Exam IV

Question 1

What is MHC?

Answer 1

Major Histocompatibility Complex protein

Question 2

Where is MHC located?

Answer 2

On the surface of plasma membrane of cells

Question 3

Which type of T cells do MHC class I and MHC class II interacts with?

Answer 3

MHC Class I = Tc and CTL cells
MHC class II = Th cells.

Question 4

What happens when an MHC class I protein is bound to an antigen?

Answer 4

It interacts with a Tc or CTL cell

Question 5

What happens when an MHC class I protein is not bound to an antigen?

Answer 5

It keeps NK cells from killing the cell.

Question 6

What type of cells are MHC class II proteins found on?

Answer 6

APC cells including dendritic, macrophages and B cells.

Question 7

On what type of cells are MHC class I proteins found on?

Answer 7

On all cells.

Question 8

When an MHC class II protein is bound to an antigen, what does it do?

Answer 8

Interacts with Th cells.

Question 9

What is TCR?

Answer 9

T cell receptor.

Question 10

What does a TCR do?

Answer 10

A TCR (T cell receptor) is used by T cells to interact with antigens displayed by MHC.

Question 11

What is used by T cells to interact with antigens displayed by MHC?

Answer 11

TCR (T cell receptor)

Question 12

What are CDs?

Answer 12

Clusters of differentiation

Question 13

What are clusters of differentiation (CDs) used for and what are the types?

Answer 13

CDs are co-receptors that help T cells distinguish between MHC I and II proteins.
CD4 and CD8

Question 14

What is CD4 used for?

Answer 14

CD4 is a cluster of differentiation that is found on Th cells to distinguish MHC class II cells.

Question 15

What cluster of differentiation is found on Th cells to distinguish MHC class II cells?

Answer 15

CD4

Question 16

What is CD8 used for?

Answer 16

CD8 is a cluster of differentiation that is found on Tc cells and recognizes MHC class I proteins.

Question 17

What type of cluster of differentiation is found on Tc cells and recognizes MHC class I proteins?

Answer 17

CD8

Question 18

Th are what?

Answer 18

T helper cells

Question 19

What do T helpers do?

Answer 19

Th cells recognize an antigen presented by an APC on an MHC class II protein.

Question 20

What type of cell recognizes an antigen presented by an APC on an MHC class II protein?

Answer 20

T helper

Question 21

What do cytotoxic T cells do?

Answer 21

Tc cells recognize an antigen presented by an APC on an MHC class I protein (all cells).

Question 22

What cells recognize an antigen presented by an APC on an MHC class I protein (all cells)?

Answer 22

Cytotoxic T cells (Tc)

Question 23

What do activated T helper cells do?

Answer 23

Divide and differentiate into several cell types, including memory cells.

Question 24

What type of T cell when activated divides and differentiate into several cell types, including memory cells?

Answer 24

T helper cells

Question 25

What do activated cytotoxic T cells do?

Answer 25

Differentiate into CTLs (Cytotoxic T lymphocytes).

Question 26

What type of cells differentiate into CTLs (Cytotoxic T lymphocytes) when activated?

Answer 26

Cytotoxic T cells (Tc)

Question 27

What class of MHC protein are CTLs associated with?

Answer 27

MHC class I

Question 28

What do CTLs do?

Answer 28

CTLs recognize antigens displayed by MHC class I proteins on the surface of a cell.

Question 29

What happens when a CTL attaches to cell?

Answer 29

Releases:
Perforin (pore-forming protein)
granzymes and proteases that cause apoptosis (programmed cell death)

Question 30

What cells release:
Perforin (pore-forming protein)
Granzymes
Proteases
That cause apoptosis (programmed cell death)

Answer 30

CTLs

Question 31

When does a cytotoxic T cell become a CTL?

Answer 31

When the Tc recognizes the antigen displayed by an MHC class I cell, it differentiates into a cytotoxic T lymphocytes (CTL).

Question 32

What are B cells covered with?

Answer 32

One type of antibody: IgD

Question 33

What do B cells do?

Answer 33

IgD antibody binds to antigen.
B cell presents to T helper cells
B cell becomes activated by Th cells
B cell divides and differentiates into memory and plasma cells.

Question 34

What do B memory cells do?

Answer 34

Remain dormant until exposed to antigen in the future. Then divide and differentiate into plasma cells when exposed to the antigen in the future.

Question 35

What do plasma cells do?

Answer 35

Produce lots of antibodies and secrete them into the blood.

Question 36

Where do plasma cells secrete antibodies?

Answer 36

Into the blood

Question 37

What do memory B cells do when exposed to the antigen for which they were first made?

Answer 37

They divide and differentiate into plasma cells.

