Basic Immunology PDF

Summary

These lecture notes cover basic immunology. The document details the immune response of the body, including innate and adaptive immunity, and the different types of hypersensitivity reactions, and the organs and cells involved.

Full Transcript

Basic immunology

Professor

Abdel Nasser El Moghazy
 IMMUNOLOGY AND THE IMMUNE SYSTEM
 Immunity: The term immunity usually means resistance of the body
to pathogenic microbes, their toxins or to other kinds of foreign
substances
 Immunology
 Study of the components and function of the immune
system
 Immune System
 Molecules, cells, tissues and organs which provide non-
fi
specific and specific protection against
 Microorganisms Microbial toxins
 Tumor cells
 There are two main types of immunity :
 1. Innate or Inborn immunity. Natio
 It is present from the birth and is inherited from the mother to offspring
-

through the placenta. It is not acquired from the previous attack of
-

 2. Acquired or Adaptive immunity.
 It is not present from the birth but is acquired during one’s own life. It is
-

developed in response to a disease caused by the infection of microbes or
vaccine.
 Innate immunity

Innate immunity refers to nonspecific defense
mechanisms that come into play immediately or
within hours of an antigen's appearance in the body.
 Characteristics of Innate Immunity &

  It acts immediately as the first line of defense against infectious agents.
  Non-specific defense mechanism.
  Such mechanisms are present from birth
  Did not depend upon having previous contact with any particular
microorganism.
  Effective against a wide range of microorganism
Elements of Innate Immunity

 The elements of the innate (non-specific) immune system include:

 Anatomical barriers:(skin and mucosal membranes)

 Cells: (phagocytes, NK cells...)

 Humoral components: (complement, cytokines)
 First line Defense
1-SKIN Anatomical barriers

 It offers a physical and chemical barrier to bacteria. The physical barrier
comprises the dead outer keratinous layer, living epithelial cells and also the
thickness of the skin through which no bacteria can penetrate
 The skin is providing a protective cover to the body.
 It secretes some acids like Pyruvic acid and Lactic acid by sweat glands, which
creates acidic environment on the skin.
--
Acid pH inhibits growth of disease producing bacteria
 Bactericidal long chain fatty acids in sebaceous gland secretions
 1-SKIN First line Defense
Anatomical barriers

 One of the main functions of the skin is to protect the host from
invasion, and it does so by employing physical barriers,
biomolecules, and an intricate network of resident immune and
non-immune cells and skin structures
 It offers a physical and chemical barrier to bacteria. The physical barrier
comprises the dead outer keratinous layer, living epithelial cells and also the
thickness of the skin through which no bacteria can penetrate
 The skin is providing a protective cover to the body.
 It secretes some acids like Pyruvic acid and Lactic acid by sweat glands, which
creates acidic environment on the skin.
Acid pH inhibits growth of disease producing bacteria
 Bactericidal long chain fatty acids in sebaceous gland secretions
Biomolecules of the Skin 

Antimicrobial peptides (AMPs) and lipids are the main 
classes of biomolecules that participate in skin defense
by disrupting bacterial membrane

The most thoroughly studied AMP families in human 
skin are the defensins and the cathelicidins, which are
produced by a variety of cells in the skin such as
keratinocytes, fibroblasts, dendritic cells, monocytes,
and macrophages, and sweat and sebaceous glands
pH of the Skin 

The pH of human skin is 5.4‒5.9, which makes the 
skin an inhospitable environment for potential
pathogens.
Myeloid Cells 

Skin-resident myeloid cells include Langerhans 
cells, dermal dendritic cells, macrophages, mast
cells, and eosinophils..
2-Respiratory tract

 a. The hairs of the nose act as filter to foreign particles inhaled
with air
 b. The cough and sneezing reflexes help to expel foreign
particles.
 c. The sticky mucous layer fixes inhaled microbes, in addition
it contains antimicrobial substances
 Cilia, tiny muscular, hair-like projections on the cells
that line the airway, are one of the respiratory
system's defense mechanisms. Cilia propel a liquid
layer of mucus that covers the airways.
The mucus layer traps pathogens (potentially infectious 
microorganisms) and other particles, preventing them
from reaching the lungs.
Cilia beat more than 1,000 times a minute, moving the 
mucus that lines the trachea. Pathogens and particles
that are trapped on the mucus layer are coughed out or
moved to the mouth and swallowed
3.The gastrointestinal tract
 a. Human saliva has some antibacterial activity.
 b. The buccal cavity and the large intestine contain normal
bacterial flora which oppose establishment of pathogenic species.
 c. The hydrochloric acid and the digestive enzymes have
antimicrobial action
 35 /
4.The genito-urinary system
a. The frequent flushing during micturition is probably the most
important factor in maintaining sterility of the urethra.
 b. The acidic pH (5-6) of urine in healthy individuals is also a
protection against bacterial infection.
 c. The stratified epithelium of the adult vagina is resistant to
penetration by bacteria.
 d. The commensal lactobacilli produces a highly acidic vaginal
secretion by fermenting the glycogen, inhibiting the growth of
other bacteria
5.The conjunctiva

 a. Eyelids acts as a very efficient mechanical barrier.
 b. Tears are rich in lysozyme, the enzyme with
antibacterial action
 Second line of defense
Cellular Factors:

