be against the hapten
and the carrying protein.
Haptens
Antibodies (Immunoglobulins)
Antibodies were first defined as proteins
produced against foreign bodies (Anti- foreign
bodies).

Later they were proved to be made of gamma
globulins and they are produced from special
immune cells so they became named
Immunoglobulins (Ig).
Antibodies (Immunoglobulins)
Antibodies are usually produced in response to
a specific antigen and they can only react
against this antigen both in vivo (inside the
body to help removal or destruction of
harmful agents) and in vitro (in the lab for
diagnosis and identification of different
antigens).
Antibodies (Immunoglobulins)
An antibody is a large Y-shaped glycoprotein
molecule produced by activated B-cells and used
by the immune system to identify and
neutralize pathogens.

Antibodies are either secreted into circulation or
remain expressed on the surface of the B cell.
Antibodies (Immunoglobulins)
Antibodies are typically made of two large heavy
chains (H chain) and two small light chains (L
chain).
Both H and L chains are combined by di-sulphide
bonds.
Each chain has a constant (C) part and a variable
(V) part which differs according to the antigen
that produced this antibody.
V parts are sometimes called Fab (fraction
antigen-binding).
 Types of Immunoglobulins
IgA: It is called secretory antibody and is
present in saliva, breast milk and other body
secretions.

It is resistant to digestion by proteolytic
enzymes found in the gastrointestinal mucosa.

It is responsible for local immunity.
Types of Immunoglobulins
IgD: It functions mainly as an antigen
receptor on B cells that have not been exposed
to antigens.

It activates basophils and mast cells to
produce antimicrobial factors.

It has a minor role in immune reactions.
 Types of Immunoglobulins
IgE: It binds to allergens, triggering histamine
release from mast cells and basophils.

Also protects against parasitic worms.

It is the antibody that is increased in allergy or
hypersensitivity.
 Types of Immunoglobulins
IgG: It provides the majority of antibody-based
immunity against invading pathogens.
It is the only antibody capable of crossing
the placenta to give passive immunity to fetus,
and can activate the classical complement system.
It the antibody mostly detected in immune
reactions as it is the most abundant antibody in
the blood.
 Types of Immunoglobulins
IgM: Expressed on the surface of B cells
(monomer) and in a secreted pentamer with
very high avidity.
Eliminates pathogens in the early (primary
immune response) before there is sufficient IgG.
Like IgG, it can also activate the classical
complement system.
Its presence indicates early or active infection.
Types of Immunoglobulins
Primary and Secondary Immune Response
 How many Heavy Chains are present in a
molecule of IgM?

A. 2 Heavy chains

B. 4 Heavy chains

C. 5 Heavy Chains

D. 10 Heavy chains
 Which of the following cells are
producing antibodies?
A. Mast cells

B. Phagocytes

C. Plasma cells

D. T helper cells.
A true antigen should be foreign protein of
good molecular size.

Hapten is not antigenic alone.

Hapten combined to a body protein may
stimulate immune system to produce antibodies
against both of them.

Antibodies are immunoglobulins produced
from activated T cells.

Each molecule of immunoglobulin-D has 2
heavy chains and 2 light chains.
 Immune Reactions
Immune reactions are those occurring between
immunogen (antigen) and its specific antibody.
It can occur both in vivo and in vitro.
These reactions are known to be:
Specific: each antibody can react only with one
antigen. This is a base for using immune
reactions to identify an unknown antigen by
reaction with its specific antibody and vice versa.
 Immune Reactions
O
It needs optimum temperature: usually 37 C.
It can be seen only if the concentrations of both
antigen and antibody are equivalent.
If one of them is much higher the other the
reaction occur but cannot be seen.
The result of immune reaction is dependent on
the nature of the antigen.
 Agglutination Reaction
If the antigen is cellular or particles; the reaction
will lead to agglutination of these particles.
The best example of this type is the test done for
blood grouping (A, B, AB or O).
Agglutination may be done in a tube (tube
agglutination) or on a slide (slide agglutination).
Sometimes the soluble antigen is carried on inert
particle (latex) and then tested by agglutination
(passive agglutination).
Tube Agglutination Test
Passive Agglutination
 Precipitation Reaction
If the antigen is soluble reaction will lead to
precipitation making it detectable and easy to
remove.
It can be done in tubes (Tube precipitation or
Ring Test).
It can also be done on transparent agarose plates
making lines or rings of opaque precipitation
(radial immundiffusion).
Tube precipitation (Ring Test)
 Immune Reactions in vivo
1. Toxin neutralization: blocking the action of toxins
2. Virus neutralization: coating the viruses to prevent
them from binding to cells and preventing infection.
3. Opsonization: coating slippery (capsulated)
bacteria to facilitate the action of phagocytes.
4. Agglutination of bacteria to make it easier to
immune cells to remove them.
5. Precipitation of soluble antigens to make it easier
for kidney or liver to remove them from the blood.
 Tube agglutination test is done mainly to:
A. Detect soluble antigens
B. Fix complement
C. Know blood group of patient
D. Know the amount of antibodies in serum of a
patient.

Radial immune diffusion is a type of:
A. Agglutination reactions
B. Complement fixation reactions
C. Precipitation reactions
D. Toxin neutralization reactions
Agglutination is an immune reaction in which the
antigens are soluble.
Tube agglutination is used to determine blood
groups.
In tube agglutination we can know the amount of
the antibody in serum of infected persons.
Sometimes the soluble antigen is carried on inert
particle (latex) and then tested by agglutination
(passive agglutination).
Precipitation reaction done in tubes is called ring
test.
Radial immune diffusion is a precipitation
reaction done on transparent agarose plates.

The complement is a part of natural innate
immunity.

Complement triggers inflammation, Phagocytosis
and membrane attack.

Opsonization is an example of immune reactions
in vitro.