IMMUNOLOGY

1. Basic Components of the
Immune System
Themba Hospital FCOG(SA) Part 1 Tutorials
By Dr N.E Manana

2. INTRODUCTION
• It is generally believed that the immune system evolved as the host’s
defence against infectious agents
• However, it may well play a larger role in the elimination of other
foreign substances, tumour cells and antibodies that attack self.
An immune response may be conveniently divided into two parts:
(1) A specific response to a given antigen
(2) A more nonspecific augmentation to that response

3. • Fig 1.1

4. Myeloid cells
• Divided into two main groups: the dendritic cell and the mature
macrophage.
• The dendritic cell’s major function is to present antigen to the
lymphocyte, and it is the earliest cell to recognize foreign antigen
• There are two forms of dendritic cells: immature and mature
• The induction of an adaptive immune response begins when a
pathogen is ingested by an immature dendritic cell
• This immature cell carries receptors on its surface that recognize
common features of many pathogens such as cell wall carbohydrates
of bacteria

5. Dendritic cells
• These cells reside in most tissues and are relatively long-lived, they are
derived from the same cell myeloid precursor as the macrophage
• Once the bacterium is in contact with these receptors, the dendritic cell
is stimulated to engulf the pathogen and degrade it intracellularly
• The main function of the “activated” dendritic cell is to carry pathogenic
antigens to the peripheral lymphoid organs to present them to T
lymphocytes.
• Once arrived, the dendritic cell matures into an APC, which now permits
it to activate pathogen-specific lymphocytes.
• Another function of activated dendritic cells is to secrete cytokines that
influence both the innate and adaptive immune responses

6. Macrophages
• The mature macrophage also derives from primitive stem cells in the
bone marrow, but unlike the lymphocyte, it matures in the tissues
• Thus monocytes, the precursors of mature macrophages, circulate for
only a few hours before entering the tissues
• Where they live for months as mature macrophages
• There is great variety in the tissue macrophages; they are
heterogeneous in appearance and metabolism.
• The primary function of these mononuclear cells is to phagocytose
invading organisms, dead cells, immune complexes, and antigens

7. Macrophages
• They include mobile alveolar and peritoneal macrophages.
• There are also fixed cells in the liver called Kupffer cells and skin macrophages
called Langerhans cells
• To do this, these cells are equipped with powerful lyososomal granules
containing acid hydrolases and other degrading enzymes.
• Macrophages need activation to carry out these functions.
• These include cytokines, which can bind to IgG: Fc receptors or most
importantly receptors for bacterial polysaccharides.
• In addition, they can be activated by soluble inflammatory products such as
C5a.
• In turn, the macrophages can release monokines, such as TNF or IL-1, which
increase the inflammation in inflamed tissues.

8. Neutrophils
• These cells produce adhesin molecule receptors, permitting them to
adhere to and migrate from the blood vessels to the site of infection
• They are attracted to the site by IL-8, C3a, and C3b, cytokines released by
TH1 cells, and mast cells
• These cells are also phagocytic cells, and the process of phagocytosis is
similar to that seen in macrophages.
• They are particularly effective when the invading organism becomes coated
with antigen-specific antibodies (opsonins) along with activated
complement components

9. Others
• NK cells also can kill target cells in the absence of either antigen or
antibody stimulation
• Their lineage is not known, but they are probably in some manner
related to T cells.
• Unlike other cells, they can be non-specifically activated by mitogens,
interferon, and IL-12.
• These cells are particularly useful in the early response to viral
infection
• NK cells have a broad range of specificity and no real memory

10. INITIATION OF THE IMMUNE RESPONSE
• The first step must involve modification of the antigen, and these
specialized cells are called APCs (Antigen presenting cells)
• Without such processing, T cells cannot recognize antigen
• Secretion of cytokines by APCs activated by antigen presentation that
further activates antigen specific T cells
• Antigen is presented to the T cells in the MHC complex present on the
surface of APCs
• The most efficient APCs are the dendritic cells

11. CYTOKINES
• They are secreted by macrophages (and T, B, epithelial cells and
fibriblast) and may act as stimulatory or inhibitory signals between
cells
• Cytokines that initiate chemotaxis of leucocytes are called
chemokines, other are interferons, interleukins, lymphokines and
TNFs
• Interleukins 1 (IL-1) and 2 (IL-2) are of particular importance
secondary to their role in amplifying the immune response
• IL-1 acts on a wide range of cells including T and B cells.
• In contrast, IL-2 primarily acts on lymphocytes

12. Specific immune response
The specific immune response may be divided into two parts (mediated
through the lymphocyte) :
(1) The humoral response
(2) The cellular response to a given antigen.
• Humoral responses are antibodies produced in response to a given antigen
• These antibodies are proteins, have similar structures, and can be divided
into various classes (immunoglobulins)
• Cellular immune responses require an intact Thymus, and are mediated by
T (Thymus) lymphocytes,
• While antibody producing cells are dependent on the bone (bursa) marrow,
are known as B cells.