 Cellular factors. There are two major cellular components
involved in non-specific immunity, phagocytic cells
(Phagocytosis ) and natural killer cells
↳
Thiemer cell
 (A) Phagocytic cells:
 If an organism or foreign body penetrates an epithelial surface it
encounters phagocytic cells
 The phagocytic cells include macrophages and
Neutrophils, Basophils, Eosinophils.
 Their function is to engulf particles, including infectious agents,
internalize them and destroy them by process called phagocytosis
 Phagocytosis: It is a process by which phagocytic cells engulf
organisms and other foreign particles. The process of phagocytosis
involves the following steps :
 The stepes of Phagasskesis :
Phagocytosis
 1. Chemotaxis is the process by which phagocytes are
-

attracted to microorganisms.
-
 2. Attachment: The phagocyte then adheres to the
or
microbial cell. This adherence may be facilitated by
opsonization –
Enguitment
coating the microbe with plasma proteins.
~
 3. Ingestion: Pseudopods of phagocytes engulf the
microorganism and enclose it in a phagosome to
complete ingestion. 692
 4. Digestion: Lysosomes fuse with the phagosome to
form a digestive vacuole. The microbeSis killed and
-
-

digested. rick
mysosomes
6) Excretion enzymes
Phagocytosis

Figure 16.8a
 (B) Natural Killer Cells

 Natural killer (NK) cells attack virus-infected body
cells and cancer cells
 Killing of cells infected by intracellular
pathogens
eg. viruses and tumor cells
-

Release chemicals that enhance the inflammatory
response
 Biochemical Factors:
or Humoral factors

 The major biochemical factors are Interferon and Complement system.

 1-Interferon:
 These are group of soluble non-toxic glycoproteins produced in small
amount by all cells of the body.
 A special defense works specially against viral infection.
 They offer resistance by blocking viral m-RNA transcription there by
disrupting the viral life-cycle..
 The interferon reaches the uninfected cells; it makes them resistant to the
viral infection.
Biochemical Factors:

 2-Lactoferrin and transferrin:
 By binding iron, an essential nutrient for bacteria, these proteins limit
-

bacterial growth.
 3-Interleukin-1:
 a protein with numerous immune system functions,
 Including activation of T cells, endothelial cells, and macrophages;
 mediation of inflammation; and stimulation of the synthesis of
lymphokines, and collagenases.
Biochemical Factors
 4-Beta lysine: Bactericidal protein present in the blood and
secreted by the blood platelets.
5-C-reactive protein (CRP): serum proteins increased
rapidly following infection. CRP recognizes and binds, Ca++
found on a wide variety of bacteria and fungi
Biochemical Factors
6- Complement
The complement system consists of a number of small proteins found in the
blood, in general synthesized by the liver, and normally circulating as
inactive precursors (pro-proteins).
 Consists of ~30 proteins that complement the action of the immune
system
 Functions:
 Stimulate leukocytes
 Lyse bacteria
 Increase phagocytosis
 Pathogens
(such as bacteria,
& fungi, and viruses)

INNATE IMMUNITY Barrier defenses:
(all animals) Skin
Recognition of traits shared Mucous membranes
by broad ranges of Secretions
pathogens, using a small Internal defenses:
set of receptors Phagocytic cells
Rapid response Natural killer cells
Antimicrobial proteins
Inflammatory response

ADAPTIVE IMMUNITY Humoral response:
(vertebrates only) Antibodies defend against
Recognition of traits infection in body fluids.
specific to particular
pathogens, using a vast Cell-mediated response:
array of receptors Cytotoxic cells defend
against infection in body cells.
Slower response
 Specific (acquired immunity) 
 This is a specific reaction of the body against (Non- self), foreign
agents (called antigens), in which its immune products react
specifically with the stimulating agent, it is conventionally divided
into passive and active immunity, both of which may be either natural
or artificial (discussed in later).
 Specific immunity may be humoral (due to production of antibodies)
or
 cell – mediated (due to sensitization of T- lymphocyts)
 Acquired (Specific) Immunity
Humoral Immunity

Involves antibodies (secreted from B
cells) dissolved in the blood plasma.
Demonstrated as a immune response
using only the blood serum.
Defense against bacteria, bacterial
toxins, & viruses.
Acquired (Specific) Immunity

Cell-Mediated Immunity

Involves the activities of specific white
blood cells (T cells).
Defense against cancer cells, virus-
infected cells, fungi, animal parasites, &
foreign cells from transplants.
 =>-
 1-Natural active acquired immunity:
 It follows infections whether clinical (i.e. diseases) or sub clinical
 infections it leaves the individual with long- lasting immunity
(e.g.
 measles, mumps, small pox and poliomyelitis) or with immunity
of short
 duration (e.g. influenza virus).
 2- Artificial active acquired immunity:
 It follows immunization of the individual with one of the following
 immunizing agents:
-Live attenuated vaccines: (e.g.) BCG for (T.B) and Sabin vaccine for
(Poliomyelitis)
-Killed vaccines: (e.g.) Salk vaccine for (Poliomyelitis) and TAB for
(Typhoid and paratyphoid fever).
-Recombinant DNA vaccines: The genes responsible for the production of
certain immunizing bacterial or viral antigens are used in the
development of new, improved, or safe vaccines, (e.g.) hepatitis B.

