1. Human Anatomy and Physiology II
The Immune System
Chapter 21
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2. Immune System Ch21 Outline
Describe immunity and know how it is regulated by innate and adaptive defenses
Know the cells involved in each and the functions they have
Understand the difference between humoral and cellular immunity

3. Overview Immunity Resistance to disease
Immune system has two intrinsic systems
1. Innate (nonspecific) defense system
2. Adaptive (specific) defense system

4. Surface barriers
• Skin
• Mucous membranes
Innate
defenses
Internal defenses
• Phagocytes
• NK cells
• Inflammation
• Antimicrobial proteins
• Fever
Humoral immunity
• B cells
Adaptive
defenses
Cellular immunity
• T cells

5. Innate Defense System Two lines of defense 1. Surface Barriers
Skin and mucosa first line of defense
Functions
Mechanical barrier
Inhibit entrance of
pathogens
Mucus, acidity, lysozyme

6. Innate Defense System Internal Defenses
Cellular and chemical defenses are second line of defense
Protection if microorganisms invade deeper in tissues
Cells
Phagocytes, Natural Killer (NK) cells, Mast cells, WBCs
Chemicals
interferons, complement
Inflammation
Fever

7. Immune Cells
Phagocytes -engulf and destroy pathogens that breach epithelial
barriers
Macrophages
Develop from monocytes and become the chief phagocytic cells
Neutrophils
Become phagocytic on encountering infectious material in tissues

8. An example of the body’s first line of defense is ____________.
Macrophages
Fever
Inflammation
Mucus

9. Immune Cells Natural Killer (NK) Cells Large granular lymphocytes
Functions
Attack cells that lack “self” cell-surface receptors
Induce apoptosis in cancer cells and virus-infected cells
Secrete potent chemicals
that enhance the
inflammatory response

10. Chemicals Antimicrobial Proteins
Attack microbes or hinder their ability to reproduce
Interferons
Complement proteins

11. Interferons Viral infected cells secrete interferons Functions
An SOS to neighboring cells
Functions
Induce other cells to secrete Anti-viral proteins
Activate macrophages and mobilize NK cells

12. Antiviral proteins block viral reproduction.
Innate defenses
Internal defenses
Virus 1
Virus enters cell.
New viruses
Viral nucleic acid
Antiviral proteins block viral reproduction. 5 2
Interferon genes switch on.
DNA
Nucleus
mRNA 4
Interferon binding stimulates cell to turn on genes for antiviral proteins.
Cell produces interferon molecules. 3
Interferon
Host cell 2 Binds interferon from cell 1; interferon induces synthesis of protective proteins
Host cell 1 Infected by virus; makes interferon; is killed by virus

13. Complement ~20 plasma proteins that circulate in an inactive form
Major mechanism for destroying foreign substances
Functions of Activated Complement
Enhances inflammation
Promotes phagocytosis
Causes cell lysis

14. Inflammation Cardinal signs of acute inflammation Redness Heat
Swelling
Pain

15. Inflammation Triggered whenever body tissues are injured or infected
Prevents the spread of damaging agents
Disposes of cell debris and pathogens
Sets the stage for repair and healing
Release of inflammatory mediators by injured tissue, phagocytes, lymphocytes, basophils, and mast cells
Histamine, cytokines, kinins, prostaglandins (PGs), leukotrienes, and complement

16. Inflammatory Response
Results
Vasodilation and increased vascular permeability
Inflammatory chemicals cause
Dilation of arterioles
Increased permeability of local capillaries and edema

17. Fever Systemic response to invading microorganisms
Leukocytes and macrophages exposed to foreign substances secrete pyrogens
Pyrogens reset the body’s thermostat upward

18. Fever Benefits of moderate fever
Causes the liver and spleen to sequester iron and zinc (needed by microorganisms)
Increases metabolic rate, which speeds up repair
High fevers are dangerous because heat denatures enzymes (proteins)

19. Why is a moderate fever helpful in the immune response?
Speeds up metabolism
Causes liver and spleen to sequester iron and zinc
Slows metabolism
Both A and B
Both B and C

20. Surface barriers
• Skin
• Mucous membranes
Innate
defenses
Internal defenses
• Phagocytes
• NK cells
• Inflammation
• Antimicrobial proteins
• Fever
Humoral immunity
• B cells
Adaptive
defenses
Cellular immunity
• T cells

