Chapter 3 Immune System Biology II PDF

Summary

This document is Chapter 3 of a biology textbook titled Biology II-Foundation of Science. It presents information about the immune system, covering topics such as different types of immune responses, innate immunity, acquired immunity, and other related aspects. It details the roles of different cells and molecules in the immune response, including various diagrams and explanations.

Full Transcript

Chapter 3

Immune system

Dr. Leong Chean Ring
Biology II – Foundation of science

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Why an immune system?

Attack from outside
❖ Lots of organisms what you for lunch!
❖ Animals must defend themselves against unwelcome invaders: viruses
bacteria, prostists and fungi
❖ We are a tasty vitamin-packed meal
No cell wall
Traded mobility for susceptibility

The immune system recognizes foreign bodies = “not self” and responds w
the production of immune cells and proteins.
Two major kinds of defense have evolved: innate immunity and acquired
immunity.
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Why an immune system?

Attack from inside
❖ Also deal with abnormal body cells = may
develop into cancers

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Are viruses alive?

The characteristic of living things
❖ Are made up of cells.
❖ Reproduce
❖ Based on a universal genetic code
❖ Grow and develop
❖ Obtain and use materials and energy
❖ Respond to their environment
❖ Maintain stable internal environment
❖ Change over time

https://www.youtube.com/watch?v=WHnpp823BW8
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Diversity of viral shapes

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Virus life cycle

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The Lytic Cycle

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The Lysogenic Cycle

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Differences between virus and cells

Vaccines Antibiotics

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Diseases caused by viruses

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Diseases caused by bacteria

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Diseases caused by protists

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Diseases caused by fungi

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How do immune cells of animals recognize foreign cells?

1.5 µm
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 Innate immunity is present before any
exposure to pathogens and is effective from
the time of birth.
It involves nonspecific responses to pathogens.
Innate immunity consists of external barriers
plus internal cellular and chemical defenses.

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 Acquired immunity = adaptive immunity,
develops after exposure to agents such as
microbes, toxins, or other foreign substances.
It involves a very specific response to
pathogens.

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Animal Immunity Pathogens
(microorganisms
and viruses)

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

ACQUIRED IMMUNITY Humoral response:
Antibodies defend against
Recognition of traits infection in body fluids.
specific to particular
pathogens, using a vast Cell-mediated response:
array of receptors Cytotoxic lymphocytes defend
against infection in body cells.
Slower response
Innate Immunity of Invertebrates

In insects, an exoskeleton made of chitin forms the
first barrier to pathogens.
The digestive system is protected by low pH and
lysozyme, an enzyme that digests microbial cell
walls.
Hemocytes circulate within hemolymph and carry
out phagocytosis, the ingestion and digestion of
foreign substances including bacteria.
Hemocytes also secrete antimicrobial peptides
that disrupt the plasma membranes of bacteria.

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Barrier Defenses

Barrier defenses include the skin and
mucous membranes of the respiratory, urinary,
and reproductive tracts.
Mucus traps and allows for the removal of
microbes.
Many body fluids including saliva, mucus, and
tears are hostile to microbes.
The low pH of skin and the digestive system
prevents growth of microbes.
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 2nd : Non-specific patrol (internal barrier)
Cells & protein Cellular elements 45%

Attack invaders that penetrate Cell type Number
per µL (mm3) of blood
Functions

body’s outer barriers
Erythrocytes 5–6 million Transport oxygen
(red blood cells) and help transport
❖ Phagocytic cells carbon dioxide

❖ Anti-microbial protein
Leukocytes 5,000–10,000 Defense and
❖ Inflammatoryy responses (white blood cells) immunity

Lymphocyte
Basophil

Eosinophil

Neutrophil Monocyte

Platelets 250,000– Blood clotting
400,000
Phagocytic leukocytes (WBC)
Phagocytes

Neutrophils (“NEUTRalize” invader)
❖ Attracted by chemical signals released by damaged cells
❖ Enter infected tissue, engulf & ingest microbes
▪ Amoeba-like (fierce!)
▪ Lysosomes
▪ -3 day life span
Macrophages
❖ “big eater”
❖ Bigger, long lived phagocytes

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Phagocytosis
Microbes

PHAGOCYTIC CELL

Vacuole
Lysosome
Containing
hydrolytic
enzymes
Cellular Innate Defenses

White blood cells = leukocytes engulf
pathogens in the body via phagocytosis.
Groups of pathogens are recognized by TLR,
Toll-like receptors.