13. Specific immune response
• Antigens, both foreign and self, are substances that may or may not
provoke an immune response
• Both T cells and B cells have receptors that recognize these antigens.
• In the case of B cells, antibodies on the surface are a major source of
antigen recognition, and once activated, they differentiate into plasma cells
that produce large quantities of antibodies
• T cells have similar receptors known as T-cell receptors (TCR), and in the
context of the major histocompatibility complex (MHC) molecules provide
a means of self-recognition functions.
• Some functions are carried out by messages transmitted between these
cells (interleukins or cytokines)

14. ANTIBODY
• FIG 1.2A 1.2B

15. Antibodies
• The IgM molecule is the oldest class of immunoglobulins, and it is a
large molecule consisting of five basic units held together by a J chain.
•
• The reason for this important physiological role is that it contains five
complement-binding sites, resulting in excellent complement
activation
• Because of its size, it does not usually penetrate into tissues
• In contrast, IgG is a smaller molecule that penetrates easily into
tissues.

16. Antibodies
• The major mucosal immunoglobulin, IgA, consists of two basic units
joined by a J chain
• IgA2 is the major IgA molecule in secretions and is quite effective in
neutralizing antigens that enter via these mucosal routes
• IgD is synthesized by antigen-sensitive B cells and is involved in the
activation of these cells by antigen
• IgE is produced by plasma cells and binds to specific IgE receptors on
most cells and basophiles

17. T CELLS AND THEIR RECEPTORS
• Each T cell is also committed to a given antigen and recognizes it by
one of two TCRs.
• These TCR2s are associated with a group of transmembrane proteins
on the CD3 molecule, which takes the antigen recognition signal
inside the cell
• The TCR complex recognizes small peptides presented to it by the
MHC class I and II

18. MAJOR HISTOCOMPATIBILITY COMPLEX
• Human histocompatibility antigens are also known as human
leucocyte antigens (HLA), synonymous with the MHC complex.
• These antigens are cell surface glycoproteins classified as type I or
type II.
• They can produce genetic polymorphism with multiple alleles at each
site, thus permitting a great deal of genetic variability between given
individuals
• Recognition of antigen by T cells is MHC restricted.

20. • Table 1.1

21. ANTIBODY PRODUCTION
• To achieve antibody production, at least four types of cells are
required: APCs, B cells, and two types of regulating cells
• Antibodies are produced by naïve B cells and are called plasma cells
• In the early stages, B cells first show surface IgM
• These cells can later express IgG, IgA, or IgE, a phenomenon known as
isotype switching
• Surface immunoglobulin act as its antigen-receptor site

22. ANTIBODY PRODUCTION
• A number of these B cells become memory cells so that a greater number
of antigen specific B cells are available on a secondary contact with the
same antigen.
• This phenomenon is known as clonal expansion and helps to account for
the greater secondary response
• B cells alone do not respond to antigen directly, even in the presence of
APC cells.
• They must have a second signal, normally provided by the T cells

23. Cellular Immunity
• Cell-mediated responses are implemented by T lymphocytes
• The major functions of T cells can be divided into two categories
- the first (cytotoxicity) is to lyse cells expressing specific antigens
(CD8+ cells is a potent killer of virally infected cells)
-The second (delayed hypersensitivity) is to release cytokines, thereby
triggering an inflammatory response

24. COMPLEMENT
• The complement component system consists of a series of heat-liable
proteins, and they normally exist as inactive precursors
• However, once activated each component may act as an enzyme and
cleaves the next component in the sequence
• The control of the sequence relies on either spontaneous decay or
specific inactivation
• Minor fragments play a role chemotaxis
• The major function of the complement system is to help in the
opsonization of microorganisms and immune complexes

25. COMPLEMENT
• The critical step in complement activation is the cleavage of the C3
component by complement-derived enzymes called C3 convertases.
• This results in the presence of C3b, which mediates a number of vital
biological activities
• Individuals who are deficient in C3 are obviously predisposed to
bacterial infections and immune complex disease

26. • Figure 1.9

27. Thank you