Question 38

Memory B cells are long lived? T/F

Answer 38

True

Question 39

What cells are long lived and can divide and differentiate into plasma cells at a later date when exposed to the same antigen?

Answer 39

Memory B cells

Question 40

What is an epitope?

Answer 40

The part of an antigen that binds to a specific antigen receptor on a B cell.

Question 41

What is a part of an antigen that binds to a specific antigen receptor on a B cell?

Answer 41

An epitope.

Question 42

What are immunoglobulins?

Answer 42

Antibodies.

Question 43

What initiates B cell activation?

Answer 43

The antibody (immunoglobulin) on the B cell surface binds to the epitope (specific receptor on the antigen) and both antigen and antibody are taken into the B cell.

Question 44

What happens to the antigen/antibody complex once it’s taken into a B cell?

Answer 44

It is processed into smaller pieces and then a fragment of the antigen is presented on the B cell surface on an MHC class II protein to attract a T helper cell. Then the Th cell produces cytokines that activate the B cell.

Question 45

What type of antibody do plasma cells secrete large amounts of?

Answer 45

IgG specific to the activated B cell

Question 46

What type of cell produces large amounts of IgG antibodies?

Answer 46

Plasma cells

Question 47

What do antigens need to have to stimulate B cells without Th cells?

Answer 47

Repeating subunits that can bind to multiple B cell receptors

Question 48

What can antigens that have repeating subunits do when binding to multiple B cell receptors?

Answer 48

Eliminate the need for T helper cell activation of the B cell.

Question 49

What do all of the activation methods of the complement system lead to activation of?

Answer 49

C3

Question 50

What are opsonins?

Answer 50

Antibodies or other substances that bind to antigens making them more susceptible to phagocytosis (IgG antibodies and the C3b molecules of the complement system).

Question 51

What is opsonization?

Answer 51

A process where antigens are marked for phagocytosis.

Question 52

What happens to C3 to activate it?

Answer 52

C3 is cleaved into C3a and C3b.

Question 53

What does C3b do?

Answer 53

As the activated part of C3:
C3b binds to an antigen surface to aid in attachment of phagocytes (opsonization)
C3b cleaves C5 into C5a and C5b

Question 54

What do C3a and C5a do?

Answer 54

Bind to mast cells and stimulate the release of histamine and other chemicals to increase vessel permeability during inflammation.

Question 55

In the complement system, what happens to C5b, C6, C7 and C8?

Answer 55

C5b, C6, C7 and C8 bind together (form a complex) and insert into the membrane of bacterial cells.

Question 56

What does the C5b, C6, C7 and C8 complex act as?

Answer 56

Acts as a receptor that attracts C9.

Question 57

How does C9 behave in the complement system?

Answer 57

Multiple C9 fragments form a transmembrane channel. C9 fragments, together with the C5b, C6, C7 and C8 complex, form the MAC (membrane attack complex).

Question 58

What is the MAC and what does it do?

Answer 58

The MAC (membrane attack complex) is an end product of the complement system whereby the C5b, C6, C7 and C8 complex and the C9 fragments join forces. This acts as a channel which leads to cytolysis of the bacterial cell.

Question 59

What are the protective outcomes of each part of the complement system?

Answer 59

Opsonization: C3 cleaves into C3a and C3b, where C3b binds to membrane of microbe (opsonin) to facilitate attachment of phagocytes.

Inflammation: C3a and C5a bind to mast cells and stimulate histamine release to increase vessel permeability during inflammation.

Cytolysis: C5b, C6, C7 and C8 combine with C9 fragments to create the MAC (membrane attack complex) that acts as a channel into the bacteria cell which leads to cell lysis.

Question 60

Define each protective outcomes of the complement system.

Answer 60

Opsonization: C3 cleaves into C3a and C3b, where C3b binds to membrane of microbe (opsonin) to facilitate attachment of phagocytes.

Inflammation: C3a and C5a bind to mast cells and stimulate histamine release to increase vessel permeability during inflammation.

Cytolysis: C5b, C6, C7 and C8 combine with C9 fragments to create the MAC (membrane attack complex) that acts as a channel into the bacteria cell which leads to cell lysis.

Question 61

What system do opsonization, inflammation and cytolysis signify?

Answer 61

The complement system

Question 62

What are three ways the complement system can be activated?

Answer 62

Classical, alternative and lectin pathways

Question 63

What controls the classical activation pathway of the complement system?

Answer 63

Antibodies

Question 64

What happens in the classical activation pathway of the complement system?

Answer 64

Antibodies attach to antigens on the surface of the microbe.

Question 65

When antibodies attach to antigens on the surface of microbes, what is recruited in the classical pathway of the complement system?