21. Adaptive Defenses Adaptive immune response
Is specific
Is systemic
Has memory
Two separate overlapping arms of defense
Humoral (antibody-mediated) immunity
Cellular (cell-mediated) immunity

22. Cells of the Adaptive Immune System
Lymphocytes
Originate in red bone marrow
B cells mature in the red bone marrow
T cells mature in the thymus
Become immunocompetent when mature
Two requirements of immunocompetence
They are able to recognize and bind to a specific antigen
Self-tolerance – unresponsive to self antigens

23. Development of Self Tolerance
Positive selection: T cells must recognize self major
histocompatibility proteins (self-MHC).
Antigen-
presenting
thymic cell
Developing
T cell
Failure to recognize self-MHC
results in apoptosis (death
by cell suicide).
MHC
T cell receptor
Self-antigen
Recognizing self-MHC results in
MHC restriction—survivors are
restricted to recognizing antigen
on self-MHC. Survivors proceed
to negative selection.

24. Development of Self Tolerance
Positive selection: T cells must recognize self major
histocompatibility proteins (self-MHC).
Antigen-
presenting
thymic cell
Developing
T cell
Failure to recognize self-MHC
results in apoptosis (death
by cell suicide).
MHC
T cell receptor
Self-antigen
Recognizing self-MHC results in
MHC restriction—survivors are
restricted to recognizing antigen
on self-MHC. Survivors proceed
to negative selection.
Negative selection: T cells must not recognize self-antigens.
Recognizing self-antigen results
in apoptosis. This eliminates
self-reactive T cells that could
cause autoimmune diseases.
Failure to recognize (bind tightly
to) self-antigen results in survival
and continued maturation.

25. Lymphocytes destined to become T cells
Humoral immunity
Red bone marrow: site of lymphocyte origin
Adaptive defenses
Cellular immunity
Primary lymphoid organs: site of
development of immunocompetence as B or
T cells
Immature
lymphocytes
Red
bone marrow
Secondary lymphoid organs: site of
antigen encounter, and activation to become
effector and memory B or T cells
Lymphocytes destined to become T cells
migrate (in blood) to the thymus and develop
immunocompetence there. B cells develop
immunocompetence in red bone marrow. 1
Thymus
Bone marrow
Immunocompetent but still naive
lymphocytes leave the thymus and bone
marrow. They “seed” the lymph nodes,
spleen, and other lymphoid tissues where
they encounter their antigen. 2
Lymph nodes,
spleen, and other
lymphoid tissues
Antigen-activated immunocompetent
lymphocytes (effector cells and memory
cells) circulate continuously in the
bloodstream and lymph and throughout
the lymphoid organs of the body. 3

26. Humoral Immunity Cells and agents of Humoral Immunity
B cells
Plasma cells
Memory B cells
Antibodies
Provide defenses against extracellular antigens

27. Review: Antigens
Substances that can mobilize the adaptive defenses and provoke an immune response
Most are large, complex molecules not normally found in the body (nonself)

28. Humoral Immunity Response
Step 1: Antigen challenge
First encounter between an antigen and a naive immunocompetent B lymphocyte
Usually occurs in the spleen or a lymph node
The antigen provokes a humoral immune response

29. Step 2: Clonal Selection
B cell is activated when antigens bind to its surface receptors
Stimulated B cell grows to form clones of identical cells bearing the same antigen-specific receptors

30. Fate of the Clones Most clone cells become plasma cells
secrete specific antibodies at the rate of 2000 molecules per second for four to five days
Secreted antibodies
Circulate in blood or lymph
Bind to free antigens
Mark antigens for destruction

31. Fate of the Clones
Clone cells that do not become plasma cells become memory cells
Provide immunological memory
Mount an immediate response to future exposures of the same antigen

32. Clonal Selection Primary response Antigen (initial encounter
with antigen)
Antigen
Antigen binding
to a receptor on a
specific B lymphocyte
(B lymphocytes with
non-complementary
receptors remain
inactive)
Proliferation to
form a clone
Activated B cells
Plasma cells
(effector B cells)
Memory B cell—
primed to
respond to same
antigen
Secreted
antibody
molecules

33. Immunological Memory Primary Immune Response
Occurs on the first exposure to a specific antigen
Lag period: three to six days
Peak levels of plasma antibody are reached in 10 days
Antibody levels then decline

