Immune System Presentation PDF

Summary

This presentation covers various aspects of the immune system, including phagocytes, macrophages, mast cells, NK cells, dendritic cells, and adaptive immune responses, along with B cells and T cells. It explains functions of each component.

Full Transcript

1. Phagocytes
▪ Phagocytes are specialized “eating” cells and there are
two main types, neutrophils and macrophages.
▪ Neutrophils, often called polymorphonuclear cells (PMNs)
because of the multilobed nature of their nuclei, are
mobile phagocytes that comprise the majority of blood
leukocytes.
▪ They have granules that contain peroxidase, alkaline and
acid phosphatases, and defensins, which are involved in
microbial killing.
▪ PMNs have receptors for chemotactic factors released
from microbes, for example muramyl dipeptide (MDP),
and for complement components activated by microbes.
Macrophages
▪ Phagocytic cells distributed throughout the
body.
▪ Monocytes are blood-borne precursors of
the major tissue phagocytes, macrophages.
▪ Different organs/tissues each have their
versions of monocyte-derived phagocytic
cells.

Mouse alveolar macrophages with
ingested bacteria
Phagocytosis
▪ Opsonization is the process of
making a microbe easier to
phagocytose. A number of molecules
called “opsonins” do this by coating
the microbe.
▪ They aid attachment of the microbe
to the phagocyte and also trigger
activation of phagocytosis.
▪ Opsonins include the complement
component C3b and antibodies
produced by activated B cells.
▪ Mononuclear phagocytes use their
surface receptors, which bind to C3b
or to the Fc region of IgG antibody.
Mast cells and Basophils
▪ Mast cells are tissue resident cells and
uniquely required for immediate
hypersensitivity. Basophils are circulating
cells, but home to areas of allergic
inflammation during the late phase
response.
▪ Both have large characteristic electron-
dense granules in their cytoplasm.
▪ Stimulation results in the fusion of the
intracellular granules with the surface
membrane and the release of their contents
by the process of exocytosis.
▪ This release is almost instantaneous and is
essential in the development of the acute
inflammatory response
NK cells
▪ NK cells are found throughout the
tissues of the body but cells mainly in
the circulation and are important for
protection against viruses and cancer
cells.
▪ Changes in the surface molecules of
cells as the result of virus infection
allow NK cells to bind to and kill
infected cells by releasing perforins
and inducing apoptosis.
▪ In addition, on binding to virus
infected cells, NK cells secrete
interferon gamma (IFNγ), which
protects adjacent cells from infection
by viruses and helps to activate T-cell-
mediated immunity.
Dendritic cells

▪ Link the innate and adaptive immune
systems.
▪ These cells have membrane folds that are
similar in appearance to dendrites of the
nervous system.
▪ These folds allow maximum interaction with
other cells of the immune system.
▪ DCs represent a primary interface between the
innate and adaptive immune systems in that they
recognize microbial antigens through PRRs, and
through cytokine production and antigen
processing and presentation they are able to
initiate adaptive immune responses by presenting
peptide antigens to T-helper (CD4+) cells.
▪ Although macrophages can process and present
antigen to T cells, the conventional DCs are much
more efficient in carrying out this function.
Adaptive Immune cells
▪ The two main types of lymphocytes, T cells
and B cells, mature in the thymus and bone
marrow, respectively.
▪ There are three main functional classes of T
lymphocytes: T helper (Th) cells, T cytotoxic
(Tc) cells, and T regulatory cells (Tregs).
▪ All T lymphocytes have antigen receptors (TCR)
that determine their specificity and CD3,
which is essential for their activation.
▪ These molecules also serve as “markers” to
identify T cells.
Cell surface markers of T cells:
CD3+CD4+: Th cell
CD3+CD8+: Tc cell
CD3+CD4+CD25+Foxp3+: Treg
T helper cell

Activation
 Helper T cells are arguably
the most important cells in
adaptive immunity, as they
are required for almost all
adaptive immune
responses.

They not only help activate
B cells to secrete
antibodies and
macrophages to destroy
ingested microbes, but
they also help activate
cytotoxic T cells to kill
infected target cells.
Cytotoxic T cell

NK cells have cytotoxic granules already formed and are ready to kill target cells.
CD8+ T cells don’t have cytotoxic granules until they have been activated by their cognate
antigen.
B cells

B cells are responsible for humoral
immunity.
On encountering a foreign
substance (antigen), the B cell
differentiates into a plasma cell,
which secretes antibodies.
Lymphoid organs produce large
numbers of B cells, each with
unique antigen receptors
(antibodies) such that, overall,
there is sufficient B-cell diversity
to recognize all of the antigens in
our environment (generate
diversity).
The B-cell receptor (BCR) is a transmembrane protein on the surface
of a B cell. A B-cell receptor includes both CD79 and the
immunoglobulin.
 B cell activation
be T-cell
independent or
dependent.

B cell activation
occurs in the
secondary
lymphoid organs
(eg, human lymph
nodes and
spleen).

T-cell independent B-cell activation
This type of activation produces plasma cells
and IgM.
B cells are activated by conserved repeat
epitopes on the surface of bacteria or virus,
including lipopolysaccharides (LPS), or DNA
fragments.
BCRs will cluster and cross-link with T-
independent antigens.
A secondary response is provided through
engaging the toll-like receptor (TLR).
Activated B cells will deliver a potent
antibody response and do not generate
memory B cells
 This type of activation produces
memory and plasma B cells.
Naïve B cells bind to soluble or
membrane bound antigens and
internalize the antigen.
The B cell presents this antigen on a
MHCII and is recognized by a helper T
cell (Th).
Cytokines are secreted by the Th cell
and this activates the B cell into
differentiating into mature B cells
capable of IgG, IgA, or IgE production
Difference between B cells
and Plasma cells

Why do you think
plasma cells have
a high RER
content?
Clonal selection:
From a large pool of B and T cells,
antigen selects those which have
receptors for it and stimulates their
expansion and differentiation into
memory and effector cells.

Although B cells can recognize and
bind native antigen, T cells only see
antigen associated with MHC
molecules on antigen-presenting
cells (APC).

APCs present antigens for
recognition by certain lymphocytes
such as T cells.
Classical APCs include dendritic
cells, macrophages, and B cells.
Interactions between
innate and adaptive
immunity
Interaction between innate and adaptive immunity

▪ Innate and Adaptive immune system do not work in isolation, but in a highly
dependent and coordinated manner.
▪ Macrophages are phagocytic but produce important cytokines that help to
induce the adaptive immune response.
▪ Cytotoxic T cells kill virus-infected body cells. These have to be cleared
from the body by phagocytic cells.
▪ Complement components of the innate immune system can be activated
directly by microbes, but can also be activated by antibodies (molecules of
the adaptive system).
▪ The various cells of both systems work together through direct contact with
each other, and through interactions cytokines and chemokines.
▪ The lymphocytes selected for clonal expansion are of two major types,
B cells and T cells, each giving rise to different kinds of immunity.
▪ T lymphocytes mature under the influence of the thymus and, on
stimulation by antigen, give rise to cellular immunity.
▪ B lymphocytes mature mainly under the influence of bone marrow and
give rise to lymphoid populations which, on contact with antigen,
proliferate and differentiate into plasma cells.
▪ These plasma cells make antibody (immunoglobulin) which is specific
for the antigen and able to neutralize and/or eliminate it (humoral
immunity).