Answer 65

C1
C1 cleaves C2 to C2a and C2b and C4 to C4a and C4b
C2a and C4b combine and activate C3 by cleaving it into C3a and C3b

Question 66

What has to happen at the end of each pathway–classical, alternative and lectin–of the complement system to achieve activation?

Answer 66

C3 must be cleaved into C3a and C3b

Question 67

What substances are employed in the alternative pathway of the complement system?

Answer 67

Protein factors, specifically Factor B, factor D and factor P

Question 68

To what system are Factor B, factor D and factor P important?

Answer 68

The alternative pathway of the complement system

Question 69

What are lectins?

Answer 69

Proteins that bind to carbohydrates found on the surface of microbes.

Question 70

What are lectins produced by and when are they produced?

Answer 70

Lectins are produced by the liver in response to cytokine release by macrophages after they ingest bacteria, viruses or foreign matter.

Question 71

When do macrophages release cytokines?

Answer 71

After they ingest microorganisms or foreign matter.

Question 72

Are lectins specific to certain carbohydrates?

Answer 72

Yes, specific lectins bind to specific carbohydrates.

Question 73

What is an example of lectins that bind to a specific carbohydrate?

Answer 73

Mannose-binding lectin binds to the carb mannose found in cell walls and viral particles. It cleaves C2 and C4, C2a and C4b combine to split C3 into C3a and C3b (as in the classical pathway).

Question 74

In the complement system alternative pathway, how do the protein factors activate C3?

Answer 74

Protein factors B, D and P recruit C3 and cleave it into C3a and C3b.

Question 75

What do the classical and lectin pathways of the complement system have in common when activating C3?

Answer 75

The classical starts with C1 and the lectin starts with C2, but they both cleave C2 and C4 and end with C2a and C4b combining to cleave C3 into C3a and C3b.

Question 76

In the complement system, how does the alternative pathway differ in the activation of C3 from the classical and lectin pathways?

Answer 76

The alternative pathway protein factors directly recruit C3 and cleave it into C3a and C3b.

Question 77

Name three ways that microbes evolved to avoid the complement system.

Answer 77

Capsules that can prevent complement activation.

Sialic acid in capsules discourages opsonization and MAC formation.

Some gram + cocci release an enzyme that breaks down C5a (w/ C3a binds with mast cells) which stops the activation cascade.

Question 78

Capsules, sialic acid, and gram + cocci enzymes are examples of what?

Answer 78

Ways in which microbes have evolved to avoid the complement system.

Question 79

What is the innate immune system?

Answer 79

That part of the immune system that people are born with that does not depend on B or T cells. It includes the 1st and 2nd lines of defense.

Question 80

Granulocytes and agranulocytes are involved in what segment of immunity?

Answer 80

Innate - 2nd line of defense

Question 81

Name 3 types of granulocytes

Answer 81

Neutrophils, eosinophils, basophils

Question 82

What is a neutrophil?

Answer 82

A type of granulocyte that is highly phagocytic and motile, can leave the blood and travel into the tissues to destroy microbes and foreign particles.

Question 83

What is a basophil?

Answer 83

A type of granulocyte that releases histamine for the inflammation and allergic response.

Question 84

What is an eosinophil?

Answer 84

A type of granulocyte that has phagocytic properties and can leave the blood (like neutrophils). Major function is to produce toxic proteins to defend against parasites (like helminths).

Question 85

How do eosinophils attack parasites?

Answer 85

Attach to the surface of the parasite and discharge peroxide ions and digestive enzymes.

Question 86

Name three types of agranulocytes.

Answer 86

Monocytes, dendritic cells and lymphocytes.

Question 87

What types of blood cells are highly phagocytic?

Answer 87

Neutrophils and macrophages

Question 88

Is a monocyte phagocytic?

Answer 88

Not actively phagocytic until it matures into a macrophage.

Question 89

What is a monocyte?

Answer 89

A slightly phagocytic agranulocyte that matures into a macrophage when leaving the blood and entering the tissues.

Question 90

What are macrophages?

Answer 90

Highly phagocytic antigen presenting cells that matured from monocytes in the blood when they entered the tissues. Have MHC class II proteins on membrane that interact with T helper cells.

Question 91

What is a dendritic cell?

Answer 91

An agranulocyte with long extension like a nerve cell that destroy microbes by phagocytosis and initiate adaptive immunity responses. Have MHC class II proteins on plasma membrane that interact with T helper cells.

Question 92

What are lymphocytes?

Answer 92

Agranular blood cells that include NK cells that check for non-self cells (MHC class I - Tc cells), T cells that regulate adaptive immune response and are responsible for cellular immunity, and B cells that produce antibodies in humoral or antibody-mediated immunity in adaptive immunity.