:
g5 lis
 (B) Passive acquired immunity:
 Passive immunity involves either the transfer of antibodies or in
some diseases, of sensitized T-lymphocytes. The duration is short
– lived, depending on the life span of the transferred antibody or
cells and there be
 memory developed. Once the passive immunity disappears, the
host is again susceptible to the disease.
 Passive immunity may occur naturally or artificially:
 1- Natural passive acquired immunity:-
 It is transferred from mother to fetus (IgG) across the
placenta and via
 colostrums during lactation (IgA).
 The protective effect of this immunity
 remains for about six months after birth.
 2- Artificial passive acquired immunity:
 Involves administration of various antitoxins or gammaglobulines, as
in the treatment of tetanus, diphtheria, gas gangrene and snake bite.
 Administration of transfer factor, may be clinical importance in the
management of certain viral infections, fungal diseases, parasitic
infestation,
 bacterial, bacterial infections and tumor disorders.
 In certain diseases, for example tuberculosis and leprosy, immunity
can only be transferred by white blood cells from immune person, not
by antibodies.
 Basic immunology

Professor
Abdel Nasser El Moghazy
 Cells of Immune Systems

Innate Immunity: Granulocytes (neutrophils,
eosinophils, and basophils),
monocyte/macrophages, and natural killers
(NK) cells.

Specific Immunity: T-cells (thymus-drived),
B-cells (bursa derived), Antigen Presenting
Cells (APC). T-cells mediate cellular immunity
and B- cells mediate humoral immunity.
 Cells of TRANSPORT
ERYTHROCYTES, immune systems
OF 02 AND
CO2
LEUKOCYTES DEFENSE OF THE BODY
1. NEUTROPHILS PHAGOCYTOSIS
2. BASOPHILS PRODUCTION
Loading…OF HISTAMINE
3. EOSINIPHILS AGAINST CERTAIN
PARASITES AND SPECIAL PHAGOCYTOSIS
4. MONOCYTES PHAGOCYTOSIS
5. LYMPHOCYTES B CELLS—ANTIBODY
PRODUCTION
T CELLS—CELL-MEDIATED IMMUNITY
PLATELETS BLOOD CLOTTING
Cells of immune systems
1- Neutrophils (microphages):
Migrate to the site of infection (chemotaxis).
Posses phagocytic activity.
Produce inflammatory and immune mediators
such as prostaglandin and Interleukins
respectively.

2- Eosinophils (acidophils): Produce
histaminase, inflammatory and immune
mediators suchLoading…
as prostaglandin and
interleukins respectively.
Participate in anaphylactic hypersensitivity
reaction
 3- Basophils (in connective tissue called mast
cells):
Produce inflammatory mediators (histamine
and other vaso-active amines).
Participate in anaphylactic hypersensitivity
reaction
 4- Monocytes (macrophages):
Monocytes circulate in blood for 3 days, then
migrate to tissues and change to macrophages.
Macrophages make up the cells of the
reticuloendothelial system (RES). Usually
macrophages of the blood are referred as
monocytes and those found in connective
tissue are called histocytes e.g. in liver (Van
Kupffer cells), in lymph node (dendritic) and
in skin (Langerhans).
 Migrate to the site of infection (chemotaxis).
Posses high phagocytic activity.
Produce inflammatory and immune mediators such as
prostaglandin and interleukins respectively.
Posses receptors for Fc fragment of the antibody and
C3b fragment of the complement.
Digest M.O. and present them as antigens to
lymphocytes to induce specific immune response and
so are called antigen-presenting cells (APC).
Destroy cells having viral antigens on their surface
and antibody coated cells
 5- Natural killer cells (NK): kill tumor cells
and virus infected cells.
6- Killer cells (K): kill antibody coated cells.
7- Lymphocytes : there are two main subsets, B

So.
and T, the main characteristics of them are
listed below

ce ↳o
1-
x sIr
Cells Involved in Innate Immunity
Macrophase is respons to anti
acterial
Phagocytosis
Macrophag Presentation to I
e lymphocytes
Monocyte
Phagocytic
Anti-bacterial
Neutrophil
PMN
Anti-parasite
Immunity - Allergy
Eosinophil

?Protection of
mucosal surfaces? -
Basophil Allergy

Protection of
Mast cell mucosal surfaces - Allergy
 B-lymphocytes:
B-lymphocytes antibody secreting cells. Fully differentiated
B-cells that secrete high level of antibody are called plasma
cells. Mature B-cells that come into contact but not develop
into plasma cells are often referred to as memory B-cells

B lymphocyte precursors arise from lymphoid stem cells and
migrate, in birds to the bursa of Fabricius, a lymphoid organ
in the hindgut. Loading…
In mammals, which do not possess such a bursa, the bursal
analogue in the embryo is the liver or spleen, while in adults
B lymphocyte maturation into plasma cells (large
lymphocytes) takes place in the bone marrow
The mature B cells are then released into the circulation and
secondary lymphoid tissues and are involved in the
synthesis of specific immunoglobulin (antibodies).These B
lymphocytes constitute 15-30% of the total peripheral
lymphocytes and their life span is short (5-7 days).
 T -lymphocytes classification
According to their function. T cells are classified into four
subclasses:
1) T helper (Th) cells: which enhance T or B cell response
T-helper (TH): Produce interleukins (lymphokines or
cytokines) which stimulate T-cells, allow B-cells to proliferate
and differentiate and stimulate phagocytic activity by
phagocytes
2) T suppressor (Ts): which suppress T or B cell response. T-
suppressor (TS): modulate immune response by inhibiting
over immune reaction
3) T cytotoxic (Tcs) cells: which lyses virally infected cells,
tumor cells or grafts? T-cytotoxic (TC): able to kill virus-
infected cells, tumor cells and foreign rejected grafts
4) T delayed hypersensitivity (Tdh) which is the effectors
cells that produce lymphokins in response to antigenic
 stimulation. T-delayed hypersensitivity (TD): produce
Platomic B-lymphocytes T-lymphocytes
cas ,