34. Immunological Memory Secondary Immune Response
Occurs on re-exposure to the same antigen
Sensitized memory cells respond within hours
Antibody levels peak in two to three days at much higher levels
Antibodies bind with greater affinity
Antibody levels can remain high for weeks to months

35. Primary response
(initial encounter
with antigen)
Antigen
Antigen binding
to a receptor on a
specific B lymphocyte
(B lymphocytes with
non-complementary
receptors remain
inactive)
Proliferation to
form a clone
Activated B cells
Plasma cells
(effector B cells)
Memory B cell—
primed to respond
to same antigen
Secreted
antibody
molecules
Subsequent
challenge by
same antigen
results in more
rapid response
Secondary response
(can be years later)
Clone of cells
identical to
ancestral cells
Plasma
cells
Secreted
antibody
molecules
Memory
B cells

36. Secondary immune response to
antigen A is faster and larger; primary
immune response to antigen B is
similar to that for antigen A.
Primary immune
response to antigen
A occurs after a delay.
Anti-
bodies
to B
Anti-
bodies
to A
First exposure
to antigen A
Second exposure to antigen A;
first exposure to antigen B
Time (days)

37. When are memory cells first produced?
Primary immune response
Secondary immune response
Neither A or B

38. Humoral
immunity
Active
Passive
Naturally
acquired
Artificially
acquired
Naturally
acquired
Artificially
acquired
Infection;
contact
with
pathogen
Vaccine;
dead or
attenuated
pathogens
Antibodies
pass from
mother to
fetus via
placenta;
or to infant
in her milk
Injection of
immune
serum
(gamma
globulin)

39. Active Humoral Immunity
Occurs when B cells encounter antigens and produce specific antibodies against them
Two types
Naturally acquired—response to a bacterial or viral infection
Artificially acquired—response to a vaccine of dead or attenuated pathogens

40. Active Humoral Immunity
Vaccines
Spare us the symptoms of the primary response
Provide antigenic determinants that are immunogenic and reactive
Downside, target only one type of helper T cell, so fail to fully establish cellular immunological memory

41. Passive Humoral Immunity
Two types
Naturally acquired—antibodies delivered to a fetus via the placenta or to infant through milk
Artificially acquired—injection of serum, such as gamma globulin
Protection is immediate but ends when antibodies naturally degrade in the body
B cells are not challenged by antigens
Immunological memory does not occur

42. What part of the humoral immune defenses includes getting a flu vaccine?
Naturally Acquired Passive
Naturally Acquired Active
Artificially Acquired Passive
Artificially Acquired Active

43. Actions of Antibodies Antibodies inactivate and tag antigens
Form antigen-antibody (immune) complexes
Defensive mechanisms used by antibodies
Neutralization and agglutination (the two most important)
Precipitation and complement fixation

44. (cell-bound antigens)
Antigen-antibody
complex
Antigen
Antibody
Inactivates by
Fixes and activates
Neutralization
(masks dangerous
parts of bacterial
exotoxins; viruses)
Agglutination
(cell-bound antigens)
Precipitation
(soluble antigens)
Complement
Enhances
Enhances
Leads to
Phagocytosis
Inflammation
Cell lysis
Chemotaxis
Histamine
release

45. Cell-Mediated Immunity
Antigen-Presenting Cells (APCs)
Functions
Engulf antigens
Present fragments of antigens to be recognized by T cells
Major types of APCs
Dendritic cells in connective tissues and epidermis
Macrophages in connective tissues
and lymphoid organs
B cells

46. Cell-Mediated Immunity
T cells provide defense against intracellular antigens
Four types of T cells
helper T cells (TH)
cytotoxic T cells (TC) destroy cells harboring foreign antigens
Regulatory T cells (TREG) = Supressor T cells
Memory T cells

47. (or regulatory T cells)
Immature
lymphocyte
Red bone marrow
T cell
receptor
T cell
receptor
Maturation
Class II MHC
protein
Class I MHC
protein
CD4
cell
CD8
cell
Thymus
Activation
Activation
APC
(dendritic cell)
Memory
cells
APC
(dendritic cell)
CD4
CD8
Lymphoid
tissues and
organs
Effector
cells
Helper T cells
(or regulatory T cells)
Cytotoxic T cells
Blood plasma