Question 93

NK, B and T cells are what type of blood cells?

Answer 93

Lymphocytes

Question 94

List 5 classes of antibodies

Answer 94

IgG, IgD, IgE, IgA, IgM

Question 95

What are IgG antibodies?

Answer 95

IgG are monomers produced by plasma cells (most common - 80%)

Question 96

What are IgD antibodies?

Answer 96

IgD are monomers similar to IgG found on B cell surface in blood and lymph. Involved in immune response initiation in B cells.

Question 97

Which antibody is responsible for immune response initiation in B cells?

Answer 97

IgD, because they cover B cell surface membrane.

Question 98

What are IgE antibodies?

Answer 98

Monomers slightly larger than IgG, very rare in serum. Fc (stem) of IgE bound to receptors on mast cell and basophils (allergic rxs). Binding of IgE to attached cell releases histamine and mediators to provoke an allergic response.

Question 99

What are IgM antibodies?

Answer 99

Pentameter - Five monomers joined by polypeptide J chain. Causes clumping of bound antigens (agglutination).

Many antigen-binding sites.

Appear first in immune response and are short lived.

Question 100

What antibody appears first in an immune response and is short lived?

Answer 100

IgM

Question 101

What antibody is a pentameter?

Answer 101

IgM

Question 102

What antibody that binds to a cell releases histamine?

Answer 102

IgE (mast cells and basophils)

Question 103

What antibody causes agglutination?

Answer 103

IgM - the pentameter

Question 104

Which antibody has many antigen-binding sites?

Answer 104

IgM

Question 105

Which antibodies are most common?

Answer 105

IgG

Question 106

What antibodies are produced by plasma cells?

Answer 106

IgG

Question 107

What is an IgA antibody?

Answer 107

Two monomers joined by J chain a polypeptide called secretory component that protects IgA from enzymatic degradation. Most common in secretions (mucus, saliva, tears and breast milk). Protects newborns from gastrointestinal infection.

Question 108

What antibody is made of two monomers?

Answer 108

IgA

Question 109

What antibody has a polypeptide called secretory component and what does it do?

Answer 109

IgA, protects IgA from enzymatic degradation.

Question 110

What type of macromolecule is secretory component of IgA antibodies?

Answer 110

Polypeptide

Question 111

What is the most common antibody in bodily secretions including breast milk?

Answer 111

IgA

Question 112

Which antibodies are monomers?

Answer 112

IgG, IgE, IgD

Question 113

Which antibodies are not monomers?

Answer 113

IgM - pentameter

IgA - two monomers

Question 114

What antibody is found on the surface of B cells?

Answer 114

IgD

Question 115

What is an antigen?

Answer 115

Anything that causes antibody formation.

Question 116

What is anything that causes antibody formation?

Answer 116

An antigen

Question 117

What macromolecules are most antigens made of?

Answer 117

Polypeptides (large proteins) or polysaccharides.

Question 118

What region of an antigen do antibodies interact with?

Answer 118

The epitope or antigenic determinant.

Question 119

What is the antigenic determinant?

Answer 119

The epitope or the region of an antigen that antibodies interact with

Question 120

What is the relationship between antibodies and antigens?

Answer 120

Antigens have an epitope or antigenic determinant that is recognized by and interacts with the antibody.

Question 121

Essay:

What are five protective outcomes of antigen-antibody binding?

Answer 121

Agglutination (IgM)

Opsonization (IgD)

Neutralization

Antibody-dependent cell-mediated cytotoxicity (eosinophils)

Activation of complement system (MAC, opsonization, inflammatory response (basophils))

Question 122

How does antibody-antigen agglutination offer protective outcome?

Answer 122

Antibodies cause antigens to clump together to make easier to ingest by phagocytes (IgM ).

Question 123

How does antibody-antigen opsonization offer protective outcomes?

Answer 123

Antigen is coated with antibodies (opsonins) that bind to phagocytes and aid in ingestion and lysis by phagocytic cells.

Question 124

How does antibody-antigen neutralization offer protective outcomes?

Answer 124

Antibodies inactivate microbes by disrupting their shape, make external antigen structures nonfunctional, prevent virions from binding to host, neutralize exotoxins by block binding to substrate.

Question 125

How does antibody-dependent cell-mediated cytotoxicity offer protective outcomes?

Answer 125

Signal eosinophils to release enzymes that kill the parasite (microbe).

Question 126

How does activation of the complement system offer protective outcomes?

Answer 126

Activates complement system to kill invading cells by cytolysis (from MAC) opsonization and activation of the inflammatory response.

Question 127

What is humoral immunity?

Answer 127

Immunity bought about by antibodies dissolved in body fluids, mediated by B cells (also antibody-mediated immunity).