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 EXTRACELLULAR
TLR FLUID Lipopolysaccharide

signaling Helper
protein Flagellin
TLR4
WHITE
BLOOD
CELL
TLR5

VESICLE
TLR9
CpG DNA

TLR3 Inflammatory
responses
ds RNA
Lymphatic Interstitial fluid
Adenoid
System
Tonsil

Blood
Lymph capillary
nodes

Spleen Tissue Lymphatic
cells vessel
Peyer’s patches
(small intestine)
Appendix

Lymphatic
vessels Lymph Masses of
node defensive cells
Antimicrobial Peptides and Proteins

Peptides and proteins function in innate
defense by attacking microbes directly or
impeding their reproduction.
Interferon proteins provide innate defense
against viruses and help activate
macrophages.
About 30 proteins make up the complement
system, which causes lysis of invading cells
and helps trigger inflammation.

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Major events in a local Inflammatory Response

1. 2. 3.
Pathogen Splinter

Chemical Macrophage
signals Fluid
Mast cell
Capillary Phagocytosis

Red blood cells Phagocytic cell

Damage to tissue triggers local inflammatory response
❖ Histamines & prostaglandins released
❖ Capillaries dilate , more permeable
❖ Lead to clot formation
Increased blood supply
❖ Swelling, reedness & heat of inflammation & infection
❖ Delivers WBC, RBC, platelets, clotting factors.
Inflammatory Responses
Following an injury, mast cells release
histamine, which promotes changes in blood
vessels; this is part of the inflammatory
response.
These changes increase local blood supply
and allow more phagocytes and antimicrobial
proteins to enter tissues.
Pus = a fluid rich in white blood cells, dead
microbes, and cell debris, accumulates at the
site of inflammation.
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 Inflammation can be either local or systemic
(throughout the body).
Fever is a systemic inflammatory response
triggered by pyrogens released by
macrophages, and toxins from pathogens.
Septic shock is a life-threatening condition
caused by an overwhelming inflammatory
response.

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In Acquired Immunity, lymphocyte receptors
provide pathogen-specific recognition
White blood cells called lymphocytes recognize and
respond to antigens, foreign molecules.
Lymphocytes that mature in the thymus above the
heart are called T cells, and those that mature in bone
marrow are called B cells.
Lymphocytes contribute to immunological memory, an
enhanced response to a foreign molecule
encountered previously.
Cytokines are secreted by macrophages and
dendritic cells to recruit and activate lymphocytes.

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Acquired Immunity = Active Immunity: Specific

B cells and T cells have receptor proteins that
can bind to foreign molecules.
Each individual lymphocyte is specialized to
recognize a specific type of molecule.
An antigen is any foreign molecule to which a
lymphocyte responds.
A single B cell or T cell has about 100,000
identical antigen receptors.

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Antigen receptors on lymphocytes

Antigen- Antigen- Antigen-
binding binding site binding
site site

Disulfide
bridge
Variable
regions V V

C C Constant C C
regions
Light
chain
Transmembrane
region

Plasma
membrane
Heavy chains  chain  chain
Disulfide bridge
B cell Cytoplasm of B cell Cytoplasm of T cell T cell

B cell receptor
T cell receptor
 All antigen receptors on a single lymphocyte
recognize the same epitope, or antigenic
determinant, on an antigen.
B cells give rise to plasma cells, which secrete
proteins called antibodies or
immunoglobulins.

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 Epitopes = antigen determinants

Antigen-
binding Epitopes
sites (antigenic
determinants)
Antigen-binding sites

Antibody A Antigen Antibody C

C C
Antibody B
The Antigen Receptors of B Cells and T Cells

B cell receptors bind to specific, intact antigens.
The B cell receptor consists of two identical heavy
chains and two identical light chains.
The tips of the chains form a constant (C) region, and
each chain contains a variable (V) region, so named
because its amino acid sequence varies extensively
from one B cell to another.
Secreted antibodies, or immunoglobulins, are
structurally similar to B cell receptors but lack
transmembrane regions that anchor receptors in the
plasma membrane.

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 Each T cell receptor consists of two different
polypeptide chains. The tips of the chain form a
variable (V) region; the rest is a constant (C) region.
T cells can bind to an antigen that is free or on the
surface of a pathogen.
T cells bind to antigen fragments presented on a host
cell. These antigen fragments are bound to cell-
surface proteins called MHC molecules.
MHC molecules are so named because they are
encoded by a family of genes (many unique / specific)
called the Major Histocompatibility Complex.

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The Role of the MHC

In infected cells, MHC molecules bind and
transport antigen fragments to the cell surface,
a process called antigen presentation.
A nearby T cell can then detect the antigen
fragment displayed on the cell’s surface.
Depending on their source, peptide antigens
are handled by different classes of MHC
molecules.

