This document provides an overview of the immune system. It begins with definitions of immunity and the historical views of disease. It then describes the innate and adaptive immune systems in detail. The innate system includes physical barriers and the complement system. Adaptive immunity involves both humoral immunity through B cells and antibodies, and cell-mediated immunity through T cell subsets. Key immune cells like macrophages and neutrophils are also summarized in terms of their functions, including phagocytosis, antigen presentation, and cytokine secretion. The document provides an extensive but concise review of immune system components and their roles in protection from pathogens.
2. INTRODUCTION
•Immunity is a biological term that describes a state of
having sufficient biological defences to avoid infection,
disease or other unwanted biological invasion.
Immunity involves both specific and non-specific
components.
•It is defined as the resistance of a host to
pathogens and their toxic products.
3. HISTORICAL BACKGROUND
The prehistoric view of disease was that it was caused
by supernatural forces, and that illness was a form of
punishment for “bad deeds”.
Between the time of Hippocrates and the 19th century,
diseases were attributed to an alteration or imbalance
in one of the four humors (blood, phlegm, yellow bile
or black bile).
4. •Miasma Theory
•Chinese physicians in the eleventh century observed that
the inhalation of small pox crusts presented the
subsequent occurrence of the disease.
5. However, it was with Louis Pasteur’s Germ theory of
disease that the fledgling science of immunology began to
explain how bacteria caused disease, and how, following
infection, the human body gained the ability to resist
further insults.
Further development of preventive immunization were
made possible by Louis Pasteur (1881), who coined the term
“vaccine”.
6. Later Robert Koch discovered the tubercle bacillus and
developed his studies of bacterial etiology of infectious
diseases.
E. Metchin Koff (1880’s) elucidated the importance of
phagocytosis by leukocytes.
Paul Ehrlich (1908) proposed the humoral theory of
antibody formation.
7.
8. INNATE IMMUNE SYSTEM (IIS)
Nat Immunol. 2012
Front line of defense for the human body.
Different components of the IIS include:
1. Intrinsic barriers (Table 2)
2. Small molecules or peptides: the complement
proteins
3. Innate immune cells
11. 2. THE COMPLEMENT SYSTEM :
The complement system is comprised of small proteins synthesized by
the liver that enhance the strength and activity of an innate as well as the
adaptive immune response.
Upon activation of C3, a cascade of events takes place where each
precursor is cleaved into two parts (C3 à C3a and C3b, C4 à C4a and
C4b and so on) until C9a and C9b are generated (naming is due to their
activation in the sequence).
Studies have shown that phagocytic properties of neutrophils and macrophages
are significantly enhanced in the presence of complement proteins. Furthermore,
chemotaxis by cytokines is upregulated and bacterial killing is stronger with
different proteins of the complement system.
17. Natural or innate immunity is non-specific and is
considered as the first line of defense without antigenic
specificity.
It has 2 major components:
a) Humoral: comprised by complement.
b) Cellular: consists of neutrophils, macrophages, and
natural killer (NK) cells.
Specific or adaptive immunity is specific and is
characterised by antigenic specificity.
It too has 2 main components:
a) Humoral: consisting of antibodies formed by B cells.
b) Cellular: mediated by T cells.
18. ORGANS OF IMMUNE SYSTEM
Although functioning as a system, the organs of
immune system are distributed at different places in
the body. These are as under:
a) Primary lymphoid organs:
i) Thymus ii) Bone marrow
b) Secondary lymphoid organs:
i) Lymph nodes ii) Spleen iii) MALT (Mucosa-
Associated Lymphoid Tissue located in the respiratory
tract and GIT).
20. LYMPHOCYTES :
the master of immune system
Lymphocytes undergo maturation and differentiation
in the bone marrow (B cells) and thymus (T cells) and
Acquire certain genetic and immune surface
characters which determine their type and function;
this is based on cluster of differentiation (CD)
molecule on their surface.