Question 128

What is cellular immunity?

Answer 128

The immune response that involves cytotoxic T cells binding to antigens presented on antigen-presenting cells. Tc causes infected cell to go through apoptosis (controlled suicide)

Question 129

What type of lymphocyte is cellular immunity based on?

Answer 129

Cytotoxic T cells

Question 130

Cytotoxic T cells are involved in what type of immunity?

Answer 130

Cellular immunity or cell-mediated immunity

Question 131

B cells are involved in what type of immunity?

Answer 131

Antibody-mediated or humoral immunity

Question 132

What is apoptosis?

Answer 132

Cellular suicide cause by cytotoxic T cells in cellular or cell-mediated immunity

Question 133

What is chemotaxis?

Answer 133

Chemical attraction of phagocytes to microorganisms.

Question 134

What chemicals can cause chemotaxis?

Answer 134

Cytokines produced by WBCs, peptides derived from complement system, components of white blood cells and damaged tissue.

Question 135

What are the four steps in phagocytosis and intracellular digestion?

Answer 135

Chemotaxis, adherence, ingestion, digestion.

Question 136

What happens during phagocytosis with adherence?

Answer 136

Attachment of the phagocyte’s plasma membrane receptors to the surface of the microorganism.
Facilitated by attachment of pathogen-associated molecular patterns (PAMS) to receptors (i.e, Toll-like receptors on surface of phagocytes). Opsonins promote attachment through opsonization.

Question 137

What happens during phagocytosis in ingestion?

Answer 137

The plasma membrane of the phagocyte extends pseudopods meet and fuse, around the microbe within a vesicle called
a phagosome.

Question 138

Where in phagocytosis and intercellular digestion does a vesicle called a phagosome house the invading microbe?

Answer 138

During ingestion.

Question 139

What is a phagosome?

Answer 139

A vesicle that is created by the meeting and fusing of the pseudopod around the invading microbe within the phagocyte.

Question 140

What happens in the digestion phase of phagocytosis or intercellular digestion?

Answer 140

The phagosome fuses with lysosomes to form phagolysosome. After digestion, remaining undigestible content (residual body) is discharged from cell.

Question 141

What are lysosomes in intercellular digestion?

Answer 141

Vesicles that contain digestive enzymes used in digestion of intercellular contents.

Question 142

What is a phagolysosome?

Answer 142

The combination of the phagosome (the cell that will phagocytize the microbe) and the enzymes (lysosomes) that will digest the microbe.

Question 143

Two ways microbes avoid phagocytosis.

Answer 143

Bacteria have structures that resist adherence. Other microbes kill the phagocyte from the inside by releasing proteins that disrupt the plasma membrane..

Question 144

Essay question: Koch’s four postulates

Answer 144

1. Every case
2. Pure culture
3. Injected
4. Isolated
5. Same pathogen must be present in every case of the disease.
6. Pathogen must be isolated from diseased host and grown in pure culture.
7. Pathogen from pure culture must cause the disease when injected into new healthy, susceptible lab animal.
8. Pathogen must be isolated from the diseased animal and shown to be the original microbe.

Question 145

Put Koch’s postulates in correct order:

1. Pathogen must be isolated from diseased host and grown in pure culture.
2. Pathogen from pure culture must cause the disease when injected into new healthy, susceptible lab animal.
3. Same pathogen must be present in every case of the disease.
4. Pathogen must be isolated from the diseased animal and shown to be the original microbe.

Answer 145

3, 1, 2, 4

Question 146

What is the procedure for Koch’s postulate?

Answer 146

1. Microorganisms are isolated from a diseased or dead individual.
2. The microorganisms are grown in pure culture and individually identified.
3. The microorganisms are individually introduced into new, healthy test organisms. Test organisms are observed for development of signs that are similar to those experienced by first organism.
4. Microorganisms are isolated from test organisms that develop similar signs to the original organism to show that the injected microorganisms multiplied inside the test organism (causing the disease signs).

Question 147

Four situations where Koch’s postulates don’t apply

Answer 147

1. Organism cannot be cultured in the lab.
2. Several different types of organisms cause the same signs.
3. Several disease conditions are caused by some microorganisms.
4. Some microorganisms have no other known host (other than humans)

Question 148

Five stages of disease

Answer 148

Incubation
Prodromal
Illness
Decline
Convalescence

Question 149

What is the incubation period of disease?

Answer 149

Interval between initial infection and the appearance of symptoms.

Question 150

What is the prodromal period of disease?

Answer 150

Short period following incubation characterized by early, mild symptoms.

Question 151

What is the level of microbes in the prodromal period of disease?