48. T Cell Activation
APCs (most often a dendritic cell) migrate to lymph nodes and other lymphoid tissues to present their antigens to T cells

49. Antigen Recognition
Immunocompetent T cells are activated when their surface receptors bind to a recognized antigen (nonself) in a receptor on an APC
T cells must simultaneously recognize
Nonself (the antigen)
Self (an MHC protein of a body cell)

50. T Cell Activation Step 2: T cells that are activated
Enlarge, proliferate, and form clones
Differentiate and perform functions according to their T cell class

51. Viral antigen Dendritic cell engulfs an exogenous antigen,
processes it, and
displays its
fragments on class
II MHC protein. 1
Class lI MHC
protein
displaying
processed
viral antigen
Dendritic
cell
CD4 protein
Immunocompetent
CD4 cell recognizes
antigen-MHC
complex. Both TCR
and CD4 protein bind
to antigen-MHC
complex. 2
T cell receptor
(TCR)
Immunocom-
petent CD4
T cell
Clone
formation
CD4 cells are
activated,
proliferate (clone),
and become memory
and effector cells. 3
Helper T
memory cell
Activated
helper
T cells

52. Actions of Helper T Cells
Play a central role in the adaptive immune response
Once primed by APC presentation of antigen
Help activate T and B cells
Induce T and B cell proliferation
Activate macrophages and recruit other immune cells
Without TH, there is no cellular immune response

53. TH cell help in cell-mediated immunity
CD4 protein 1
Helper T cell
Previously
activated TH cell
binds dendritic cell.
Class II MHC
protein
APC (dendritic cell)
TH cell stimulates
dendritic cell to express
co-stimulatory
molecules (not shown)
needed to activate CD8
cell. 2
IL-2
Dendritic cell can
now activate CD8 cell
with the help of
interleukin 2 secreted
by TH cell. 3
Class I
MHC protein
CD8
protein
CD8 T cell

54. When do we produce memory T cells?
Antigen challenge
Primary immune response
Secondary immune response
Both B and C
During a fever

55. Actions of Cytotoxic T Cells
Directly attack and kill other cells
Activated TC cells circulate in blood, lymph and lymphoid organs in search of body cells displaying antigen they recognize
Targets
Virus-infected cells
Cells with intracellular bacteria or parasites
Cancer cells
Foreign cells (transfusions or transplants)

56. 1 2 3 4 5 Adaptive defenses Cellular immunity Cytotoxic T cell (TC)
TC binds tightly to
the target cell when it
identifies foreign antigen
on MHC I proteins. 1
TC releases perforin and
granzyme molecules from its
granules by exocytosis. 2
Granule
Perforin molecules
insert into the target
cell membrane,
polymerize, and form
transmembrane pores
(cylindrical holes)
similar to those
produced by
complement
activation. 3
Perforin
TC cell
membrane
Target
cell
membrane
Granzymes enter the
target cell via the pores.
Once inside, these
proteases degrade
cellular contents,
stimulating apoptosis. 4
Target
cell
Perforin
pore
Granzymes
The TC detaches and
searches for another prey. 5
A mechanism of target cell killing by TC cells.

57. Actions of Regulatory T Cells
Dampen the immune response by direct contact or by inhibitory cytokines
Important in preventing autoimmune reactions

58. physical attack on the Ag
Cell-mediated
immunity
Humoral
immunity
Antigen (Ag) intruder
Inhibits
Inhibits
Triggers
Adaptive defenses
Innate defenses
Surface
barriers
Internal
defenses
Free Ags
may directly
activate B cell
Ag-infected
body cell engulfed
by dendritic cell
Antigen-
activated
B cells
Becomes
Clone and
give rise to
Ag-presenting cell
(APC) presents
self-Ag complex
Activates
Activates
Memory
B cells
Naïve
CD8
T cells
Naïve
CD4
T cells
Activated to clone
and give rise to
Activated to clone
and give rise to
Induce
co-stimulation
Plasma cells
(effector B cells)
Memory
cytotoxic T cells
Memory
helper T cells
Secrete
Activated
cytotoxic
T cells
Activated
helper
T cells
Cytokines stimulate
Antibodies (Igs)
Nonspecific killers
(macrophages and
NK cells of innate
immunity)
Circulating lgs along with
complement mount a chemical
attack on the Ag
Together the nonspecific killers
and cytotoxic T cells mount a
physical attack on the Ag