CD surface protein molecules belong to
immunoglobulin superfamily of cell adhesion
molecules (CAMs). About 250 different surface CD
molecules have been identified so far.
21.
22. T-lymphocytes (T-cell) :
Produced in the bone marrow but mature in the thymus.
Have a unique antigen receptor, generated during development in the thymus.
This T-cell receptor (TCR) recognizes a specific peptide sequences bound to the major
histocompatibility complex (MHC) on APCs and the infected cells. This TCR and MHC
interaction allows T-cells to activate and proliferate.
MHC is a cell surface molecule that mediates interaction of immune cells with other immune
cells or body cells. In humans, MHC is also called human leukocyte antigen (HLA).
Each person inherits up to 6 class I molecules and 12 class II molecules. Each different
type of HLA molecule binds a different antigen sequence for presentation.
MHC class I molecules are found on all nucleated cells of the body. They present
cytosolic protein sequences, and cytotoxic T cells are main responding cell.
In contrast, MHC class II molecules are only found on lymphoid tissue cells. They
present proteins found in lysosomes and endosomes or extracellular pathogens, and T
helper cells are the responding cells.
23. T-CELL
These cells are implicated in inciting cell-mediated
immunity and delayed type of hypersensitivity.
T cells in circulation comprise 75-80% of
lymphocytes.
Pan T cell markers are CD3, CD7 and CD2. Besides, T
cells also carry receptor (TCR) for recognition of MHC
molecules.
Depending upon functional activity, T cells have two
major subtypes: T helper cells and T suppressor cells.
24. T cells
TH0
TH1
TH cells – CD4 Positive TH2
TH3
TH17
TC1
TC cells – CD8 Positive TC2
Double Negative T cells – CD4 Negative CD8 Negative
NK T Cells
Regulatory T Cells
25. T-HELPER CELL
Abbreviated as TH cells,
these cells promote and enhance the immune reaction and are also termed as T-
regulatory cells.
They carry CD4 molecule on their surface and hence are also called CD4+ cells.
CD4+ cells in circulation are about twice the number of CD8+ cells (CD4+/CD8 ratio
2:1).
These cells act by elaboration of variety of cytokines.
Depending upon the type of cytokines elaborated, these TH cells are further of two
subclasses:
TH 1 and TH 2.
TH 1 cells elaborate IL-2 and interferon (IFN)-γ.
TH 2 cells elaborate IL-4, IL-5, IL-6, and IL-10.
CD4+ cells are predominantly involved in cell-mediated reactions to viral infections
(e.g. in HIV), tissue transplant reactions and tumour lysis.
26.
27. Effector functions of TH cells:
TH cell activation and maturation will lead to release of
various cytokine and that can lead to:
1. B cell differentiation to plasma cell (TH2 response)
2. Activation of TC cells (TH1 response)
3. Activation or suppression of other cells such as
macrophages and NK cells.
28. T-SUPPRESSOR CELLS
Abbreviated as TS cells,
they suppress immune reactions but are cytotoxic and actually destroy the
invading antigen; hence are also termed as cytotoxic T lymphocytes (CTL).
These cells carry CD8 molecule on their surface and hence are also called
CD8+ cells.
CD8+ cells in circulation are about half the number of CD4+ cells.
Compared to CD4+ cells which act by elaboration of cytokines, CD8+ cells
are directly cytotoxic to the antigen.
CD8+ cells are particularly involved in destroying cells infected with viruses,
foreign cells and tumour cells.
29.
30. NK CELLS
NK cells comprise about 10-15% of circulating lymphocytes.
These lymphocytes do not have B or T cell markers, nor are these cells
dependent upon thymus for development unlike CD4+ and CD8+ T cells.
NK cells carry surface molecules of CD2, CD16 and CD56, but negative for T
cell marker CD3.
NK cells are morphologically distinct from B and T cells in being large
granular lymphocytes.
NK cells are part of the natural or innate immunity. These cells recognise
antibody-coated target cells and bring about killing of the target directly; this
process is termed as antibody dependent cell-mediated cytotoxicity (ADCC).