Answer 151

Low number of microbes but increasing

Question 152

What happens in the period of illness stage of the five stages of disease?

Answer 152

Signs and symptoms most severe: fever, chills, muscle pain, sensitivity to light, sore throat, lymph node enlargement, gastrointestinal disturbances. If disease is not successfully overcome, death occurs.

Question 153

At what stage of the five stages of disease does death occur?

Answer 153

Illness stage

Question 154

In what state of the five stages of disease is the level of microbes the highest?

Answer 154

The illness stage

Question 155

What happens in the period of decline in the five stages of disease?

Answer 155

Signs and symptoms subside. Number of microbes peaks and declines. Lasts less than 24 hours to several days.

Question 156

In what stage of the five stages of disease do microbes peak and decline?

Answer 156

Period of decline

Question 157

What happens in the period of convalescence in the five stages of disease?

Answer 157

Person regains strength and body returns to pre-disease state. Number of infecting microbes decreases to zero.

Question 158

What is the level of microbes in the period of convalescence?

Answer 158

Zero

Question 159

What are the level of microbes in each of the five stages of disease?

Answer 159

Incubation period - Very low
Prodromal period - Low but increasing
Period of illness - Highest
Period of decline - Peak and decline
Convalescence - Zero

Question 160

Put the stage of disease in the correct order:

1. Prodromal
2. Illness
3. Convalescence
4. Incubation
5. Decline

Answer 160

Incubation
Prodromal
Illness
Decline
Convalescence

Question 161

Two organizations that monitor disease

Answer 161

CDC - National, source of epidemiological information. Publishes MMWR (morbidity, mortality)
WHO - Global, tracks and studies emerging infectious diseases

Question 162

What is a reservoir of infection?

Answer 162

A continually source of disease-causing organisms.

Question 163

Three different types of reservoirs of infection.

Answer 163

Human, animal, nonliving.

Question 164

What is a carrier of disease?

Answer 164

People that harbor pathogens and transmit them without exhibiting any signs of illness.

Question 165

What is a nosocomial infection?

Answer 165

Infections spread via healthcare settings

Question 166

What are infections spread in healthcare settings called?

Answer 166

Nosocomial infections

Question 167

Animal reservoirs of infection include what two types of animals?

Answer 167

Wild and domestic

Question 168

What are Zoonosis diseases?

Answer 168

Diseases that occur in wild and domestic animals that can be transmitted to humans

Question 169

What are diseases that occur in animals that can be transmitted to humans?

Answer 169

Zoonosis diseases

Question 170

What represents nonliving disease reservoirs?

Answer 170

Soil and water

Question 171

Three microbe portals of entry

Answer 171

Mucous membranes
Skin
Perenteral route

Question 172

Name the mucous membranes

Answer 172

Lining of respiratory tract, GI tract, genitourinary tract, conjunctiva

Question 173

What qualities of skin provides a portal of microbe entry?

Answer 173

Skin is impenetrable but some microbes find entry through sweat gland ducts, hair follicles. Hookworm larvae bore through skin; some fungi grow on keratin.

Question 174

What portals of entry of parenteral routes do microbes use for entry?

Answer 174

When deposited directly into tissues beneath skin via punctures, injections, bites, cuts, wound, surgery and splitting of skin or mucous membranes from swelling/drying.

Question 175

Punctures, injections, bites, cuts, wound, surgery and splitting of skin are examples of what type of microbe portals of entry?

Answer 175

Parenteral

Question 176

Hookworms and fungi are examples of what type of microbe portals of entry?

Answer 176

Skin

Question 177

Microbes entering the GI tract via dirty fingers are an example of what type of portal of entry?

Answer 177

Mucous membranes

Question 178

Microbes that are killed by hydrochloric acid, bile and enzymes were located in what parts of the GI tract?

Answer 178

Hydrochloric acid - stomach

Bile, enzymes - small intestine

Question 179

How do bacteria use capsules to penetrate host defenses?

Answer 179

Capsules resists phagocytosis. Opsonins may be able to bind to capsule to allow attachment of phagocytes.

Question 180

How do bacteria use cell wall components to penetrate host defenses?

Answer 180

Cell walls contain chemical components that enhance virulence.

Question 181

What are examples of cell wall components that are used to penetrate host defenses?

Answer 181

M protein of Streptococcus pyogenes resist heat/acid that assist in attachment and resists phagocytosis.

Opa protein in Neisseria gonorrhoeae grows inside human epithelial cells and leukocytes.

Mycobacterium tuberculosis, mycolic acid in cell wall makes it resistant to phagocytosis

Question 182

Give examples of enzymes used by bacteria to penetrate host defenses.

Answer 182

Extracellular enzymes (exoenzymes) can digest materials between cells and form or digest blood clots.

