1. Chapter 24
The Immune System

2. Introduction Neutrophils are a kind of white blood cell,
Neutrophils are
a kind of white blood cell,
capable of recognizing and destroying foreign invaders, and
part of the body’s immune system.
© 2012 Pearson Education, Inc. 2

3. Introduction The human body’s immune system
The human body’s immune system
recognizes agents that cause disease and
attacks them.
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4. Disorders of the Immune System
Figure 24.0_1
Chapter 24: Big Ideas
Innate Immunity
Adaptive Immunity
Figure 24.0_1 Ch 24: Big Ideas
Disorders of the Immune System 4

5. Figure 24.0_2
Figure 24.0_2 Neutrophil engulfing four bacteria 5

6. INNATE IMMUNITY
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7. 24.1 All animals have innate immunity
Nearly everything in the environment teems with pathogens, agents that cause disease.
The immune system is the body’s system of defenses against agents that cause disease.
Innate immunity is a series of defenses that
act immediately upon infection and
are the same whether or not the pathogen has been encountered before.
Student Misconceptions and Concerns
Students may be frustrated by the amount of detail about the immune system provided in this chapter, and struggle to organize information about the many types of cells and responses. Asking them to create or complete tables, similar to the one in Figure 24.1, can help your students manage the information presented in the textbook and in your class discussions.
Teaching Tips
1. Students might be interested to learn that interferons are now mass-produced using recombinant DNA technology. Clinical studies are under way to explore their use in treating viral infections and cancer.
2. In an interesting article on the effectiveness of common hygiene methods, “Hygiene of the Skin: When Is Clean Too Clean?” Elaine Larson reviews the relationship between skin hygiene and infection. It can be found at the CDC website at
© 2012 Pearson Education, Inc. 7

8. 24.1 All animals have innate immunity
Invertebrates rely solely on innate immunity, which may consist of
an exoskeleton,
low pH,
the enzyme lysozyme, and
immune cells capable of phagocytosis, cellular ingestion and digestion of foreign substances.
Vertebrates have innate and adaptive immunity.
Student Misconceptions and Concerns
Students may be frustrated by the amount of detail about the immune system provided in this chapter, and struggle to organize information about the many types of cells and responses. Asking them to create or complete tables, similar to the one in Figure 24.1, can help your students manage the information presented in the textbook and in your class discussions.
Teaching Tips
1. Students might be interested to learn that interferons are now mass-produced using recombinant DNA technology. Clinical studies are under way to explore their use in treating viral infections and cancer.
2. In an interesting article on the effectiveness of common hygiene methods, “Hygiene of the Skin: When Is Clean Too Clean?” Elaine Larson reviews the relationship between skin hygiene and infection. It can be found at the CDC website at
© 2012 Pearson Education, Inc. 8

9. • Mucous membranes • Hairs • Cilia • Phagocytic cells
Figure 24.1A
Innate immunity (24.1–3) The response is the same whether or not the pathogen has been previously encountered
Adaptive immunity (24.4–15) Found only in vertebrates; previous exposure to the pathogen enhances the immune response
External barriers (24.1)
Internal defenses (24.1–2)
• Skin/ exoskeleton
• Acidic environment
• Secretions
• Mucous membranes • Hairs • Cilia
• Phagocytic cells
• NK cells • Defensive proteins
• Inflammatory response (24.2)
• Antibodies (24.8–10) • Lymphocytes (24.11–13)
Figure 24.1A An overview of animal immune systems
The lymphatic system (24.3) 9

10. 24.1 All animals have innate immunity
Vertebrate innate immunity includes
barriers such as skin and mucous membranes,
interferons, proteins produced by virus-infected cells, that help to limit the cell-to-cell spread of viruses,
neutrophils (phagocytic cells),
macrophages, large phagocytic cells that wander through the interstitial fluid,
natural killer cells that attack cancer cells and virus-infected cells, and
a complement system, a group of about 30 kinds of proteins that can act with other defense mechanisms.
Student Misconceptions and Concerns
Students may be frustrated by the amount of detail about the immune system provided in this chapter, and struggle to organize information about the many types of cells and responses. Asking them to create or complete tables, similar to the one in Figure 24.1, can help your students manage the information presented in the textbook and in your class discussions.
Teaching Tips
1. Students might be interested to learn that interferons are now mass-produced using recombinant DNA technology. Clinical studies are under way to explore their use in treating viral infections and cancer.
2. In an interesting article on the effectiveness of common hygiene methods, “Hygiene of the Skin: When Is Clean Too Clean?” Elaine Larson reviews the relationship between skin hygiene and infection. It can be found at the CDC website at
© 2012 Pearson Education, Inc. 10

11. Antiviral proteins block viral reproduction Virus
Figure 24.1B
Viral nucleic acid
Antiviral proteins block viral reproduction
Virus 1
New viruses 2
Interferon genes turn on
DNA
mRNA 3 5
Interferon molecules
Interferon stimulates cell to turn on genes for antiviral proteins
Figure 24.1B The interferon mechanism against viruses 4
Host cell 1
Host cell 2
Makes interferon; is killed by the virus
Is protected against the virus by interferon from cell 1 11

12. 24.2 Inflammation mobilizes the innate immune response
Tissue damage triggers the inflammatory response, a major component of our innate immunity, which can
disinfect and clean infected tissues and
limit the spread of infection to surrounding tissues.
Bacterial infections can bring about an overwhelming systemic inflammatory response leading to septic shock, characterized by
very high fever and
low blood pressure.
Student Misconceptions and Concerns
Students may be frustrated by the amount of detail about the immune system provided in this chapter, and struggle to organize information about the many types of cells and responses. Asking them to create or complete tables, similar to the one in Figure 24.1, can help your students manage the information presented in the textbook and in your class discussions.
Teaching Tips
1. The inflammatory response described in Module 24.2 and characterized in Figure 24.2 provides a good student hook for this chapter. The inflammatory response is a reaction that is immediately apparent, with characteristics that can cause alarm. Students are typically more interested in subjects that have obvious relevance to their lives, including potential threats to their health!
2. Excessive amounts of iron in the human body can promote bacterial infections and other disease. Searching for the key words iron supplements bacteria on the CDC website at will turn up many articles on this subject.
© 2012 Pearson Education, Inc. 12

13. Figure 24.2 The inflammatory response
Pin
Skin surface
Blood clot
Swelling
Bacteria
Phagocytes and fluid move into the area
Phagocytes
Signaling molecules
White blood cell
Figure 24.2 The inflammatory response
Blood vessel 1
Tissue injury; signaling molecules, such as histamine, are released. 2
Dilation and increased leakiness of local blood vessels; phagocytes
migrate to the area. 3
Phagocytes (macrophages and neutrophils) consume bacteria and cellular debris; the tissue heals. 13