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Antigen Presentation
by an MHC molecule Top view: binding surface
exposed to antigen receptors

Antigen
Class I MHC Antigen
molecule

Plasma
membrane of
infected cell
 Class I MHC molecules are found on almost
all nucleated cells of the body.
They display peptide antigens to cytotoxic T
cells.
Class II MHC molecules are found on
specialized cells: macrophages, B cells, and
activated T cells…

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 Interaction of T cells with Antigen-Presenting Cells

Infected cell Microbe Antigen-
1 Antigen presenting
cell
associates
with MHC
Antigen molecule
fragment Antigen
fragment
1
1
Class I MHC Class II MHC
molecule 2 molecule
2
T cell T cell
2 T cell receptor
receptor
recognizes
combination

(a) Cytotoxic T cell (b)
Helper T cell
 Class II MHC molecules are located mainly on
dendritic cells, macrophages, and B cells.
Dendritic cells, macrophages, and B cells are
antigen-presenting cells that display antigens
on their surface to cytotoxic T cells and helper
T cells.

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Amplifying Lymphocytes by Clonal Selection

In the body there are few lymphocytes with antigen
receptors for any particular epitope.
The binding of a mature lymphocyte to an antigen
induces the lymphocyte to divide rapidly.
This proliferation of lymphocytes is called clonal
selection.
Two types of clones are produced: short-lived
activated effector cells (fight current battle) and long-
lived memory cells… for future attacks by same
pathogen.

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Clonal Selection of B cells Antigen molecules

B cells that
differ in
antigen
specificity Antigen
receptor

Antibody
molecules

Clone of memory cells Clone of plasma cells = effectors
Primary immune response Secondary immune response to
to antigen A produces antigen A produces antibodies to A.
antibodies to A. Primary immune response to antigen
B produces antibodies to B.

104
Antibody concentration
(arbitrary units)

103
Antibodies
to A
102 Antibodies
to B

101

100
0 7 14 21 28 35 42 49 56

Exposure Exposure to
to antigen A antigens A and B
Time (days)
 The first exposure to a specific antigen
represents the primary immune response.
During this time, effector B cells = plasma
cells are generated, and T cells are activated
to their effector forms.
In the secondary immune response =
memory cells facilitate a faster, more efficient
response.

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Acquired immunity defends against infection of
body cells and fluids
Acquired immunity has two branches: the
humoral immune response and the cell-
mediated immune response.
Humoral immune response involves
activation and clonal selection of B cells,
resulting in production of secreted antibodies.
Cell-mediated immune response involves
activation and clonal selection of cytotoxic T
cells.
Helper T cells aid both responses.
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 Humoral (antibody-mediated) immune response Cell-mediated immune response
Key
Antigen (1st exposure)
+ Stimulates
Engulfed by Gives rise to

Acquired Antigen-
+ +
presenting cell
Immune
Response +

B cell + Helper T cell + Cytotoxic T cell

Memory
Helper T cells

+ + +

Antigen (2nd exposure)

+ Memory Active
Plasma cells Memory B cells Cytotoxic T cells Cytotoxic T cells

Secreted
antibodies

Defend against extracellular pathogens by binding to antigens, Defend against intracellular pathogens
thereby neutralizing pathogens or making them better targets and cancer by binding to and lysing the
for phagocytes and complement proteins. infected cells or cancer cells.
Acquired Humoral (antibody-mediated) immune response
Immune Key Antigen (1st exposure)
Response + Stimulates Engulfed by
Gives rise to
Antigen-
+ presenting cell

+

B cell +
Helper T cell

Memory
Helper T cells

+ +
Antigen (2nd exposure)
Plasma cells Memory +
B cells

Secreted
antibodies
Defend against extracellular pathogens
Acquired Cell-mediated immune response
Immune Antigen (1st exposure) Key
Response + Stimulates
Engulfed by
Gives rise to
Antigen-
presenting cell +

+

Helper T cell + Cytotoxic T cell

Memory
Helper T cells

+ +
Antigen (2nd exposure)
Active
+ Cytotoxic T cells

Memory
Cytotoxic T cells

Defend against intracellular pathogens
 Helper T Cells: Respond to Nearly All Antigens

A surface protein called CD4 binds the class II
MHC molecule.
This binding keeps the helper T cell joined to
the antigen-presenting cell while activation
occurs.
Activated helper T cells secrete cytokines that
stimulate other lymphocytes.
Positive Feedback in the Immune System
enhances the process until some endpoint
or maximum rate is reached.
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 The central role of helper T cells in humoral and
cell-mediated immune responses