Question 183

Three examples of enzymes used by bacteria to penetrate host defenses.

Answer 183

Coagulase (forms blood clots)

Fibrinolysin - digests clots

Hyaluronidase - breaks down molecules that hold CT together.

Question 184

What is antigenic variation?

Answer 184

Ability of some pathogens to alter surface antigens to avoid specific antibodies.

Question 185

How do bacteria penetrate host defenses by using penetration into host cell cytoskeleton?

Answer 185

Allows microbes to avoid immune system components (invasins, listeria)

Question 186

What are examples of bacteria that penetrate host defenses by penetrating into host cell cytoskeleton?

Answer 186

Invasins - proteins that rearrange nearby host actin filaments to cause ruffle and engulf bacteria.

Listeria - intracellular parasite that polymerizes actin for propulsion and to transfer to new cells.

Question 187

What do invasins do to allow bacteria to penetrate host defenses?

Answer 187

Cause ruffle near site of attachment of membrane and allow cell to engulf bacteria.

Question 188

Three ways bacterial pathogens damage host tissues.

Answer 188

Siderophores, direct damage, toxins (endo and exotoxins)

Question 189

What are siderophores?

Answer 189

Molecules that allow bacteria to steal iron from host.

Question 190

Pathogens that multiply inside host cells can do what to host tissues?

Answer 190

Damage them

Question 191

What are three ways bacteria damage host cells?

Answer 191

Siderophores, direct damage, toxins

Question 192

Siderophores, direct damage and toxins are three ways for bacteria to do what?

Answer 192

Damage host cells

Question 193

What is a bacterial exotoxin?

Answer 193

Destroy part of host cell or inhibit metabolic function. Because are enzymes can catabolize reactions repeatedly, can cause large effects in small amounts.

Question 194

Exotoxins are enzymes. Why are they so destructive?

Answer 194

Because they can catabolize the same reaction repeatedly.

Question 195

Exotoxins are what type of molecule?

Answer 195

Enzyme

Question 196

How is immunity to exotoxins induced?

Answer 196

Through vaccinating with heat-denatured exotoxins (toxoids)

Question 197

What type of molecule are endotoxins?

Answer 197

Lipopolysaccharides (LPS) that are part of the cell wall of gram negative bacteria.

Question 198

When are endotoxins released?

Answer 198

When the cell dies and the wall undergoes lysis.

Question 199

What cells do endotoxins stimulate?

Answer 199

Macrophages that produce cytokines at toxic levels.

Question 200

All endotoxins produce the same signs and symptoms. What are they?

Answer 200

Chills, fever, weakness generalized aches.

Question 201

Why do all endotoxins cause the same symptoms?

Answer 201

Because endotoxins stimulate macrophages to produce cytokines at toxic levels.

Question 202

What do cytocidal viruses cause?

Answer 202

Cause macromolecular synthesis to stop in host cell.

Question 203

How do cytocidal viruses cause destruction of intracellular contents?

Answer 203

Cause cell’s lysosomes to release enzymes

Question 204

Five cytopathic effects of viral infections

Answer 204

Cytocidal viruses destruction of intracellular contents:
- Inclusion bodies
- Adjacent cell agglutination (form syncytium)
- Antigenic changes on cell surface
- Oncogenic viruses (chromosome
changes)
- Contact inhibition

Question 205

What are these examples of:

• Inclusion bodies
• Adjacent cell agglutination (form syncytium)
• Antigenic changes on cell surface
• Oncogenic viruses (in chromosome
  changes)
• Contact inhibition

Answer 205

Cytopathic effects of viruses

Question 206

What does cytopathic mean?

Answer 206

Producing damage to living cells

Question 207

Three organisms that commonly produce antibiotics

Answer 207

Streptomyces (from soil)
Endospore-forming bacillus
Molds (Penicillium and Cephalosporum)

Question 208

These organisms are examples of what?

Streptomyces (from soil)
Endospore-forming bacillus
Mols (Penicillium and Cephalosporium)

Answer 208

Three organisms that commonly produce antibiotics.

Question 209

Five actions of antibiotic drug action

Answer 209

Inhibition of:

Cell wall synthesis
Protein synthesis
Nucleic acid synthesis
Essential metabolite synthesis
Injuring plasma membrane

Question 210

Inhibition of:

Cell wall synthesis
Protein synthesis
Nucleic acid synthesis
Essential metabolite synthesis and 
Injuring plasma membrane
are examples of what?

Answer 210

Mechanisms of antibiotic drugs

Question 211

What type of drug is built around a beta-lactam ring?

Answer 211

Pencilliln

Question 212

Essay question:

Two methods to reduce antibiotic resistance.