14. Tissue injury; signaling molecules, such as histamine, are released.
Figure 24.2_1
Pin
Skin surface
Bacteria
Signaling molecules
White blood cell
Figure 24.2_1 The inflammatory response: tissue injury (part 1)
Blood vessel 1
Tissue injury; signaling molecules, such as histamine, are released. 14

15. Phagocytes and fluid move into the area
Figure 24.2_2
Blood clot
Swelling
Phagocytes and fluid move into the area
Figure 24.2_2 The inflammatory response: phagocyte migration (part 2) 2
Dilation and increased leakiness of local blood vessels; phagocytes migrate to the area. 15

16. Figure 24.2_3
Phagocytes
Figure 24.2_3 The inflammatory response: phagocytes consume bacteria (part 3) 3
Phagocytes (macrophages and neutrophils) consume bacteria and cellular debris; the tissue heals. 16

17. 24.3 The lymphatic system becomes a crucial battleground during infection
The lymphatic system is
involved in innate and adaptive immunity and
consists of a network of
lymphatic vessels,
lymph nodes, and
lymph.
Student Misconceptions and Concerns
Students may be frustrated by the amount of detail about the immune system provided in this chapter, and struggle to organize information about the many types of cells and responses. Asking them to create or complete tables, similar to the one in Figure 24.1, can help your students manage the information presented in the textbook and in your class discussions.
Teaching Tips
1. Excessive amounts of iron in the human body can promote bacterial infections and other disease. Searching for the key words iron supplements bacteria on the CDC website at will turn up many articles on this subject.
2. During a medical examination, a physician might feel for tenderness in the throat, axillary (armpit), and inguinal (groin) regions. Students are unlikely to appreciate the significance of this part of the exam. Making this connection for them can add relevance to your class discussions and generate additional interest in the subject.
© 2012 Pearson Education, Inc. 17

18. 24.3 The lymphatic system becomes a crucial battleground during infection
Lymphatic vessels
collect fluid from body tissues and
return it as lymph to the blood.
Lymph organs
include the spleen and lymph nodes and
are packed with white blood cells that fight infections.
Student Misconceptions and Concerns
Students may be frustrated by the amount of detail about the immune system provided in this chapter, and struggle to organize information about the many types of cells and responses. Asking them to create or complete tables, similar to the one in Figure 24.1, can help your students manage the information presented in the textbook and in your class discussions.
Teaching Tips
1. Excessive amounts of iron in the human body can promote bacterial infections and other disease. Searching for the key words iron supplements bacteria on the CDC website at will turn up many articles on this subject.
2. During a medical examination, a physician might feel for tenderness in the throat, axillary (armpit), and inguinal (groin) regions. Students are unlikely to appreciate the significance of this part of the exam. Making this connection for them can add relevance to your class discussions and generate additional interest in the subject.
© 2012 Pearson Education, Inc. 18

19. 24.3 The lymphatic system becomes a crucial battleground during infection
As lymph circulates through lymphatic organs it
collects
microbes,
parts of microbes, and
microbial toxins, and
transports them to lymphatic organs where
macrophages in lymphatic organs engulf the invaders and
lymphocytes may mount an adaptive immune response.
Student Misconceptions and Concerns
Students may be frustrated by the amount of detail about the immune system provided in this chapter, and struggle to organize information about the many types of cells and responses. Asking them to create or complete tables, similar to the one in Figure 24.1, can help your students manage the information presented in the textbook and in your class discussions.
Teaching Tips
1. Excessive amounts of iron in the human body can promote bacterial infections and other disease. Searching for the key words iron supplements bacteria on the CDC website at will turn up many articles on this subject.
2. During a medical examination, a physician might feel for tenderness in the throat, axillary (armpit), and inguinal (groin) regions. Students are unlikely to appreciate the significance of this part of the exam. Making this connection for them can add relevance to your class discussions and generate additional interest in the subject.
© 2012 Pearson Education, Inc. 19

20. Figure 24.3
Organs
Adenoid
Lymphatic ducts that drain into veins
Lymph node
Tonsils
Lymph nodes
Masses of lymphocytes and macrophages
Thymus
Lymphatic vessels
Valve
Lymphatic vessel
Spleen
Blood capillary
Tissue cells
Interstitial fluid
Appendix
Bone marrow
Figure 24.3 The human lymphatic system
Lymphatic capillary 20

21. Lymphatic ducts that drain into veins Tonsils
Figure 24.3_1
Organs
Adenoid
Lymphatic ducts that drain into veins
Tonsils
Lymph nodes
Thymus
Lymphatic vessels
Spleen
Appendix
Bone marrow
Figure 24.3_1 The human lymphatic system (part 1) 21

22. Masses of lymphocytes and macrophages
Figure 24.3_2
Lymph node
Masses of lymphocytes and macrophages
Valve
Lymphatic vessel
Blood capillary
Tissue cells
Interstitial fluid
Figure 24.3_2 The human lymphatic system (part 2)
Lymphatic capillary 22

23. ADAPTIVE IMMUNITY
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24. 24.4 The adaptive immune response counters specific invaders
Our immune system responds to foreign molecules called antigens, which elicit the adaptive immune response.
The adaptive immune system
is found only in the vertebrates,
reacts to specific pathogens, and
“remembers” an invader.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
3. The concept of nonspecific and specific defenses is sometimes difficult for students new to the subject. Some analogies, such as the following, might help. Clothing can be considered a general defense against heat loss, minor surface abrasions, and minor chemical damage such as sunburn. Sunscreen is a specific defense, intended to limit exposure to ultraviolet radiation in particular.
Teaching Tips
The old saying “Give a man a fish and you have fed him for today; teach a man to fish and you have fed him for a lifetime” can be compared to the concept of passive and active immunity. Passive immunity, like the gift of a fish, is temporary. However, active immunity, like the ability to fish, can last a lifetime!
© 2012 Pearson Education, Inc. 24

25. 24.4 The adaptive immune response counters specific invaders
Infection or vaccination triggers active immunity.
Vaccination, or immunization, exposes the immune system to a vaccine,
a harmless variant or
part of a disease-causing microbe.
We can temporarily acquire passive immunity by receiving premade antibodies.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
3. The concept of nonspecific and specific defenses is sometimes difficult for students new to the subject. Some analogies, such as the following, might help. Clothing can be considered a general defense against heat loss, minor surface abrasions, and minor chemical damage such as sunburn. Sunscreen is a specific defense, intended to limit exposure to ultraviolet radiation in particular.
Teaching Tips
The old saying “Give a man a fish and you have fed him for today; teach a man to fish and you have fed him for a lifetime” can be compared to the concept of passive and active immunity. Passive immunity, like the gift of a fish, is temporary. However, active immunity, like the ability to fish, can last a lifetime!
© 2012 Pearson Education, Inc. 25