Named after fabricus found in chicken and Named after thymus gland on which their
responsible for antibody formation. In maturation depends
humans, bursa equivalent includes bone
marrow, Peyers patches and appendix.
Constitute 30% of total lymphocytes Constitute 70% of total lymphocytes
Of short life span (days or weeks) Of long life span (months or years)
Upon stimulation, they proliferate and Upon stimulation, they proliferate and
fo
differentiate into plasma cells producing differentiate into effector T-cells. Some of
specific antibody or immunoglobulin “Ig” T-cells subsets produces lymphokines

Have receptors for antigens (usually IgM, or Have receptors for antigens called T-cell
IgD) called B-cell receptor (BCR) receptor (TCR)
Produce memory cells Produce memory cells
Have receptors for Epestein-Barr virus Form rosettes with sheep RBCS
Have glycoprotein markers on their surface
 Tissues of the Immune System
Primary Lymphoid Organs
1-Bone marrow: The bone marrow is the site
of blood cell formation after birth.
All blood cells are derived from stem cells.
These stem cells have the capacity for self-
renewal and differentiation into every type of
cell found in the blood
In mammals, mature B-lymphocytes develop
from stem cells in the bone marrow
 2-thymus: the thymus is derived into two
anatomically distinct regions. These regions
are the cortex and medalla.
I Pre-T-cells migrate
from the bone marrow to the thymus and enter
the cortex. About 90% of the cells die in the
thymic cortex the remaining 10% undergo a
process of differentiation. The 10% surviving
cells represent T-cells that can recognize
antigens on APC
it's derived into both of corfex and medulla
 Secondary Lymphoid organs
Spleen: The spleen is a major secondary lymphoid
organ. Foreign antigens in the circulation are filtered
through the spleen and come in contact with
lymphocytes and APCs that initiate a specific
immune response.
Fetal Liver: In the fetus, the liver is the
primary site of hematopoiesis.
Lymph nodes
Lymphocytes and APC in lymph nodes
 II-Adapive immunity (acquired
immunity)
Specific defense mechanism, effective against a
specific MO.

Depend upon having previous contact with a
particular microorganism.

Microorganisms that overcome the innate non-specific
immunity come up against the host's second line of
Dar formt
defense. Godig
 In this type of immunity, antigens of the
invading M.O. come in contact with cells of
the immune system (macrophages and
lymphocytes) to initiate the acquired specific
immunity which may be humoral (appearance
of antibodies) or cellular (cytotoxic effects
 Antigens (immunogens)
Antigens "Ags" are substances capable of acting as
10

specific stimulants for the specific immune
response.
Characterizes of antigens
1) Foreignness: only molecules that are foreign to
the circulation ofLoading…
an animal are immunogenic. The
more foreignness the more powerful the antigen
2) Molecular size: small molecules such as
monosaccharides and amino acids are not
immunogenic, while proteins and polysaccharides
are immunogenic.
 the specificatie
What is of
entigens
3) Specificity, only restricted portions of them
are involved in the actual binding with the
antibody combining sites. antigenic
determinants (epitopes).
Epitope or Antigenic Determinant: That
portion of an antigen that combines with the
products of a specific immune response

4) Chemical complexity: a molecule must
possess certain degree of chemical complexity
in order to be immunogenic.
5) Physical form: In general, particulate
/
 Hapten: Is a low molecular weight substance
which can not stimulate an immune response
by itself; however, if it is carried on a larger
molecules (e.g.Loading…
if it is bound to a protein
carrier), it becomes antigenic and can induces
a specific immune response and react
specifically with it, (e.g. polysaccharide
capsule of pneumococci).
 Common types of
I
antigens:
a. Bacterial antigens: e.g.
cell wall (O), flagellar (H),
capsular and fimbrial
antigens. Also extracellular
antigens (e.g. exotoxins) and
intracellular antigens (e.g.
 Antibodies Immunoglobulins
Antibody (Ab): A specific
“Igs” protein which is
produced in response to an immunogen and
which reacts with an antigen

Antibodies are glycoproteins synthesized and
S i

secreted by plasma cells in response to
antigenic stimulation of B cells. They are
present in the serum and tissue fluids of all
mammals and responsible for immune
reactions called (Humural immunity or
antibody mediated immunity).
 Structure of immunoglobulin molecule (Ig)
Basic structure: The basic unit
of Ig molecule is formed of four
polypeptide chains; two light and
two heavy chains hold together by
inter chain disulphide bonds.
Light chains: These are two
identical short chains, each consists
of about 200 amino acids.
According to the amino acid
sequence, there are two types of
light chains; kappa and lambda. The
Ig molecule contains either kappa
 According to the amino acid sequence, there
are five types of heavy chains; gamma, alpha,
Mu, delta and epsilon. According these types
of heavy chains, there are five types of
immunoglobulins (IgG, IgA, IgM, IgD and
IgE )
Disulphide bonds: There are two types of
disulphide bonds:
Inter chain disulphide bonds: These are three
bonds. The first bond is present between the
two heavy chains. The other two bonds; each
joins a light chain with the adjacent heavy
chain.
 Each light and heavy chain consists of two
regions:
The variable (V) region: It is a segment
formed of one domain called the variable
domain since it shows marked variations of its
amino acid sequence. The variable region is
present in the amino (N) terminal portion of
the chain.
The constant (C) region: The rest of the Ig
molecule shows little variation and relatively
constant in its amino acid sequence. The
constant region is present towards the carboxy
(C) terminal portion of Ig molecule.