This mechanism is particularly operative against viruses and tumour cells
31. B-lymphocytes (B cells):
Produced and mature in the bone marrow.
Play the lead role in humoral immunity and mainly functions to produce various types of
antibody. Several different types of B-cells exist but only the major ones are discussed
here: memory B-cells and plasma cells.
Memory cells are formed from the activated B-cells specific for a certain antigen
encountered during an active immune response. These cells remain in the circulation for
long periods of time and respond immediately upon the exposure of the same antigen.
Plasma cells produce and secrete copious amounts of various antibodies. Each plasma cell
is specific for a specific antibody (one plasma cell cannot secrete all antibodies).
B-cell activation can be T-cell dependent or it can also be T-cell independent. Since MHC can
present peptide sequences only, carbohydrate sequences directly bind B-cells and cross-link
antibody receptors (antibodies can act as B-cell receptors also) leading to B-cell activation.
32. While B cells differentiate into plasma cells which form specific
antibodies.
T cells get functionally activated on coming in contact with appropriate
antigen. Upon coming in contact with antigen, it is the macrophage, i.e.
specialised antigen-presenting cell such as dendritic cell, and the major
histocompatibilty complex (MHC) in the macrophage, which
determines whether the invading antigen is to be presented to B cells or
T cells. Some strong antigens that cannot be dealt by antibody response
from B cells such as certain microorganisms (e.g. viruses, mycobacteria
M. tuberculosis and M. leprae), cancer cells, tissue transplantation
antigen etc, are presented to T cells.
33. B-CELL
On coming in contact with antigen (e.g. invading microorganims), B
cells are activated to proliferate and transform into plasmacytoid
lymphocytes and then into plasma cells.
Depending upon the maturation stage of B cells, specific CD molecules
appear on the cell surface which can be identified by CD markers;
common B cell markers include: CD 19, 20, 21, 23.
These cells also possess B cell receptors (BCR) for surface
immunoglobulins (IgM and IgG) and Fc receptor for attaching to
antibody molecule. T cell help is provided to B cells by a subset of T
helper cells, TH 2, by elaborated interleukins (IL-4, IL-5, IL-10, IL-13).
35. CHEMOTAXIS
Once the leukocyte enters the connective tissue, it must be able to locate
and migrate to the site of insult. This is accomplished by chemotaxis,
which depends on the leukocyte’s ability to sense a chemical gradient
across its cell body and migrate in the direction of increasing
concentration.
The phagocyte senses only a limited number of chemicals: chemotaxins
for which it has receptors and chemotaxin receptors.
36. PHAGOCYTOSIS Phagocytosis is the process by which cells ingest particles of a size visible to
light microscopy.
Neutrophils and monocytes/macrophages are the only cells efficient enough
at phagocytosis to be considered “professional phagocytes.”
Phagocytosis results in the eventual containment of a pathogen within a
membrane-delimited structure, the phagosome
The immune system has evolved mechanisms of coating the pathogen with a
few recognizable ligands (opsonins), which enable the phagocyte to bind to
and ingest the pathogen. This is referred to as opsonization.
37. Phagocytes kill bacteria through two broad categories
of killing mechanisms.
One category is based on the reduction of oxygen and
is referred to as “oxidative.”
Oxidative mechanisms require
(1) the presence of oxygen and
(2) an oxidationreduction potential, Eh, at or above -
160 mV.
38. Microbicidal activity occurs by forming toxic, reduced-oxygen
metabolites such as superoxide anion (O2-) using the NADPH oxidase
system.
The superoxide anion also contributes to the formation of hydrogen
peroxide (H2O2), which is capable of diffusing across membranes.
In the presence of H2O2 and chloride, MPO catalyzes the formation of
hypochlorous acid (HOCl).
39. Second category of killing mechanisms, the nonoxidative mechanisms.
It requires phagosome-lysosome fusion, phagolysosome.