26. Figure 24.4
Figure 24.4 A soldier receiving a vaccination against the smallpox virus (inset) 26

27. Figure 24.4_1
Figure 24.4_1 A soldier receiving a vaccination against the smallpox virus (part 1) 27

28. Figure 24.4_2
Figure 24.4_2 A soldier receiving a vaccination against the smallpox virus (part 2) 28

29. 24.5 Lymphocytes mount a dual defense
Lymphocytes
are white blood cells that spend most of their time in the tissues and organs of the lymphatic system,
are responsible for adaptive immunity, and
originate from stem cells in the bone marrow.
B lymphocytes or B cells continue developing in bone marrow.
T lymphocytes or T cells develop further in the thymus.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
Many analogies can be developed relating to the cells and molecules involved in the immune response. In Module 24.5, the authors note that lymphocytes, which can respond to any antigen, resemble a standing army of soldiers in which each soldier is able to recognize a unique form of the enemy.
© 2012 Pearson Education, Inc. 29

30. 24.5 Lymphocytes mount a dual defense
B cells
participate in the humoral immune response and
secrete antibodies into the blood and lymph.
T cells
participate in the cell-mediated immune response,
attack cells infected with bacteria or viruses, and
promote phagocytosis by other white blood cells and by stimulating B cells to produce antibodies.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
Many analogies can be developed relating to the cells and molecules involved in the immune response. In Module 24.5, the authors note that lymphocytes, which can respond to any antigen, resemble a standing army of soldiers in which each soldier is able to recognize a unique form of the enemy.
© 2012 Pearson Education, Inc. 30

31. Figure 24.5A The development of B cells and T cells
Stem cell
Bone marrow
Via blood
Immature lymphocytes
Thymus
Antigen receptors
Via blood
B cell
T cell
Figure 24.5A The development of B cells and T cells
Final maturation of B and T cells in a lymphatic organ
Lymph nodes, spleen, and other lymphatic organs
Humoral immune response
Cell-mediated immune response 31

32. Via blood Antigen receptors
Figure 24.5A_1
Stem cell
Bone marrow
Via blood
Immature lymphocytes
Figure 24.5A_1 The development of B cells and T cells (part 1)
Thymus
Antigen receptors
B cell
T cell 32

33. Final maturation of B and T cells in a lymphatic organ
Figure 24.5A_2
Antigen receptors
Via blood
B cell
T cell
Final maturation of B and T cells in a lymphatic organ
Lymph nodes, spleen, and other lymphatic organs
Figure 24.5A_2 The development of B cells and T cells (part 2)
Humoral immune response
Cell-mediated immune response 33

34. 24.5 Lymphocytes mount a dual defense
Millions of kinds of B cells and T cells
each with different antigen receptors, capable of binding one specific type of antigen,
wait in the lymphatic system,
where they may respond to invaders.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
Many analogies can be developed relating to the cells and molecules involved in the immune response. In Module 24.5, the authors note that lymphocytes, which can respond to any antigen, resemble a standing army of soldiers in which each soldier is able to recognize a unique form of the enemy.
© 2012 Pearson Education, Inc. 34

35. Figure 24.5B
Figure 24.5B A B cell (left) and T cell (right) 35

36. 24.6 Antigens have specific regions where antibodies bind to them
Antigens
are molecules that elicit the adaptive immune response,
usually do not belong to the host animal, and
are proteins or large polysaccharides on the surfaces of viruses or foreign cells.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
The authors suggest that the specific “fit” between an antigen and an antibody is like the relationship between a lock and a key. You might further this analogy by noting that the tremendous diversity of antibodies is like having a set of keys for virtually every possible type of lock.
© 2012 Pearson Education, Inc. 36

37. 24.6 Antigens have specific regions where antibodies bind to them
Antigenic determinants are specific regions on an antigen where antibodies bind.
An antigen usually has several different determinants.
The antigen-binding site of an antibody and an antigenic determinant have complementary shapes.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
The authors suggest that the specific “fit” between an antigen and an antibody is like the relationship between a lock and a key. You might further this analogy by noting that the tremendous diversity of antibodies is like having a set of keys for virtually every possible type of lock.
© 2012 Pearson Education, Inc. 37

38. Two different antibody molecules
Figure 24.6
Antigen- binding site
Two different antibody molecules
Antigen molecule
Antigenic determinant
Figure 24.6 The binding of antibodies to antigenic determinants 38

39. 24.7 Clonal selection musters defensive forces against specific antigens
When an antigen enters the body it activates only a small subset of lymphocytes that have complementary receptors.
In clonal selection, the selected lymphocyte cells
multiply into clones of short-lived effector cells, specialized for defending against the antigen that triggered the response, and
multiply into memory cells, which confer long-term immunity.
Plasma cells are the effector cells produced during clonal selection of B cells.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
Our own learning experiences provide an analogy to the greater swiftness and intensity of a secondary immune response. When first presented with a problem, we may struggle to determine how best to respond. However, with that first experience behind us, we expect to respond more quickly and effectively when we meet that challenge again. Although in each circumstance we benefit from a certain type of memory (experiential in one case, chemical in the other) their mechanisms are quite different. Consider noting these similarities and differences in your class discussion of primary and secondary immune responses.
© 2012 Pearson Education, Inc. 39

40. 24.7 Clonal selection musters defensive forces against specific antigens
The clonal selection of B cells occurs in two responses.
In the primary immune response, clonal selection produces
effector cells and
memory cells that may confer lifelong immunity.
In the secondary immune response, memory cells are activated by a second exposure to the same antigen.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
Our own learning experiences provide an analogy to the greater swiftness and intensity of a secondary immune response. When first presented with a problem, we may struggle to determine how best to respond. However, with that first experience behind us, we expect to respond more quickly and effectively when we meet that challenge again. Although in each circumstance we benefit from a certain type of memory (experiential in one case, chemical in the other) their mechanisms are quite different. Consider noting these similarities and differences in your class discussion of primary and secondary immune responses.
© 2012 Pearson Education, Inc. 40

41. Animation: Role of B Cells
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
Our own learning experiences provide an analogy to the greater swiftness and intensity of a secondary immune response. When first presented with a problem, we may struggle to determine how best to respond. However, with that first experience behind us, we expect to respond more quickly and effectively when we meet that challenge again. Although in each circumstance we benefit from a certain type of memory (experiential in one case, chemical in the other) their mechanisms are quite different. Consider noting these similarities and differences in your class discussion of primary and secondary immune responses.
Animation: Role of B Cells
Right click on animation / Click play
© 2012 Pearson Education, Inc. 41

42. Clone of plasma (effector) cells secreting antibodies
Figure 24.7A
Primary immune response
Secondary immune response 2
Antigen molecules
Antigen receptor on the cell surface
Antibody molecules 1
B cells with different antigen receptors 3
First exposure to the antigen
Cell activation: growth, division, and differentiation
Clone of plasma (effector) cells secreting antibodies
Antigen molecules
Second clone
Antibody molecules 4 5 6
Second exposure to the same antigen
First clone
Figure 24.7A Clonal selection of B cells in the primary and secondary immune responses
Endoplasmic reticulum
Clone of memory cells
Plasma (effector) cells secreting antibodies
Memory cells 42