Loading…
 ThereTypes
are fiveoftypes
immunoglobulins
of immunoglobulins
(IgG, IgA, IgM, IgD and IgE ). They differ
from each other in size, charge, amino acid
composition, and carbohydrate content.
1. IgG: Is the major immunoglobulin, and
comprises about 70- 75% of the total
immunoglobulins in normal human sera. IgG is
monomeric protein. It predominates in
secondary antibody response against bacterial,
viral and fungal infections and it is the only
type that can pass through the placenta.
 2. IgM: Is the largest of the immunoglobulin
molecules; it has pentameric structure. It
comprises about 10% of immunoglobulins in
normal serum. The greater size of IgM
molecule is due to five units (each similar to
one IgG unit), linked through disulphide bonds

3.IgA: It is found to small extent in serum
(serum IgA), but predominantly in the external
seromucous secretions of the respiratory,
gastrointestinal, and genitourinary tracts,
including tears, sweat, saliva, and milk
(secretory IgA).
 4. IgE:. It has a special attraction to mast cells
and basophils. IgE play an important role in
hypersensitivity reactions and in defense against
parasitic infections.

5. IgD:. Its function is unknown; but it has been
suggested that IgD on B cells prevents the
development of immunological tolerance when the
cell encounters an antigen.
 Mechanism of antibody
When an antigenproduction
enters the body, it is trapped by
phagocytic cells and transported to the local lymph
nodes.
Antigens which are disseminated by the blood
stream are trapped by the endothelial cells in the
spleen.
The second step is digestion of the particulate
antigen into the macrophages then presenting the
antigen to the B lymphocytes.
The third step is that of antigen recognition by B
lymphocytes by two parameters; being foreign and
its antigenic determinants

Theories for antibody formation:
1) Instructive (Template) theory:
This suggested that antigen acts as a template
around which a standard unfolded gamma
globulin chain could be molded to provide a
complementary shape of the antigen. The
produced immunoglobulin molecule will
stimulate the B lymphocytes to produce other
immunoglobulin molecules with the same
shape.
 2) Colonal selection theory:
This theory is widely accepted. It assume that each
individual has a very large number of different
classes of lymphocytes, each class is called clone
(class of lymphocytes and its progeny), and each
clone is capable of responding to only one antigen
When the antigen is introduced into the body it
selects the best "fit" clone by means of surface
receptors (antibody molecule) and stimulate it to
differentiate into plasma cell that multiply and
produce antibodies
 Monoclonal antibodies
A monoclonal antibody is an antibody that is
specific to a single antigen. In vitro hybridoma
technology was used to synthesize monoclonal
antibodies.
Hybridoma technology involves fusion of myeloma
cells with plasma cell derived from the bone marrow
or spleen of a host immunized with the appropriate
antigen. The resultant hybrid cells are called
hybridoma; separated out as single clones and
continue to proliferate unchecked as a malignant cell
and secretes the products of the two parent cells.
 Clinical application of the monoclonal
antibodies:
1. Diagnosis of infectious diseases ( Known
monoclonal antibody + unknown organism).
2. Assay of hormones.
3. Identification of cell-surface markers.
4. Isolation and purification of human
products prepared in bacteria(by genetic
engineering), e.g. vaccines and interferons.
5. Passive immunization (to transfer a
specific artificial passive acquired immunity).
6. A possible therapeutic role in tumors.
 Antigen dose response relationship:
The time interval between the introduction of
an antigen and the appearance of full immune
response could be divided into two stages
a) inductive stage: the introduced antigen is
first phagocyted by a macrophage, which do
not produce antibodies, but it process the
antigen in some way and present it to "B" cells
in the form of activated antigen. In most cases
the induction may require the collaboration of
"T" helper cells together with the
macrophages.
 b) productive stage: in this stage the activated
Primary and secondary antibody
Primary response
response
Following the first dose of antigen
administration there is a lag phase where no
antibodies can be detected (inductive stage).
This is followed by a phase in which the
antibody titer rises logarithmically reaching a
small plateau and finally decline again. IgM
appears first then IgG, but IgM concentration
declines more rapidly than IgG
 No
las Phas
Secondary response
When an animal is reinjected with the same
antigen weeks, months or even years after the
primary antibody have subsided, there is a
more rapid antibody response and to a higher
level and for a longer period. This may be
explained to be due to the presence of antigen
sensitive memory cells. During the secondary response, the level of
IgM is more or less the same as the primary
response, whereas IgG production is far greater
 Items Primary Secondary

Definition. Introduction of an Secondary or
antigen for the first time. subsequent exposure to
the same antigen.

Slow (a latent period of Rapid (within few
several days before hours to few days).
Onset.
response).
Low; (gradual increase). High (rapid increase).

