Innate Immunity Lecture Notes PDF

Summary

This document describes innate immunity, focusing on the recognition of microbes and damaged cells by the immune system, the function of different components of innate immunity in combating microbes, and how innate immune reactions stimulate adaptive immune responses. It also covers blood cells and their role in the body's defense mechanisms.

Full Transcript

Innate Immunity:

The Early Defense Against
Infections

How does the innate immune
system recognize microbes and
damaged cells?

How do the different components
of innate immunity function to
combat different types of
microbes?

How do innate immune reactions
stimulate adaptive immune
responses?
Blood
 Blood

Blood is the fluid contained within the heart,
arteries, capillaries and veins of the circulatory
system.

It delivers oxygen and nutrients to organs and
tissues and carries carbon dioxide and metabolic
‘waste’ products to excretory organs such as the
kidneys, liver and lungs.

Blood consists of several components:
Plasma
Cells (red cells, white cells, platelets)
Electrolytes (e.g., Na + , K + , Ca ++ )
Proteins (including hormones and immunoglobulins)
Lipids
Glucose
The cellular components of blood are synthesized in the bone marrow in a
process called ‘haematopoiesis’.
 Haematopoiesis

Haematopoiesis is the
formation and
development of blood
cells.

The haematopoietic
system is composed of
the bone marrow, spleen,
liver, lymph nodes and
thymus.
Haematopoiesis is the
formation and
development of blood
cells.

The haematopoietic
system is composed of
the bone marrow, spleen,
liver, lymph nodes and
thymus. Pluripotent haemopoietic stem cells

All blood cells originally derive from a population of pluripotent,
CD34 + haemopoietic stem cells, residing in haematopoietic
tissues.
Remain as pluripotent stem cells, dividing to form identical
daughter cells, maintaining the haemopoietic population

Differentiate into specific progenitor cells, which ultimately
develop into specific cellular components of blood.
Myeloid lineage multipotent
progenitor cell

Red cell progenitor (BFU-E)

Platelet progenitor (CFU-Meg)

Eosinophil progenitor (CFU-Eos)

Basophil progenitor (CFU-Baso)

Neutrophil/monocyte progenitor (CFU-GM)
 Myeloid lineage multipotent
progenitor cell
Red blood cells
Red blood cells (‘erythrocytes’) are derived from the
erythroid blast-forming unit (BFU-E) progenitor cell.

Red cells lack a nucleus and have a biconcave
discoid shape.

They contain haemoglobin and their primary role is
the transportation of oxygen (from lung to tissue)
and carbon dioxide (from tissue to lung).
 Myeloid lineage multipotent
progenitor cell
Platelets
Platelets (thrombocytes) are derived from
megakaryocytes, which derive from the colony-
forming unit megakaryocyte (CFU-Meg)
progenitor cell.

Like red cells, platelets lack nuclei.

They play an important role in haemostasis.
 Myeloid lineage multipotent
progenitor cell
Basophils

Basophils have bilobed nuclei and granular
cytoplasm.

Basophils represent ≤ 1% of the bloodstream’s
white cell population.

They contribute strongly to innate and adaptive
immunity.
 Myeloid lineage multipotent
progenitor cell
Eosinophils

Eosinophils have bilobed nuclei and granular
cytoplasm.
Eosinophils represent 1 – 6% of the bloodstream’s
white cell population.
Eosinophils migrate into areas of inflammation
or infection and release specific cytotoxic and
messenger molecules.

They are also important in both innate and adaptive immunity and allergic responses
 Myeloid lineage multipotent
progenitor cell
Neutrophils

Neutrophils have multilobed nuclei comprise ≈
60% of the bloodstream white cell population.
Neutrophils are an essential component of the
innate immune system, due to their ability to
phagocytose (engulf) microorganisms and kill
them by releasing cytotoxic molecules from their
granules.

Neutrophils therefore represent a key component of the first-line defence
against bacterial infections.
 Myeloid lineage multipotent
progenitor cell
Monocytes/macrophages

Monocytes and macrophages account for ~ 2%–
10% of the white cell population.
They circulate for 1–3 days, then leave the
circulation and enter the tissues, where they
differentiate further, developing into
macrophages.
They phagocytose cellular debris and pathogens
and produce various cytokines
 Lymphoid lineage multipotent
progenitor cell

Pre-B cell (B cell precursor)

Pre-T cell (T cell precursor)

NK cell precursor

These cells are all derived from the lymphoid
lineage.
 Lymphoid lineage multipotent
progenitor cell

Pre-B cell (B cell precursor)

Pre-T cell (T cell precursor)

NK cell precursor
These cells are all derived from the lymphoid lineage.

Lymphocytes
These white blood cells are small and have a relatively large, round nucleus relative to
their nongranular, basophilic cytoplasm volume. They all originate from the lymphoid
lineage.
 Lymphoid lineage multipotent
progenitor cell
B lymphocytes

These cells are small lymphocytes (diameter 6–9 μm) expressing the
B cell receptor.

They secrete immunoglobulins (antibodies).

A large proportion of B lymphocytes reside in lymph node germinal
centres, where they are known as memory B cells. Some B
lymphocytes also mature further into plasma cells.
 Lymphoid lineage multipotent
progenitor cell
T lymphocytes

These cells are small lymphocytes (diameter 6–9 μm) expressing the
T cell receptor.

T cells are subclassified by type of surface glycoproteins they express,
indicated by the CD prefix.

Cytotoxic T cells (CD8 + ve) mediate destruction of cells infected by
intracellular organisms, while T helper cells (CD4 + ve) release cytokines
to regulate and assist in the adaptive immune response.
 Lymphoid lineage multipotent
progenitor cell
Natural killer cells

These large granular lymphocytes are also cytotoxic
lymphocytes, like T cells, but natural killer (NK) cells are larger.

Their behaviour differs from that of T cells in that they do not
require major histocompatibility complex (MHC) or antibody-
bound antigen complexes to recognize and destroy foreign or
infected cells.

They are prominent in the innate immune response.
Haematopoiesis