43. Primary immune response
Figure 24.7A_s1
Primary immune response
Antigen receptor on the cell surface
B cells with different antigen receptors 1
Figure 24.7A_s1 Clonal selection of B cells: primary response (part 1, step 1) 43

44. Primary immune response
Figure 24.7A_s2
Primary immune response 2
Antigen molecules
Antigen receptor on the cell surface
B cells with different antigen receptors 1
Figure 24.7A_s2 Clonal selection of B cells: primary response (part 1, step 2) 44

45. Primary immune response
Figure 24.7A_s3
Primary immune response 2
Antigen molecules
Antigen receptor on the cell surface
B cells with different antigen receptors 1 3
First exposure to the antigen
Cell activation: growth, division, and differentiation
Figure 24.7A_s3 Clonal selection of B cells: primary response (part 1, step 3) 45

46. Primary immune response
Figure 24.7A_s4
Primary immune response 2
Antigen molecules
Antigen receptor on the cell surface
B cells with different antigen receptors 1 3
First exposure to the antigen
Cell activation: growth, division, and differentiation
Antibody molecules
Figure 24.7A_s4 Clonal selection of B cells: primary response (part 1, step 4) 4 5
First clone
Endoplasmic reticulum
Plasma (effector) cells secreting antibodies
Memory cells 46

47. Second exposure to the same antigen
Figure 24.7A_s5
Antigen molecules 6
Second exposure to the same antigen
Figure 24.7A_s5 Clonal selection of B cells: secondary response (part 2, step 1)
Memory cells 47

48. Clone of plasma (effector) cells secreting antibodies
Figure 24.7A_s6
Secondary immune response
Antibody molecules
Antigen molecules
Clone of plasma (effector) cells secreting antibodies 6
Second exposure to the same antigen
Second clone
Figure 24.7A_s6 Clonal selection of B cells: secondary response (part 2, step 2)
Clone of memory cells
Memory cells 48

49. 24.7 Clonal selection musters defensive forces against specific antigens
Primary vs. secondary immune responses
The primary immune response
occurs upon first exposure to an antigen and
is slower than the secondary immune response.
The secondary immune response
occurs upon second exposure to an antigen and
is faster and stronger than the primary immune response.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
Our own learning experiences provide an analogy to the greater swiftness and intensity of a secondary immune response. When first presented with a problem, we may struggle to determine how best to respond. However, with that first experience behind us, we expect to respond more quickly and effectively when we meet that challenge again. Although in each circumstance we benefit from a certain type of memory (experiential in one case, chemical in the other) their mechanisms are quite different. Consider noting these similarities and differences in your class discussion of primary and secondary immune responses.
© 2012 Pearson Education, Inc. 49

50. Second exposure to antigen X, first exposure to antigen Y
Figure 24.7B
Second exposure to antigen X, first exposure to antigen Y
Secondary immune response to antigen X
First exposure to antigen X
Antibody concentration
Primary immune response to antigen X
Primary immune response to antigen Y
Figure 24.7B The two phases of the adaptive immune response
Antibodies to X
Antibodies to Y 7 14 21 28 35 42 49 56
Time (days) 50

51. 24.8 Antibodies are the weapons of the humoral immune response
Antibodies are secreted
by plasma (effector) B cells,
into the blood and lymph.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
Challenge your class to explain the adaptive advantages of antibodies’ Y-shaped structure. Why aren’t antibodies just made up of a single heavy and a single light chain? (Biologists have theorized that the Y shape permits the bonding together of two antigens or antigen-presenting surfaces, allowing a chain reaction or form of clumping.)
© 2012 Pearson Education, Inc. 51

52. Light chain Heavy chain Figure 24.8A
Figure 24.8A A computer graphic of an antibody molecule 52

53. 24.8 Antibodies are the weapons of the humoral immune response
An antibody molecule
is Y-shaped and
has two antigen-binding sites specific to the antigenic determinants that elicited its secretion.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
Challenge your class to explain the adaptive advantages of antibodies’ Y-shaped structure. Why aren’t antibodies just made up of a single heavy and a single light chain? (Biologists have theorized that the Y shape permits the bonding together of two antigens or antigen-presenting surfaces, allowing a chain reaction or form of clumping.)
© 2012 Pearson Education, Inc. 53

54. Antigen-binding sites
Figure 24.8B
Antigen
Antigen-binding sites V V V V C C
Light chain C C
Figure 24.8B Antibody structure and the binding of an antigen-binding site to its complementary antigen (enlargement)
Heavy chain 54

55. 24.9 Antibodies mark antigens for elimination
Antibodies promote antigen elimination through several mechanisms:
neutralization, binding to surface proteins on a virus or bacterium and blocking its ability to infect a host,
agglutination, using both binding sites of an antibody to join invading cells together into a clump,
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
1. Challenge your class to explain the adaptive advantages of antibodies’ Y-shaped structure. Why aren’t antibodies just made up of a single heavy and a single light chain? (Biologists have theorized that the Y shape permits the bonding together of two antigens or antigen-presenting surfaces, allowing a chain reaction or form of clumping.)
2. Figure 24.9 depicts four effector mechanisms and their consequences. This figure organizes the information and relates the processes to each other, making comparisons easier. Such figures are especially helpful for students. Highlighting such figures in your lecture helps students follow up after class discussions by identifying the most relevant sections of their textbook assignments.
© 2012 Pearson Education, Inc. 55

56. 24.9 Antibodies mark antigens for elimination
precipitation, similar to agglutination, except that the antibody molecules link dissolved antigen molecules together, and
activation of the complement system by antigen-antibody complexes.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
1. Challenge your class to explain the adaptive advantages of antibodies’ Y-shaped structure. Why aren’t antibodies just made up of a single heavy and a single light chain? (Biologists have theorized that the Y shape permits the bonding together of two antigens or antigen-presenting surfaces, allowing a chain reaction or form of clumping.)
2. Figure 24.9 depicts four effector mechanisms and their consequences. This figure organizes the information and relates the processes to each other, making comparisons easier. Such figures are especially helpful for students. Highlighting such figures in your lecture helps students follow up after class discussions by identifying the most relevant sections of their textbook assignments.
© 2012 Pearson Education, Inc. 56