Antibody level.
For short duration (the For long duration
antibody decreases (months or years).
Persistence. rapidly). ·Predominately

Absent before primary Present during
exposure secondary or subsequent
Immune memory. immune response.
 Immunization
Artificial passive immunization
Live vaccines: Before a live organism can be
administered as a vaccine, it must be
attenuated, i.e. rendered harmless. This is most
frequently achieved by growing the organism
and then frequently sub culturing it in the
laboratory. Such propagation under unnatural
conditions tends favor the emergence of
mutant strains that are not harmful to the
human host. Live vaccines produce an
ongoing stimulus to the immune system due to
the multiplication of the M.O. in the host
 Killed Vaccines: These vaccines are completely
safe but the immunity conferred by them, even
when given with adjuvant, is often inferior to
that resulting from live vaccine or natural
infection. Because self-replication of the
microorganism does not occur, booster doses
of vaccine are necessary

Moreover, injected killed vaccine (e.g. cholera)
may stimulate systemic antibody synthesis
without initiating an adequate response in the
intestine, i. e. the site of natural infection
 Toxoids: In diseases such as tetanus and
diphtheria, the organisms multiplying locally
producing potent exotoxin responsible for life-
threatening effects on heart and nervous
system. These exotoxins, when purified and
inactivated with formalin are known as toxoids
which are non-toxigenic but are still antigenic.
When toxoids are combined with an adjuvant,
their administration leads to the production of
antitoxin by the recipient
 Genetically engineered products: In diseases
when the causative agent cold not be cultivated
e.g. hepatitis B.
 Bacterial products: (e.g.) toxoids of
diphtheria and tetanus.
Recombinant DNA vaccines: The genes
responsible for the production of certain
immunizing bacterial or viral antigens are used
in the development of new, improved, or safe
vaccines, (e.g.) hepatitis B, Vibrio cholerae
and meningococcus

X
 Immune tolerance
Immune tolerance: A state of unresponsiveness
to a specific antigen or group of antigens to
which a person is normally responsive.
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Immune tolerance is achieved under conditions
that suppress the immune reaction and is not
just the absence of a immune response.

Immune tolerance can be defined as a state in
which a T cell can no longer respond to
antigen. The T cellX"tolerates" the antigen.
 Immune tolerance can result from a number of
causes including:
Prior contact with the same antigen in fetal life
or in the newborn period when the immune
system is not yet mature;
Prior contact with the antigen in extremely
high or low doses;
Exposure to radiation, chemotherapy drugs, or
other agents that impair the immune system;
Heritable diseases of the immune system;
Acquired diseases of the immune system such
as HIV/AIDS. X
The Complement system
 The complement system
A defensive system consisting of over 30
proteins produced by the liver and found in
circulating blood serum.
Complement kills microbes in three
different ways
– 1. opsonization
– 2. inflammation
– 3. Cytolysis
 ⑤
General Properties of Complement
Synthesized mainly by liver hepatocytes.
Most circulate in the serum in functionally inactive forms
Designated by numbers, by letter symbols.
Primary role is cell lysis.
Activity of complement destroyed by heating sera to 56 C for 30
minutes.
IgM and IgG are the only immunoglobulin capable of activating
complement (classical pathway).
Complement activation can be initiated by complex
polysaccharides or enzymes (alternative or properdin pathway).
The complement system contribute to chemotaxis,
opsonization, immune adherence, anaphylatoxin formation,
virus neutralization, and other physiologic functions
 Pathma
A Cascade system
The complement works as a cascade
system.
– Cascade is when one reaction triggers
another reaction which trigger others and so
on. These types of systems can grow
exponentially very fast.

30 profine in the
snrum
sette
From liver
 The Classical Pathway
The classical pathway is
considered to be part of
the specific immune
response because it relies
on antibodies to initiate it.

C1 becomes activated
when it binds to the ends
of antibodies
 The building of a C3 activation
complex
Once C1 is activated, it
activates 2 other complement
proteins, C2 and C4 by cutting
them in half
C2 is cleaved into C2a and C2b
C4 is cleaved into C4a and C4b
Both C2b and C4b bind together
on the surface of the bacteria
C2a and C4a diffuse away
 C3 Activation complex
I
C2b and C4b bind together
> -

on the surface to form a C3
activation complex

The function of the C3
activation complex is to
activate C3 proteins.
– This is done by cleaving
C3 into C3a and C3b
 C3b
Many C3b molecules are produced by the C3
activation complex.
The C3b bind to and coat the surface of the
bacteria.
C3b is an opsonin
– Opsonins are molecules that bind both to
bacteria and phagocytes
– Opsonization increases phagocytosis by
1,000 fold.

Opsonins
 C3a

C3a increases the inflammatory response by binding
to mast cells and causing them to release histamine
Building the C5 activation complex
Eventially enough C3b is cleaved that the
surface of the bacteria begins to become
saturated with it.
C2b and C4b which make up the C3
activation complex has a slight affinity for
C3b and C3b binds to them
When C3b binds to C2b and C4b it forms
a new complex referred to as the C5
activation complex
 The C5 activation complex
The C5 activation complex (C2b, C4b,
C3b) activates C5 proteins by cleaving
them into C5a and C5b

Many C5b proteins are produced by the
C5 activation complex. These C5b begin
to coat the surface of the bacteria.
Hypersensitivity reactions
The immune system is concerned with
protection of the host against foreign antigens,
particularly infectious agents.