It results in the secretion of lysosomal components into the phagolysosome.
Less than 30 seconds after phagocytosis, neutrophils secrete specific granule
components into the phagolysosome.
Specific granules contain several microbiocidal components, including
lysozyme and lactoferrin.
Lysozyme is an enzyme that possesses enzymedependent bactericidal activity
and enzyme-independent bactericidal and fungicidal activity.
Lactoferrin is a bacteriostatic compound that contains a bactericidal peptide
domain, lactoferricin.
40.
41. MONOCYTE & MACROPHAGE
Circulating monocytes are immature macrophages and constitute about
5% of peripheral leucocytes.
They remain in circulation for about 3 days before they enter tissues to
become macrophages.
The macrophage subpopulations like the dendritic cells found in the
lymphoid tissue and Langerhans’ cells seen in the epidermis, are
characterised by the presence of dendritic cytoplasmic processes and are
active in the immune system.
43. 1. Antigen recognition
They possess cell surface receptors to several extracellular molecules—
receptor for cytokines, component of complement (C3b), selectins,
integrins and Fc (constant fragment) of antibody.
These receptors recognise the organisms and initiate intracellular
mechanism in macrophages.
Antigen to become recognisable can also get coated by antibodies or
complement, the process being termed as opsonisation.
Macrophages have capacity to distinguish self from non-self by
presence of human leucocyte antigens (HLA) or major histocompatibilty
complex (MHC).
44. 2. Phagocytosis
Antigen that has been recognised by the macrophages
due to availability of surface receptors, or the
opsonised antigen, is ready to be engulfed by the
process of cell-eating by macrophages
45. 3. Secretory function.
Macrophages secrete important substances as follows:
i) Cytokines (IL-1, IL-2, IL-6, 8, IL-10, IL-12, tumour
necrosis factor-α) and prostaglandins (PGE,
thromboxane-A, leukotrienes) which are chemical
mediators of inflammation and activate other
leucocytes.
ii) Secretion of proteins involved in wound healing e.g.
collagenase, elastase, fibroblast growth factor,
angiogenesis factor.
iii) Acute phase reactants e.g. fibronectin,
microglobulin, complement components
46. 4. Antigen presentation
When macrophages are unable to lyse an antigen or an
organism, the next best course adopted by them is to
act as antigen-presenting cells for presenting to
immunocompetent T cells (subtype CD4+ or CD8+
cells) or to B cells. Accordingly, the lymphoid cell
would then deal with such antigen.
47. Antigens & Antibodies
ANTIGENS
An antigen (Ag) is defined as a substance, usually protein in
nature, which when introduced into the tissues stimulates antibody
production.
An antigen may induce specifically sensitised cells having
the capacity to recognise, react and neutralise the injurious
agent or organisms.
ANTIBODIES (Immunoglobulins):
An antibody (Ab) is a protein substance produced as a result of
antigenic stimulation. Circulating antibodies are immunoglobulins
(Igs) of which there are 5 classes: IgG, IgA, IgM, IgE and IgD.
48. Nature of Antigens
1. Extra cellular & intra cellular antigens
2. Pathogenic LPS
3. Non pathogenic LPS
4. P gingivalis
5. Super antigens & mitogens
50. Antigen Processing and Presentation
MHC is a locus on short arm of chromosome 6 (6p21.3)
that encodes MHC classes I,II, III, which are involved in
antigen uptake, processing and presentation.
MHC class I molecules: present intracellular antigens to
CD8+ T cells and NK cells.
MHC class II molecules: present extracellular antigens to
CD4+ Tcells.
MHC class III molecules include complement factors B,
C2 and C4.
51. Antigen Presenting Cells
Includes B cells, macrophages, dermal dendritic cells
and Langerhan cells
These cells naturally express MHC-II molecules to
activate specific effector T cells.
Generate antigen specific immune response to
periodontal pathogens.
52.