57. Animation: Antibodies
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
1. Challenge your class to explain the adaptive advantages of antibodies’ Y-shaped structure. Why aren’t antibodies just made up of a single heavy and a single light chain? (Biologists have theorized that the Y shape permits the bonding together of two antigens or antigen-presenting surfaces, allowing a chain reaction or form of clumping.)
2. Figure 24.9 depicts four effector mechanisms and their consequences. This figure organizes the information and relates the processes to each other, making comparisons easier. Such figures are especially helpful for students. Highlighting such figures in your lecture helps students follow up after class discussions by identifying the most relevant sections of their textbook assignments.
Animation: Antibodies
Right click on animation / Click play
© 2012 Pearson Education, Inc. 57

58. Figure 24.9 Effector mechanisms of the humoral immune response
Binding of antibodies to antigens inactivates antigens by
Neutralization (blocks viral binding sites; coats bacteria)
Agglutination of microbes
Precipitation of dissolved antigens
Activation of the complement system
Complement molecule
Bacteria
Virus
Antigen molecules
Bacterium
Foreign cell
Hole
Enhances
Leads to
Figure 24.9 Effector mechanisms of the humoral immune response
Phagocytosis
Cell lysis
Macrophage 58

59. Neutralization (blocks viral binding sites; coats bacteria)
Figure 24.9_1
Neutralization (blocks viral binding sites; coats bacteria)
Agglutination of microbes
Precipitation of dissolved antigens
Bacteria
Virus
Antigen molecules
Bacterium
Enhances
Figure 24.9_1 Effector mechanisms of the humoral immune response (part 1)
Phagocytosis
Macrophage 59

60. Activation of the complement system
Figure 24.9_2
Activation of the complement system
Complement molecule
Foreign cell
Hole
Leads to
Cell lysis
Figure 24.9_2 Effector mechanisms of the humoral immune response (part 2) 60

61. 24.10 CONNECTION: Monoclonal antibodies are powerful tools in the lab and clinic
Monoclonal antibodies (mAb) are
identical antibodies
produced by cells that are all descendants of a single, hybrid cell.
To make the hybrid cell with desirable properties, two cells are fused.
A cancerous tumor cell, able to multiply indefinitely, is fused to
a normal antibody-producing B cell, which is producing the desired antibody.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
Once produced, monoclonal antibodies have the ability to specifically identify one particular antigen and bind to it. Challenge your class to think of analogies to this reaction. As you and your class evaluate the analogies, help your class check the analogy against a proper understanding of monoclonal antibody properties (an important point in this chapter). (One possible analogy might be the use of a Phillips screwdriver to turn only Phillips-shaped screw heads.)
© 2012 Pearson Education, Inc. 61

62. Early pregnancy (hCG in the blood and urine)
Figure 24.10
Early pregnancy (hCG in the blood and urine)
Urine is applied to the strip
hCG
hCG/mAb complex
Control mAb
hCG
Figure Monoclonal antibodies used in a home pregnancy test 62

63. 24.10 CONNECTION: Monoclonal antibodies are powerful tools in the lab and clinic
Monoclonal antibodies are useful in
research,
diagnosis (such as home pregnancy tests), and
treatment of certain cancers.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
Once produced, monoclonal antibodies have the ability to specifically identify one particular antigen and bind to it. Challenge your class to think of analogies to this reaction. As you and your class evaluate the analogies, help your class check the analogy against a proper understanding of monoclonal antibody properties (an important point in this chapter). (One possible analogy might be the use of a Phillips screwdriver to turn only Phillips-shaped screw heads.)
© 2012 Pearson Education, Inc. 63

64. 24.11 Helper T cells stimulate the humoral and cell-mediated immune responses
In the cell-mediated immune response, an antigen-presenting cell displays
a foreign antigen (a nonself molecule) and
one of the body’s own self proteins
to a helper T cell.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
1. The authors note that the recognition by a helper T cell of a self protein and a foreign antigen in combination is like the two-key system used by banks to access safe-deposit boxes.
2. Your students might find the descriptions in Modules and to be particularly confusing, as the interactions of many cell types are described. Figures and help to simplify the details of these interactions.
© 2012 Pearson Education, Inc. 64

65. 24.11 Helper T cells stimulate the humoral and cell-mediated immune responses
The helper T cell’s receptors
recognize the self–nonself complexes and
the interaction activates the helper T cells.
The helper T cell can then activate
cytotoxic T cells, which attack body cells that are infected with pathogens, and
B cells.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
1. The authors note that the recognition by a helper T cell of a self protein and a foreign antigen in combination is like the two-key system used by banks to access safe-deposit boxes.
2. Your students might find the descriptions in Modules and to be particularly confusing, as the interactions of many cell types are described. Figures and help to simplify the details of these interactions.
© 2012 Pearson Education, Inc. 65

66. Animation: Helper T Cells
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
1. The authors note that the recognition by a helper T cell of a self protein and a foreign antigen in combination is like the two-key system used by banks to access safe-deposit boxes.
2. Your students might find the descriptions in Modules and to be particularly confusing, as the interactions of many cell types are described. Figures and help to simplify the details of these interactions.
Animation: Helper T Cells
Right click on animation / Click play
© 2012 Pearson Education, Inc. 66

67. Video: T Cell Receptors
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
1. The authors note that the recognition by a helper T cell of a self protein and a foreign antigen in combination is like the two-key system used by banks to access safe-deposit boxes.
2. Your students might find the descriptions in Modules and to be particularly confusing, as the interactions of many cell types are described. Figures and help to simplify the details of these interactions.
Video: T Cell Receptors
Use window controls to play
© 2012 Pearson Education, Inc. 67

68. Figure 24.11
Humoral immune response (secretion of antibodies by plasma cells)
Phagocytic cell (yellow) engulfing a foreign cell
Self-nonself complex
B cell
Interleukin-2 stimulates cell division
T cell receptor
Microbe
Macrophage 3 5 6
Interleukin-2 activates B cells and other T cells 1 2
Helper T cell 4 7
Figure The activation of a helper T cell and its roles in immunity
Self protein
Cell-mediated immune response (attack on infected cells)
Binding site for the self protein
Antigen-presenting cell
Cytotoxic T cell
Antigen from the microbe (nonself molecule)
Interleukin-1 stimulates the helper T cell
Binding site for the antigen 68

69. Antigen-presenting cell Antigen from the microbe (nonself molecule)
Figure 24.11_1
Self-nonself complex
Macrophage
Microbe 3 1 2
Figure 24.11_1 The activation of a helper T cell and its roles in immunity (part 1)
Self protein
Antigen-presenting cell
Antigen from the microbe (nonself molecule) 69

70. Interleukin-2 stimulates cell division T cell receptor
Figure 24.11_2
Self-nonself complex
B cell
Interleukin-2 stimulates cell division
T cell receptor 5 6 3
Interleukin-2 activates B cells and other T cells 2
Helper T cell 4 7
Figure 24.11_2 The activation of a helper T cell and its roles in immunity (part 2)
Binding site for the self protein
Antigen- presenting cell
Cytotoxic T cell
Interleukin-1 stimulates the helper T cell
Binding site for the antigen 70