Inappropriate immune response may be:
1.Allergy: exaggerated immune response
against environmental antigens.
2.Autoimmunity: misdirected immune
response against the host’s own cells.
3. Alloimmunity: immune response
directed against beneficial foreign tissues
e.g. blood transfusion or organ
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transplantation.
4. Immune deficiency: inability of the
immune system to protect the host.
 Hypersensitivity
Is an altered immunologic response to an antigen tha
results in tissue damage.
Hypersensitivity reactions:
inflammatory immune responses induced by repeated
antigen exposure resulting in host tissue damage.
Allergen:
is an antigen capable of stimulating hypersensitivity
reactions
Types of Allergen:
Exogenous:
1- Animal products.
2- Drugs ( penicillin)
3- Food : Egg albumen, Corn, peanuts, soybeans, milk,
and seafood.
4-. Mold spores. Loading…
5-Plant pollens.

Endogenous:
-Self antigen.
Types of Hypersensitivity:
Hypersensitivity reactions are divided according to

mechanism of action into four groups:

1-Type I (Immediate hypersensitivity).

2-Type II (Cytotoxic hypersensitivity).

3-Type III (Immune complex hypersensitivity).

4-Type IV (Cell-mediated hypersensitivity).
 Type I Hypersensitivity
It is also known as immediate or anaphylactic
hypersensitivity. The reaction may involve skin
(urticaria and eczema), eyes (conjunctivitis),
nasopharynx (rhinitis), bronchopulmonary tissues
(asthma) and gastrointestinal tract (gastroenteritis).
The reaction may cause from minor inconvenience
to death. The reaction takes 15-30 minutes from the
time of exposure to the antigen. Sometimes the
reaction may have a delayed onset (10-12 hours).
 Mechanism:
* First exposure to allergen
I

Allergen stimulates B lymphocytes to form antibody (IgE type).

IgE fixes, by its Fc portion to mast cells and basophils.

* Second exposure to the same allergen

The antigen fixes directly to IgE (which is already fixed to mast cell)
leading to activation and degranulation of mast cells and release of
mediators

These mediators cause vasodilatation, increased capillary permeability,
mucus hypersecretion, smooth muscle spasm, and tissue infiltration
with eosinophils, helper T cells, and other inflammatory cells.
 Mediators of Type I Hypersensitivity
Immediate effects
1. Histamine:
Vasodilatation and
increased vascular
2. Leukotrienes: permeability.

Bronchial smooth muscles contraction

3. Prostaglandin :
Causes bronchospasm.

4. Platelet activating factor (PAF) :

platelet aggregation, release of histamine, bronchospasm,
increased vascular permeability, and vasodilation

5. Eosinophil chemotactic factor（ECF-A:
6. Bradykinin:

Vasodilation
Clinical examples of type I hypersensitivity
1. Systemic anaphylaxis: a very dangerous condition

Allergic reactions after injection of drugs (penicllin) or serum

2. Respiratory allergic diseases :
1) Allergic asthma：acute response, chronic response
2) Allergic rhinitis, Allergic rhinoconjunctivitis

3. Gastrointestinal allergic disease
4. Skin allergy: Eczema (atopic dermatitis), Acute urticaria

9
Clinical examples on Type I Hypersensitivity:
1-Localized reaction in Skin:
Urticaria Eczema

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2-Systemic Anaphylaxis: In bloodstream.
Lethal effect.
 -Systemic Anaphylaxis
* Systemic form of Type I hypersensitivity
* Allergens:
Drugs: penicillin

* Clinical picture:
Shock due to sudden decrease of blood pressure, respiratory distress due to
bronchospasm, cyanosis, edema, urticaria

* Treatment: corticosteroids injection, epinephrine, antihistamines

set
 Methods of diagnosis Type I hypersensitivity
1) History taking for determining the allergen involved

2) Skin tests: 15 30 mi
-

Intradermal injection of different allergens
A wheal and (erythema) develop at the site of
allergen to which the person is allergic

3) Determination of total serum IgE level-
Radioimmunosorbent test (RIST)
 Management of Type I hypersensitivity
1) Avoidance of specific allergen.

2) Hyposensitization:
Minute quantities of the responsible allergen is injected in
increasing doses over a long period.

3) Drug Therapy:
corticosteroids injection, epinephrine, antihistamines
 Type II Hypersensitivity:
-Known as Cytotoxic Hypersensitivity. involve immunoglobulin G or immunoglobulin M antibodies
bound to cell surface antigens, with subsequent complement
fixation.

-Allergen could be:
1-Endogenous: Cell surface protein.
2-Exogenous: Drug metabolite adsorbed onto cell
membrane.

-Sites of occurrence of Type II reactions:
On cell surface (Example: RBCs).
* Mechanisms of type II hypersensitivity
reactions:
Complement-mediated cell lysis.
Complement fixation to antigen antibody complex on cell
surface. The activated complement will lead to cell lysis.