53. HLA SYSTEM AND
MAJOR HISTOCOMPATIBILITY
COMPLEX
HLA stands for Human Leucocyte Antigens because these antigens or
genetic proteins in the body which determine one’s own tissue from
non-self (histocompatibility) were first discovered on the surface of
leucocytes.
Subsequently, it was found that HLA are actually gene complexes of
proteins on the surface of all nucleated cells of the body and platelets.
Since these complexes are of immense importance in matching donor
and recipient for organ transplant, they are called major
histocompatibility complex (MHC) or HLA complex
54. Out of various genes for histocompatibility,
most of the transplantation antigens or MHC
are located on a portion of chromosome 6 of
all nucleated cells of the body and platelets.
These genes occupy four regions or loci—A,
B, C and D, on the short (p) arm of
chromosome 6 and exhibit marked variation in
allelic genes at each locus.
Therefore, the product of HLA antigens is
highly polymorphic.
HLA system is part of immunoglobulin
superfamily of CAMs.
55. 3 CLASSES OF HLA :
Class I MHC antigens have loci as HLA-A, HLA-B and HLA-C. CD8+ (i.e. T
suppressor) lymphocytes carry receptors for class I MHC and these cells are used to
identify class I antigen on them.
Class II MHC antigens have single locus as HLA-D. These antigens have further 3
loci: DR, DQ and DP.
Class II MHC is identified by B cells and CD4+ (i.e. T helper) cells.
Class III MHC antigens are some components of the complement system (C2 and C4)
coded on HLA complex but are not associated with HLA expression and are not used
in antigen identification.
In view of high polymorphism of class I and class II genes, they have a number of
alleles on loci numbered serially like HLA-A 1, HLA-A 2, HLA-A 3 etc.
MHC antigens present on the cell surface help the macrophage in its function of
bacterial antigen recognition i.e. they help to identify self from foreign, and
accordingly present the foreign antigen to T cells (CD4+ or CD8+) or to B cells.
56. MHC classes I, II, and III molecules, which are involved with antigen uptake,
processing, and presentation.
All cells process and present self derived antigens (intracellular antigens) in
association with MHC class I molecules.
MHC class I molecules are used to present intracellular antigens to CD8+ T cells and
NK cells.
MHC class III molecules include complement factors B, C2, and C4.
Antigens derived from extracellular sources are presented by professional antigen-
presenting cells (APCs) in association with MHC class II molecules.
The three main professional APCs are
peripheral DCs,
monocyte derivatives, and
B cells.
57. CO-STIMULATION
The interaction between two cells permits a high level of sophistication
unattainable by the simple interaction of two molecules, enabling the
APC to present antigen to the T cell with a second signal.
The most important second signal is called co-stimulation. Co-
stimulation reaffirms to the T cell that it has recognized an undesirable
antigen.
In the absence of co-stimulation, T cells may become unresponsive or
apoptotic and die.
58.
59. Activation – Signal transduction
Co-stimulation – B71 & B72 interaction
with CD28.
60. TOLL LIKE RECEPTORS
A receptor molecule named “toll,” first identified in fruit flies
(Drosophila spp.), was shown to be important in certain responses to
injury or infection.
The human toll-like receptors (TLRs) are stimulated by highly
conserved bacterial components such as LPS and are important in
dictating the adaptations found in the innate immune system.
TLRs cause APCs to upregulate the co-stimulatory B7 molecules.
Although T cells may constantly interact with antigen, co-stimulation
enables this interaction to progress to T-cell proliferation.
61. SPECIFIC IMMUNE RESPONSES:
Chronic inflammation, if protracted, can result in an adaptation called the
specific immune response.
The specific immune response requires lymphocytes, which use two types of
receptors, to generate
specific immune responses, the B-cell antigen receptor (BCR) and the T-cell
antigen receptor (TCR).
Four phases are involved in the generation of specific immunity:
(1) clonal selection, the selection of lymphocytes that bear receptors (BCRs or
TCRs) recognizing the specific antigen;
(2) clonal expansion, the proliferation of those lymphocytes;
(3) clonal contraction, the death of “effector” lymphocytes; and
(4) memory, the maintenance of an expanded clone of cells that bears the
specific receptors (BCRs or TCRs) recognizing the antigen .