71. Phagocytic cell (yellow) engulfing a foreign cell
Figure 24.11_3
Figure 24.11_3 The activation of a helper T cell and its roles in immunity (micrograph)
Phagocytic cell (yellow) engulfing a foreign cell 71

72. 24.12 Cytotoxic T cells destroy infected body cells
Cytotoxic T cells
are the only T cells that kill infected cells,
bind to infected body cells, and
destroy them.
Cytotoxic T cells also play a role in protecting the body against the spread of some cancers.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
1. Your students might find the descriptions in Modules and to be particularly confusing, as the interactions of many cell types are described. Figures and help to simplify the details of these interactions.
2. The destruction of an infected cell by a cytotoxic T cell provides an obvious opportunity for a fight analogy. The two cells become interlocked “in battle,” the infected cell develops “puncture wounds,” and a fatal poison is absorbed into these “wounds.”
© 2012 Pearson Education, Inc. 72

73. Animation: Cytotoxic T Cells
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
1. Your students might find the descriptions in Modules and to be particularly confusing, as the interactions of many cell types are described. Figures and help to simplify the details of these interactions.
2. The destruction of an infected cell by a cytotoxic T cell provides an obvious opportunity for a fight analogy. The two cells become interlocked “in battle,” the infected cell develops “puncture wounds,” and a fatal poison is absorbed into these “wounds.”
Animation: Cytotoxic T Cells
Right click on animation / Click play
© 2012 Pearson Education, Inc. 73

74. A cytotoxic T cell binds to an infected cell.
Figure 24.12_s1 1
A cytotoxic T cell binds to an infected cell.
Self-nonself complex
Foreign antigen
Infected cell
Cytotoxic T cell
Perforin molecule
Figure 24.12_s1 How a cytotoxic T cell kills an infected cell (step 1) 74

75. A cytotoxic T cell binds to an infected cell.
Figure 24.12_s2 1
A cytotoxic T cell binds to an infected cell. 2
Perforin makes holes in the infected cell’s membrane, and an enzyme that promotes apoptosis enters.
Self-nonself complex
A hole forming
Foreign antigen
Infected cell
Enzymes that promote apoptosis
Cytotoxic T cell
Perforin molecule
Figure 24.12_s2 How a cytotoxic T cell kills an infected cell (step 2) 75

76. A cytotoxic T cell binds to an infected cell.
Figure 24.12_s3 1
A cytotoxic T cell binds to an infected cell. 2
Perforin makes holes in the infected cell’s membrane, and an enzyme that promotes apoptosis enters. 3
The infected cell is destroyed.
Self-nonself complex
A hole forming
Foreign antigen
Infected cell
Enzymes that promote apoptosis
Cytotoxic T cell
Perforin molecule
Figure 24.12_s3 How a cytotoxic T cell kills an infected cell (step 3) 76

77. 24.13 CONNECTION: HIV destroys helper T cells, compromising the body’s defenses
AIDS (acquired immunodeficiency syndrome), results from infection by HIV, the human immunodeficiency virus.
Since 1981 AIDS has killed more than 27 million people, and more than 33 million people live today with HIV.
In 2008,
2.7 million people were newly infected with HIV, and
over 2 million died, including 300,000 children under age 15.
Most AIDS infections and deaths occur in nonindustrialized nations of southern Asia and sub-Saharan Africa.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
1. The Centers for Disease Control and Prevention has extensive information about AIDS and other public health threats on its website at
2. Students often do not understand how disproportionately distributed cases of HIV and AIDS now are in our world. Consider assigning students to identify the regions of the world most affected by HIV/AIDS by performing Internet research. The web site is a good starting point.
3. Despite efforts to educate the general public, many misconceptions about AIDS persist. A list of 18 common misconceptions can be found at the website
© 2012 Pearson Education, Inc. 77

78. 24.13 CONNECTION: HIV destroys helper T cells, compromising the body’s defenses
The AIDS virus usually attacks helper T cells, impairing the
cell-mediated immune response and
humoral immune response, and
opening the way for opportunistic infections.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
1. The Centers for Disease Control and Prevention has extensive information about AIDS and other public health threats on its website at
2. Students often do not understand how disproportionately distributed cases of HIV and AIDS now are in our world. Consider assigning students to identify the regions of the world most affected by HIV/AIDS by performing Internet research. The web site is a good starting point.
3. Despite efforts to educate the general public, many misconceptions about AIDS persist. A list of 18 common misconceptions can be found at the website
© 2012 Pearson Education, Inc. 78

79. 24.13 CONNECTION: HIV destroys helper T cells, compromising the body’s defenses
AIDS patients typically die from
opportunistic infections and
cancers
that would normally be resisted by a person with a healthy immune system.
Until there is a vaccine or a cure, the best way to stop AIDS is to educate people about how the virus is transmitted.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
1. The Centers for Disease Control and Prevention has extensive information about AIDS and other public health threats on its website at
2. Students often do not understand how disproportionately distributed cases of HIV and AIDS now are in our world. Consider assigning students to identify the regions of the world most affected by HIV/AIDS by performing Internet research. The web site is a good starting point.
3. Despite efforts to educate the general public, many misconceptions about AIDS persist. A list of 18 common misconceptions can be found at the website
© 2012 Pearson Education, Inc. 79

80. Animation: HIV Reproductive Cycle
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
1. The Centers for Disease Control and Prevention has extensive information about AIDS and other public health threats on its website at
2. Students often do not understand how disproportionately distributed cases of HIV and AIDS now are in our world. Consider assigning students to identify the regions of the world most affected by HIV/AIDS by performing Internet research. The web site is a good starting point.
3. Despite efforts to educate the general public, many misconceptions about AIDS persist. A list of 18 common misconceptions can be found at the website
Animation: HIV Reproductive Cycle
Right click on animation / Click play
© 2012 Pearson Education, Inc. 80

81. Figure 24.13
Figure A human helper T cell (red) under attack by HIV (blue dots) 81

82. 24.14 EVOLUTION CONNECTION: The rapid evolution of HIV complicates AIDS treatment
HIV mutates very quickly.
New strains are resistant to AIDS drugs.
Drug-resistant strains now infect new patients.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
1. The Centers for Disease Control and Prevention has extensive information about AIDS and other public health threats on its website at
2. Students often do not understand how disproportionately distributed cases of HIV and AIDS now are in our world. Consider assigning students to identify the regions of the world most affected by HIV/AIDS by performing Internet research. The web site is a good starting point.
3. Despite efforts to educate the general public, many misconceptions about AIDS persist. A list of 18 common misconceptions can be found at the website
© 2012 Pearson Education, Inc. 82