Phagocytosis mediated cell lysis.
Phagocytosis is enhanced by the antibody (opsinin) bound
to cell antigen leading to opsonization of the target cell

Both processes result in lysis of the Ab-coated cell
 Clinical examples of Type II responses include:
– Certain autoimmune diseases where Ab’s produced vs membrane
Ag’s
Grave’s Disease – Ab’s produced vs thyroid hormone receptor
Myasthenia Gravis – Ab’s produced vs acetylcholine recpetors
Autoimmune hemolytic anemia – Ab’s produced vs RBC membrane
Ag’s
– Hemolytic Disease of the Newborn
– Hyperacute graft rejection
Blood Transfusion
Graft rejection
Type III (Immune Complex) Reactions
Involve reactions against soluble antigens circulating in
serum.
Usually involve IgA antibodies.
Antibody-Antigen immune complexes are deposited in
organs, activate complement, and cause inflammatory
damage.
Glomerulonephritis: Inflammatory kidney damage.
Occurs when slightly high antigen-antibody ratio is
present.
Immune Complex Mediated Hypersensitivity

Kher 0
Type III Hypersensitivity:
- Clinical Examples on Type III Hypersensitivity.
--Two types:
1-Localized in skin: Example: Arthus reaction.
Intradermal injection of antigen in skin; necrotizing.
2-Systemic: Example: Serum sickness disease..
 Clinical Examples on Type III
Hypersensitivity
Local form (Arthus reaction):
Developed in persons injected with an
antigen intradermal or subcutaneous, to
which antibodies are found circulating in
the blood and so microprecipitate is formed
at the site of injection i.e. within the walls
of the local blood vessels e.g. during
frequent administration of insulin.
0
 Clinical Examples on Type III
Hypersensitivity
Systemic form (Serum sickness):
Developed in persons receiving large doses (10-12 ml) of
foreign serum such as horse diphtheria antitoxin or tetanus
antitoxin. Antibodies will be formed against the foreign
protein present in the horse serum. The antibodies formed
will react with the large quantity of the foreign protein "Ag"
remaining the blood. The resulting "Ag"-"Ab" complex
cause serum sickness. Serum sickness consists of
inflammatory changes in various organs e.g.
glomerulonephritis in kidney, myocarditis and valvitis in
heart, swelling in joints and urticaria in skin. 0
 Delayed hypersensitivity (Type IV)
- It is cell mediated and not antibody mediated.
Mechanism of delayed hypersensitivity
- Cells responsible for this type of hypersensitivity
are the sensitized T-lymphocytes i.e. it is associated
with cellular immunity. - The T cell necessary for
production of the delayed hypersensitivity are the T-
delayed hypersensitivity or TD cells, which become
sensitized to certain antigen
 Type IV (Cell-Mediated) Reactions
–.
– Reactions are delayed by one or more days (delayed
type hypersensitivity).
Delay is due to migration of macrophages and T cells to site of
foreign antigens.
– Reactions are frequently displayed on the skin: itching,
redness, swelling, pain.
– Anaphylactic shock may occur.
Accompanied by the release of lymphokines, and
consists of inflammatory changes.
- Has slow onset of action taking 24-48 hours to
reach maximum and persists for long time.
- Unlike other forms of hypersensitivity, it can not be
passively transferred from one animal to the other by
serum, but can be transferred by T-lymphocytes.
- Delayed hypersensitivity is classified into two types;
Tuberculin (Infection) type
Contact dermatitis type
 Tuberculin type –
– ID inoculation of PPD in sensitized individual leads to
indurations & inflammation in 48-72 hrs. This is not
same as skin test done for Type I hypersensitivity.
– Used for diagnosis / exclusion of diagnosis of many
bacterial / fungal / parasitic / viral and autoimmune
diseases.

0
Clinical example:
Tuberculin test:
Contact allergy (contact dermatitis)
Occur after sensitization with a variety of metals
e.g. nickel, chromium; chemicals e.g. potassium
dichromate and acrylates found in cloth; drugs e.g.
sulfa and penicillin in local cream or ointment; also
plant materials e.g. chlorogenic acids found in
some vegetables.
- Such substances are only antigenic after
combination with serum proteins i.e. they are only
haptens.
- The reaction consists of redness, swelling, itching,
vesicles, scaling and exudation
Summary
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 classification of hypersensitivity reaction

Type Description Time Mechanism, Typical manifestation

⑮Type I IgE-mediated 2-3min Ag induce cross-linkage Systemic anaphylaxis
hypersensitivity of IgE bound to mast cells Localized anaphylaxis:
or basophils with release -Hay fever, Asthma,
of vasoactive mediators Hives, Food Allergy
Eczema.
Type II Ab-mediated 5-8h Ab directed against cell- Blood-transfusion
cytotoxic surface Ags mediates cell reactions.
hypersensitivity destruction via C activation Erythroblastosis fetalis
Autoimmune hemolytic anemia.
 classification of hypersensitivity reaction

Type Description Time Mechanism Typical Manifestations

TypeIII Immune complex 2-8h Ag-Ab complexes Localized Arthus
-mediated deposited in various reaction
hypersensitivity tissues induce C acti- Generalized reactions:
vation and an ensuing Serum sickness,
inflammatory response Glomerulonephritis
Rheumatoid arthritis
SLE

Delayed reactions

Type IV cell-mediated 24-72h Sensitized TDTH cells Contact dermatitis,
hypersensitivity release cytokines that Tuberculous lesions,
activate Macrophages, Graft rejection.
which mediate direct
 The function of C5a

C5a disperses away from the bacteria.
– Binds to mast cells and increases
inflammation.
– Most powerful chemotactic factor known for
leukocytes
 Building the Membrane Attack
complex
C5b on the surface of bacteria binds to C6
The binding of C6 to C5b activates C6 so
that it can bind to C7
C7 binds to C8 which in turn binds to
many C9’s
Together these proteins form a circular
complex called the Membrane attack
complex (MAC)
&
-
 Membrane Attack complex
The MAC causes Cytolysis.
– The circular membrane attack
complex acts as a channel in
which cytoplasm can rush out
of and water rushes in.

The cells inner integrity is
compromised and it dies