As long as a sufficient number of lymphocytes are maintained to provide
protection against a specific antigen, the individual is said to be “immune.”
62. Protective immunity is achieved if an adequate number of the lymphocytes are maintained in the memory
phase, and the individual is said to be immune.
this does not always occur because an individual (1) may not undergo sufficient clonal expansion, (2) may
undergo excessive clonal contraction, or (3) may be unable to maintain memory.
(Modified from Ahmed R, Gray D: Science 272(5258):54, 1996.)
64. Specific Immune Responses
Four phases are involved:
Clonal Selection: selection of lymphocytes that bear
receptors (BCR’s or TCR’s) recognizing the specific antigen.
Clonal Expansion: proliferation of those lymphocytes.
Clonal contraction: death of “effector” lymphocytes.
Memory: the maintainence of an expanded clone of cells.
65. T-CELL RESPONSES
T cells may express 3000 to 50,000 TCRs on their
surface.
Antigens are presented to the TCR by MHC class I or II
molecules on the APC.
The TCR recognizes and binds the MHC-peptide
complex.
Antigen (Ag) is contacted by the TCR using variable
domains found at the Nterminus of the TCRα and β
subunits.
68. CD8 AND CD4
CD8 and CD4 are T-cell co-receptors, whose
recognition of MHC class I and II molecules,
respectively, on APCs is essential for T-cell function
and subsequent TCR activation.
Activation of these co-receptors increases the
excitability of the TCR and increases the binding
between the T cell and the APC.
69. The low affinity of the TCR enables the T cell to bind
APCs in a reversible manner, which occurs between
multiple TCRs and one or a few antigens over time.
This time-dependent interaction of many TCRs with a
few antigens is referred to as scanning.
Scanning that leads to T-cell activation is called serial
triggering.
To fully activate T-cells, multiple TCR engagement
must be sustained for 2 to 20 hours.
71. ACTIVATION OF T-CELL
proliferative differentiation.
begins with activation of the
protein tyrosine kinases lck, TCR
fyn, PLC
ZAP CD28
Activation of CD28
prepares the T cell to
receive the
costimulatory
signals, which are
important in T-cell
survival and function
Diacyl
glycerol
(DAG)
1,4,5-
inositol
triphosph
ate (IP3).
DAG signals the
activation of a
transcription-
activating
cofactor, NF-ATn
Ca+2
activation of a
calmodulin-
calcineurin
A/B
phosphatase.
dephosp
horylates
NF-ATc
active nuclear factor of activated T
cells
(NF-AT).
upregulates transcription of
genes, such as those for interleukin-2 (IL-2) and
the IL-2 receptor α subunit (IL-2Rα),
stimulate
proliferative differentiation
76. ROLE OF HLA COMPLEX
1. Organ transplantation. The greater the genetic disparity between
donor and recipient in HLA system, the stronger and more rapid will be
the rejection reaction.
2. Regulation of the immune system.
Class I and II histocompatibility antigens play a role in regulating both
cellular and humoral immunity:
Class I MHC antigens regulate the function of cytotoxic T cells (CD8+
subpopulation) e.g. in virus infections.
Class II MHC antigens regulate the function of helper T cells (CD4+
subpopulation).
77. 3. Association of diseases with HLA.
An increasing number of diseases have been found to have association
with some specific histocompatibility antigens. These disorders include
the following:
i) Inflammatory disorders e.g. ankylosing spondylitis.
ii) Autoimmune disorders e.g. rheumatoid arthritis, insulindependent
diabetes mellitus.
iii) Inherited disorders of metabolism e.g. idiopathic haemochromatosis.
78. Basophils and Mast Cells
Basophils are a type of circulating granulocytes (0-1%) while
mast cells are their counterparts seen in tissues, especially in
connective tissue around blood vessels and in submucosal
location.