83. Figure 24.14
Figure A “cocktail” of three separate drugs, the current treatment for people living with HIV 83

84. 24.15 The immune system depends on our molecular fingerprints
The immune system normally reacts
only against nonself substances and
not against self.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
Students may enter your course knowing that the best types of tissue transplants are from a closely matched donor. However, what does it mean to have a tissue “match”? Few students can explain the specific reasons behind the need for tissue matching, or how such matching is done. Challenge your students to explain why we try to ensure a match between the tissues of a donor and a recipient. By posing such general questions, instructors can raise interest in the specific details of the answers.
© 2012 Pearson Education, Inc. 84

85. 24.15 The immune system depends on our molecular fingerprints
Transplanted organs may be rejected because the transplanted cells lack the unique “fingerprint” of the patient’s self proteins, called major histocompatibility complex (MHC) molecules.
Donors are used that most closely match the patient’s tissues.
Transplants between identical twins do not typically have this problem.
Student Misconceptions and Concerns
1. For students with limited science backgrounds, this section of the chapter can be particularly difficult; for some, it is the most challenging part of the textbook. Students must have a solid knowledge of the properties of different cells and their interactions, and understand that repeated exposure to antigens generates new interactions. The challenge is similar to explaining a new sport to someone unfamiliar to the game. (Imagine explaining the rules and strategies of football or poker to someone who had never heard of them.) Instructors might consider slowing their pace and using learning aids such as reference lists of cell types and their functions, or diagrams that remind students of these cellular interactions.
2. Having students read relevant material before it is addressed in lecture is one of the best ways to improve student comprehension. Before lecturing on a topic, identify specific textbook modules that should be read before you address them in class. Reading before lecture can lay a foundation that makes the lecture much more meaningful. However, it helps in other ways, too. As students listen in lecture, they know if definitions in lecture are included in the book, and students are already aware of which figures outline certain processes.
Teaching Tips
Students may enter your course knowing that the best types of tissue transplants are from a closely matched donor. However, what does it mean to have a tissue “match”? Few students can explain the specific reasons behind the need for tissue matching, or how such matching is done. Challenge your students to explain why we try to ensure a match between the tissues of a donor and a recipient. By posing such general questions, instructors can raise interest in the specific details of the answers.
© 2012 Pearson Education, Inc. 85

86. DISORDERS OF THE IMMUNE SYSTEM
DISORDERS OF THE IMMUNE SYSTEM
© 2012 Pearson Education, Inc. 86

87. 24.16 CONNECTION: Malfunction or failure of the immune system causes disease
Autoimmune diseases occur when the immune system turns against the body’s own molecules.
Examples of autoimmune diseases include
lupus,
rheumatoid arthritis,
insulin-dependent diabetes mellitus, and
multiple sclerosis.
Student Misconceptions and Concerns
1. Student interest in diseases and allergies can provide motivation for learning in this final module. However, researching a medical subject without the necessary background to fully understand it often leads to confusion. Consider probing for misunderstandings about autoimmune diseases and allergies by asking students about their causes and treatments.
2. Students may believe that anything “natural” is somehow good. In addition to the many natural poisons found in animals and plants, our allergic responses to pollen, molds, and other environmental allergens remind us that “natural” is not always healthy.
Teaching Tips
Although the triggers of autoimmune diseases are not well understood, it does appear that autoimmune diseases are not communicable, and cannot be caught through exposure to others with the disease. Family histories of autoimmune diseases do suggest some degree of heritability, at least of predisposition. Thus, some family members may share degrees of a common autoimmune disease.
© 2012 Pearson Education, Inc. 87

88. Figure 24.16
Figure An X-ray image of hands affected by rheumatoid arthritis 88

89. 24.16 CONNECTION: Malfunction or failure of the immune system causes disease
Immunodeficiency diseases occur when an immune response is
defective or
absent.
The immune system may be weakened by
physical stress or
emotional stress.
Students are more likely to be sick during a week of exams.
Student Misconceptions and Concerns
1. Student interest in diseases and allergies can provide motivation for learning in this final module. However, researching a medical subject without the necessary background to fully understand it often leads to confusion. Consider probing for misunderstandings about autoimmune diseases and allergies by asking students about their causes and treatments.
2. Students may believe that anything “natural” is somehow good. In addition to the many natural poisons found in animals and plants, our allergic responses to pollen, molds, and other environmental allergens remind us that “natural” is not always healthy.
Teaching Tips
Although the triggers of autoimmune diseases are not well understood, it does appear that autoimmune diseases are not communicable, and cannot be caught through exposure to others with the disease. Family histories of autoimmune diseases do suggest some degree of heritability, at least of predisposition. Thus, some family members may share degrees of a common autoimmune disease.
© 2012 Pearson Education, Inc. 89

90. 24.17 CONNECTION: Allergies are overreactions to certain environmental antigens
Allergies are hypersensitive (exaggerated) responses to otherwise harmless antigens in our surroundings.
Antigens that cause allergies are called allergens.
Student Misconceptions and Concerns
1. Student interest in diseases and allergies can provide motivation for learning in this final module. However, researching a medical subject without the necessary background to fully understand it often leads to confusion. Consider probing for misunderstandings about autoimmune diseases and allergies by asking students about their causes and treatments.
2. Students may believe that anything “natural” is somehow good. In addition to the many natural poisons found in animals and plants, our allergic responses to pollen, molds, and other environmental allergens remind us that “natural” is not always healthy.
Teaching Tips
1. Allergic contact dermatitis occurs when an allergen triggers an immune response on the skin. One example is the rash that results from exposure to poison ivy.
2. As noted in Module 24.17, antihistamines are drugs that interfere with the action of histamine. They provide temporary relief from the symptoms of allergic reactions. Therefore, a person suffering from a severe reaction to poison ivy might find some relief by taking antihistamines. Unfortunately, antihistamines can also produce drowsiness.
© 2012 Pearson Education, Inc. 90

91. 24.17 CONNECTION: Allergies are overreactions to certain environmental antigens
Allergic reactions typically occur
very rapidly and
in response to tiny amounts of an allergen.
Allergic reactions can occur in many parts of the body, including
nasal passages,
bronchi, and
skin.
Student Misconceptions and Concerns
1. Student interest in diseases and allergies can provide motivation for learning in this final module. However, researching a medical subject without the necessary background to fully understand it often leads to confusion. Consider probing for misunderstandings about autoimmune diseases and allergies by asking students about their causes and treatments.
2. Students may believe that anything “natural” is somehow good. In addition to the many natural poisons found in animals and plants, our allergic responses to pollen, molds, and other environmental allergens remind us that “natural” is not always healthy.
Teaching Tips
1. Allergic contact dermatitis occurs when an allergen triggers an immune response on the skin. One example is the rash that results from exposure to poison ivy.
2. As noted in Module 24.17, antihistamines are drugs that interfere with the action of histamine. They provide temporary relief from the symptoms of allergic reactions. Therefore, a person suffering from a severe reaction to poison ivy might find some relief by taking antihistamines. Unfortunately, antihistamines can also produce drowsiness.
© 2012 Pearson Education, Inc. 91