Antigen-
presenting Peptide antigen
cell
Bacterium

Class II MHC molecule
CD4
TCR (T cell receptor)
Helper T cell
Cytokines + +
Humoral Positive Feedback … Cell-mediated
immunity
+ + immunity
= secretion of
B cell Cytotoxic T cell = attack on
antibodies by
infected cells.
plasma cells.
Cytotoxic T Cells: A Response to Infected Cells

Cytotoxic T cells are the effector cells in cell-
mediated immune response.
Cytotoxic T cells make CD8, a surface protein
that greatly enhances interaction between a
target cell and a cytotoxic T cell.
Binding to a class I MHC complex on an
infected cell activates a cytotoxic T cell and
makes it an active killer.
The activated cytotoxic T cell secretes proteins
that destroy the infected target cell.

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The killing action of cytotoxic T cells

3. lysis
1. 2.
Released cytotoxic T cell
Cytotoxic T cell

Perforin
Granzymes

CD8 TCR Dying target cell
Class I MHC Pore
molecule

Target Peptide
cell antigen
B Cells: A Response to Extracellular Pathogens

The humoral response is characterized by
secretion of antibodies by B cells.
Activation of B cells is aided by cytokines and
antigen binding to helper T cells.
Clonal selection of B cells generates antibody-
secreting plasma cells, the effector cells of
humoral immunity. Positive Feedback …

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B cell activation in the humoral immune response

Antigen-presenting cell Bacterium

Peptide B cell
antigen

Class II MHC
molecule + Clone of plasma cells Secreted
TCR CD4 Cytokines
antibody
molecules
Endoplasmic
reticulum of
plasma cell
Activated
Helper T cell helper T cell Clone of memory
B cells

2 µm
Antibody Classes

The five major classes of antibodies, or
immunoglobulins, differ in distribution and
function.
Polyclonal antibodies are the products of many
different clones of B cells following exposure to
a microbial antigen.
Monoclonal antibodies are prepared from a
single clone of B cells grown in culture.

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The five Class of Immuno-
globulin (Antibody)
Distribution Function

antibody, or IgM
(pentamer)
First Ig class
produced after
Promotes neutraliza-
tion and cross-

immunoglobulin initial exposure to
antigen; then its
concentration in
the blood declines
linking of antigens;
very effective in
complement system
activation

(Ig), classes J chain

IgG Most abundant Ig Promotes opsoniza-
(monomer) class in blood; tion, neutralization,
also present in and cross-linking of
tissue fluids antigens; less effec-
tive in activation of
complement system
than IgM

Only Ig class that
crosses placenta,
thus conferring
passive immunity
on fetus

IgA Present in Provides localized
(dimer) secretions such defense of mucous
as tears, saliva, membranes by
mucus, and cross-linking and
J chain breast milk neutralization of
antigens

Presence in breast
milk confers
Secretory passive immunity
component on nursing infant

IgE Present in blood Triggers release from
(monomer) at low concen- mast cells and
trations basophils of hista-
mine and other
chemicals that cause
allergic reactions

IgD Present primarily Acts as antigen
(monomer) on surface of receptor in the
B cells that have antigen-stimulated
not been exposed proliferation and
to antigens differentiation of
B cells (clonal
Trans- selection)
membrane
region
 Class of Immuno-
Distribution Function
globulin (Antibody)

IgM First Ig class Promotes neutraliza-
(pentamer) produced after tion and cross-
initial exposure to linking of antigens;
antigen; then its very effective in
concentration in complement system
the blood declines activation
J chain
 Class of Immuno-
Distribution Function
globulin (Antibody)

IgG Most abundant Ig Promotes opsoniza-
(monomer) class in blood; tion, neutralization,
also present in and cross-linking of
tissue fluids antigens; less effec-
tive in activation of
complement system
than IgM

Only Ig class that
crosses placenta,
thus conferring
passive immunity
on fetus
 Class of Immuno-
Distribution Function
globulin (Antibody)

IgA Present in Provides localized
(dimer) secretions such defense of mucous
as tears, saliva, membranes by
mucus, and cross-linking and
J chain breast milk neutralization of
antigens

Presence in breast
milk confers
Secretory passive immunity
component on nursing infant
 Class of Immuno-
Distribution Function
globulin (Antibody)

IgE Present in blood Triggers release from
(monomer) at low concen- mast cells and
trations basophils of hista-
mine and other
chemicals that cause
allergic reactions
 Class of Immuno-
Distribution Function
globulin (Antibody)

IgD Present primarily Acts as antigen
(monomer) on surface of receptor in the
B cells that have antigen-stimulated
not been exposed proliferation and
to antigens differentiation of
B cells (clonal
Trans- selection)
membrane
region
Active Immunization

Active immunity develops naturally in
response to an infection.
It can also develop following/ from
immunization, also called vaccination.
In immunization, a nonpathogenic form of a
microbe or part of a microbe elicits an immune
response to an immunological memory.