Basophils and mast cells have IgE surface receptor; thus on
coming in contact with antigen binding to IgE (e.g. allergic
reaction to parasites), these cells get activated and release
granules i.e. degranulate.
These granules contain substances such as: histamine, platelet
activating factor, heparin and certain chemical mediators (e.g.
prostaglandins, leukotrienes).
Mast cells and basophils are thus involved in mediating
inflammation in allergic reactions and have a role in wound
healing
79. Neutrophils
Polymorphonuclear neutrophils (PMNs) are normally the most
numerous of the circulating leucocytes (40-75%).
The cytoplasm of PMNs contains lysosomal granules of three types:
primary (azurophilic), secondary, and tertiary.
PMNs have similar function to those of macrophages and are therefore
appropriately referred to as ‘microphages’ owing to their role as first
line of defense against an invading foreign organism in the body.
However, these cells have limitation of size and type of organisms to be
engulfed e.g. while they are capable of acting against bacteria and small
foreign particulate material but not against viruses and large particles.
80. Eosinophils
Eosinophils are also circulating granulocytes (1-6%).
These cells play a role in allergic reactions and in
intestinal helminthiasis.
The granules of eosinophils contain lysosomal
enzymes, peroxidases, and chemical mediators of
inflammation (e.g. prostaglandins, leukotrienes).
On coming in contact with IgE opsonised antigen
(e.g. helminths), eosinophils degranulate and release
the chemicals stored in granules and incite
inflammation
81. Hypersensitivity
It is defined as state of exaggerated immune
response to an antigen.
The lesions of hypersensitivity are produced due
to interaction between antigen and products
of immune response.
82. HYPERSENSITIVITY REACTIONS
TYPE I – Anaphylactic type
TYPE II – Cytotoxic type
TYPE III – Immune complex type
TYPE IV – Cell mediated or delayed type
TYPE V- Stimulatory or antireceptor
83. TYPE I – Anaphylactic type
It is defined as state of rapid developing immune response to
an antigen to which the individual is exposed.
It is mediated by IgE antibody and is due to powerful effects of
histamine.
It may be local / general depending upon the amount of histamine
released.
Local :- hay fever, bronchial asthma
Systemic :- bee stings, penicillin, horse serum
84. TYPE II – Cytotoxic type
These are defined as reactions which cause injury to
the cell by combining antibodies with cell surface
antigens.
IgG and IgM involved
Eg :-
• Mismatched transfusion
reaction
• Autoimmune haemolytic
anaemia
• Erythroblastosis foetalis
85. TYPE III – Immune complex type
These result from formation of immune complexes
by direct antigen antibody combination, causing
cell injury.
The formation of antigen-antibody complexes in
the serum , followed by deposition in tissues, is the
key event in causing these reactions .
86. 2 types of reactions occur:
a) Local: Arthus reaction- when rabbits were repeatedly
injected subcutaneously with horse serum, the initial
injections were without any local effect, but later injections
caused local oedema, induration and haemorrhage.
a) Systemic :Serum sickness-seen in persons who receive high
dose of horse antitoxin against tetanus, gas gangrene
After 7-12 days, there occurs fever,
lymphadenopathy, splenomegaly,
glomerulonephritis, endocarditis, urticarial
rash.
87. TYPE IV- CELL MEDIATED OR DELAYED
TYPE
It is mediated by sensitized T lymphocytes and
macrophages.
Occurs 24-48 hours after presensitization with antigen, hence
the name
Eg :-Tuberculin reaction
When a small dose of tuberculin is injected intradermally , an
indurated inflammatory reaction develops at the site of
injection within 48-72 hours
88. TYPE V – STIMULATORY OR
ANTIRECEPTOR
This an antibody mediated hypersensitivity where
antibody reacts with hormone receptors and stimulates
the cells.
Eg:- Thyroid hyperactivity in Graves disease due to
thyroid stimulating autoantibody