92. 24.17 CONNECTION: Allergies are overreactions to certain environmental antigens
The symptoms of an allergy result from a two-stage reaction.
The first stage, called sensitization, occurs when a person is first exposed to an allergen.
The second stage begins when the person is exposed to the same allergen later.
The allergen binds to mast cells.
Mast cells release histamine, causing irritation, itchy skin, and tears.
Student Misconceptions and Concerns
1. Student interest in diseases and allergies can provide motivation for learning in this final module. However, researching a medical subject without the necessary background to fully understand it often leads to confusion. Consider probing for misunderstandings about autoimmune diseases and allergies by asking students about their causes and treatments.
2. Students may believe that anything “natural” is somehow good. In addition to the many natural poisons found in animals and plants, our allergic responses to pollen, molds, and other environmental allergens remind us that “natural” is not always healthy.
Teaching Tips
1. Allergic contact dermatitis occurs when an allergen triggers an immune response on the skin. One example is the rash that results from exposure to poison ivy.
2. As noted in Module 24.17, antihistamines are drugs that interfere with the action of histamine. They provide temporary relief from the symptoms of allergic reactions. Therefore, a person suffering from a severe reaction to poison ivy might find some relief by taking antihistamines. Unfortunately, antihistamines can also produce drowsiness.
© 2012 Pearson Education, Inc. 92

93. Figure 24.17 The two stages of an allergic reaction
Sensitization: Initial exposure to an allergen
Later exposure to the same allergen
B cell (plasma cell)
Mast cell
Antigenic determinant
Histamine 1
An allergen (pollen grain) enters the bloodstream.
Figure The two stages of an allergic reaction 2
B cells make antibodies. 3
Antibodies attach to a mast cell. 4
The allergen binds to antibodies on a mast cell. 5
Histamine is released, causing allergy symptoms. 93

94. Sensitization: Initial exposure to an allergen
Figure 24.17_1
Sensitization: Initial exposure to an allergen
B cell (plasma cell)
Mast cell
Figure 24.17_1 The two stages of an allergic reaction (part 1)
Antigenic determinant
Histamine 1
An allergen (pollen grain) enters the bloodstream. 2
B cells make antibodies. 3
Antibodies attach to a mast cell. 94

95. Later exposure to the same allergen
Figure 24.17_2
Later exposure to the same allergen
Figure 24.17_2 The two stages of an allergic reaction (part 2) 4
The allergen binds to antibodies on a mast cell. 5
Histamine is released, causing allergy symptoms. 95

96. 24.17 CONNECTION: Allergies are overreactions to certain environmental antigens
Antihistamines
interfere with histamine’s action,
provide temporary relief, but
often make people drowsy.
Anaphylactic shock
is an extreme life-threatening allergic reaction and
can be treated with injections of epinephrine.
Student Misconceptions and Concerns
1. Student interest in diseases and allergies can provide motivation for learning in this final module. However, researching a medical subject without the necessary background to fully understand it often leads to confusion. Consider probing for misunderstandings about autoimmune diseases and allergies by asking students about their causes and treatments.
2. Students may believe that anything “natural” is somehow good. In addition to the many natural poisons found in animals and plants, our allergic responses to pollen, molds, and other environmental allergens remind us that “natural” is not always healthy.
Teaching Tips
1. Allergic contact dermatitis occurs when an allergen triggers an immune response on the skin. One example is the rash that results from exposure to poison ivy.
2. As noted in Module 24.17, antihistamines are drugs that interfere with the action of histamine. They provide temporary relief from the symptoms of allergic reactions. Therefore, a person suffering from a severe reaction to poison ivy might find some relief by taking antihistamines. Unfortunately, antihistamines can also produce drowsiness.
© 2012 Pearson Education, Inc. 96

97. You should now be able to
Describe the functions of neutrophils.
Describe the nature of innate defenses in invertebrates and vertebrates.
Describe the steps of the inflammatory response and explain how they help to prevent the spread of disease.
Describe the specific nature of adaptive immune system responses.
Describe the development and functions of B lymphocytes and T lymphocytes.
© 2012 Pearson Education, Inc. 97

98. You should now be able to
Define and distinguish between the humoral immune response and the cell-mediated immune response.
Describe the nature of antigens. Explain how an antigen and an antibody interact.
Describe the process of clonal selection and compare a primary immune response to a secondary immune response.
Describe the specific structure of an antibody and relate its shape to its functions.
© 2012 Pearson Education, Inc. 98

99. You should now be able to
Describe four effector mechanisms of the humoral immune system.
Describe the production and uses of monoclonal antibodies.
Describe the specific functions of helper T cells and how they interact with other cells.
Explain how cytotoxic T cells destroy infected body cells.
Explain how HIV infects cells, multiplies, and causes disease.
© 2012 Pearson Education, Inc. 99

100. You should now be able to
Explain why it has been difficult to develop a successful treatment for AIDS.
Explain how the immune system identifies the body’s own molecules and how this system complicates organ transplantations.
Describe how the malfunction or failure of the immune system can cause disease.
Explain why allergies occur and what causes anaphylactic shock.
© 2012 Pearson Education, Inc.
100

101. The humoral immune response:
Figure 24.UN01
The humoral immune response:
makes
which bind to
B cell
Antibodies
Antigens in body fluid
The cell-mediated immune response:
Infected body cell
Figure 24.UN01 Reviewing the Concepts, 24.5
T cell
Self-nonself complex
101

102. Figure 24.UN02 Connecting the Concepts, question 1
Body’s defenses
include
(a)
(b)
is present
found in
is present
found in
vertebrates and invertebrates
only after exposure
at birth
vertebrates
produced by cells called
Lymphocytes
include
Figure 24.UN02 Connecting the Concepts, question 1
responsible for
cell-mediated immune response
(c)
(d)
secrete
responsible for
include
humoral immune response
stimulate
cytotoxic T cells
(e)
(f)
stimulate
102

103. vertebrates and invertebrates produced by cells called
Figure 24.UN02_1
Body’s defenses
include
(a)
(b)
is present
found in
is present
found in
vertebrates and invertebrates
only after exposure
at birth
vertebrates
Figure 24.UN02_1 Connecting the Concepts, question 1 (part 1)
produced by cells called
Lymphocytes
103

104. cell-mediated immune response humoral immune response
Figure 24.UN02_2
Lymphocytes
include
responsible for
cell-mediated immune response
(c)
(d)
secrete
responsible for
include
stimulate
Figure 24.UN02_2 Connecting the Concepts, question 1 (part 2)
humoral immune response
cytotoxic T cells
(e)
(f)
stimulate
104

105. Figure 24.17_UN01
Figure 24.17_UN01 An “epi pen” for counteraction of anaphylactic shock
105