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 Passive Immunity

Passive immunity provides immediate, short-
term protection.
It is conferred naturally when IgG crosses the
placenta from mother to fetus or when IgA
passes from mother to infant in breast milk.
It can also be conferred artificially by injecting
antibodies into a nonimmune person.

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Passive
immunization
of an infant
occurs during
breast-feeding
Immune Rejection

Cells transferred from one person to another
can be attacked by immune defenses.
This complicates blood transfusions or the
transplant of tissues or organs.
MHC molecules are different among genetically
nonidentical individuals.
Differences in MHC molecules stimulate
rejection of tissue grafts and organ transplants.

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 Chances of successful transplantation increase
if donor and recipient MHC tissue types are
well matched.
Immunosuppressive drugs facilitate
transplantation.
Lymphocytes in bone marrow transplants may
cause the donor tissue to reject the recipient.

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Blood Groups

Antigens on red blood cells surface determine
whether a person has blood type A (A antigen),
B (B antigen), AB (both A and B antigens), or O
(neither antigen).
Antibodies to nonself blood types exist in the
body.
Transfusion with incompatible blood leads to
destruction of the transfused cells.
Recipient-donor combinations can be fatal or
safe.
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 Disruption in immune system function can elicit
or exacerbate disease
Some pathogens have evolved to diminish the
effectiveness of host immune responses.
If the delicate balance of the immune system is
disrupted, effects range from minor to often
fatal.

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Allergies

Allergies are exaggerated (hypersensitive)
responses to antigens called allergens.
In localized allergies such as hay fever, IgE
antibodies produced after first exposure to an
allergen attach to receptors on mast cells.

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Mast cells, IgE, and the allergic response

IgE
Histamine
Allergen

Granule
Mast cell
 The next time the allergen enters the body, it
binds to mast cell–associated IgE molecules.
Mast cells release histamine and other
mediators that cause vascular changes leading
to typical allergy symptoms.
An acute allergic response can lead to
anaphylactic shock, a life-threatening reaction
that can occur within seconds of allergen
exposure.

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Autoimmune Diseases

In individuals with autoimmune diseases, the
immune system loses tolerance for self and
turns against certain molecules of the body.
Autoimmune diseases include systemic lupus
erythematosus, rheumatoid arthritis, insulin-
dependent diabetes mellitus, and multiple
sclerosis.

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X-ray of a
hand
deformed
by
rheumatoid
arthritis
Exertion, Stress, and the Immune System

Moderate exercise improves immune system
function.
Psychological stress has been shown to disrupt
hormonal, nervous, and immune systems.

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Immunodeficiency Diseases

Inborn immunodeficiency results from
hereditary or developmental defects that
prevent proper functioning of innate, humoral,
and/or cell-mediated defenses.
Acquired immunodeficiency results from
exposure to chemical and biological agents.
Acquired immunodeficiency syndrome
(AIDS) is caused by a virus.

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Acquired Immune System Evasion by Pathogens

Pathogens have evolved mechanisms to attack
immune responses.
Through antigenic variation, some pathogens are able
to change epitope expression and prevent recognition.
The human influenza virus mutates rapidly, and new
flu vaccines must be made each year.
Human viruses occasionally exchange genes with the
viruses of domesticated animals.
This poses a danger as human immune systems are
unable to recognize the new viral strain.

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Latency

Some viruses may remain in a host in an
inactive state called latency.
Herpes simplex viruses can be present in a
human host without causing symptoms.

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Attack on the Immune System: HIV

Human immunodeficiency virus (HIV) infects
helper T cells.
The loss of helper T cells impairs both the
humoral and cell-mediated immune responses
and leads to AIDS.
HIV eludes the immune system because of
antigenic variation and an ability to remain
latent while integrated into host DNA.

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The progress of an
untreated HIV infection Latency AIDS

Relative antibody
concentration
800
Helper T cell concentration
in blood (cells/mm3)

Relative HIV
600 concentration
Helper T cell
concentration
400

200

0
0 1 2 3 4 5 6 7 8 9 10
Years after untreated infection