Answer 212

Patients:

• Finish full course to discourage survival and proliferation of resistant microbes
• Never use leftover antibiotics to treat new illnesses
• Never use antibiotics prescribed for someone else.

Healthcare workers:

• Avoid unnecessary prescriptions
• Ensure choice and dosage are appropriate to situation
• Prescribe most specific antibiotic possible to decrease resistance in patient’s flora.

Question 213

What are three ways patients can avoid antibiotic resistant strains?

Answer 213

Patients:

• Finish full course to discourage survival and proliferation of resistant microbes
• Never use leftover antibiotics to treat new illnesses
• Never use antibiotics prescribed for someone else.

Question 214

What are three things healthcare workers can do to avoid antibiotic resistant strains?

Answer 214

Healthcare workers:

• Avoid unnecessary prescriptions
• Ensure choice and dosage are appropriate to situation
• Prescribe most specific antibiotic possible to decrease resistance in patient’s flora.

Question 215

2 mechanisms of antiviral drugs

Answer 215

Entry/fusion inhibitors
Assembly/exit inhibitors
Uncoating, genome integration and nuclei acid synthesis inhibitors
Interferons, activate antiviral host defenses

Question 216

E tests exhibit what concept?

Answer 216

Minimum inhibitory concentration (MIC)

Question 217

What is MIC (minimum inhibitory concentration) and what test is it associated with?

Answer 217

E tests, plastic strips that test antibiotic effectiveness.
MIC - lowest concentration that inhibits growth and is highest concentration where bacteria can grow directly next to plastic strip.

Question 218

What tests uses the zone of inhibition?

Answer 218

Kirby-Bauer assay (disk diffusion method)

Question 219

Four mechanisms used by bacteria to resist antibiotics

Answer 219

Blocking entry (especially gram negative)
Modify pores
inactivating enzymes
Altering drug target site
Rapid efflux (ejection)

Question 220

What are the following an example of?

Blocking entry (especially gram negative)
Modify pores
inactivating enzymes
Altering drug target site
Rapid efflux (ejection)

Answer 220

Ways in which bacteria evade antibiotics

Question 221

Two means of research for new chemotherapeutic drugs

Answer 221

Antimicrobial peptides - small protein chains in bird, amphibians, plants, mammals.
Directly damage bacteria, viruses, fungi or stimulate host immune system.
(Peptide DRGN-1 from Komono dragon displayed antimicrobial activity against Pseudomonas aeroginosa and Staphylococcus aureus and aided in health of wounds.)

Phage therapy - Use phages to kill bacteria, used in 2017 successfully. Few potential disadvantages: immune system kills it in secondary response. Don’t spread as well in host.

Question 222

The peptide DRGN-1 is an example of what?

Answer 222

New chemotherapeutic drugs called antimicrobial peptides

Question 223

What is phage therapy an example of?

Answer 223

New chemotherapeutic drugs

Question 224

T/F The skin acts as a direct barrier to microbial entry.

Answer 224

True

Question 225

What are the two layers of the mucous membranes?

Answer 225

Epithelial and underlying connective tissue.

Question 226

What do mucous membranes line?

Answer 226

GI tract, genitourinary tract, respiratory tract.

Question 227

What does the epithelial lining of the mucous membranes secrete?

Answer 227

Mucous

Question 228

What is a viscous glycoprotein produced by goblet cells?

Answer 228

Mucous

Question 229

What is mucous produced by?

Answer 229

Goblet cells

Question 230

How does mucous protect against infections?

Answer 230

Keeping membranes from drying out and traps pathogens

Question 231

What keeps membranes from drying out and traps pathogens?

Answer 231

Mucous

Question 232

What does the lacrimal apparatus do?

Answer 232

Maintains and drains away tears.

Question 233

What anatomical structure does the lacrimal apparatus protect?

Answer 233

The eyes

Question 234

How does the lacrimal apparatus protect the eyes?

Answer 234

It provides continual washing action to keep microbes from settling on the surface of the eye.

Question 235

Name the chemical components of the first line of defense

Answer 235

Sebum - unsaturated fatty acids, maintains acidic pH.
Perspiration - flush microbes, lysozyme
Lysozyme - breaks down cell walls of gram+ and some gram-negative bacteria in tears, saliva, nasal secretions, tissue fluids, urine.
Gastric juices - pH 1.2 - 3
Vaginal secretions - contain glycogen, broken down by Lactobacillus acidophilus to make acidic pH.
Cervical mucus - antibacterial properties
Urine - contains lysozyme, acid pH, urea that inhibit bacteria growth

Question 236

Sebum, perspiration, lysozyme, gastric juices, vaginal secretions and cervical mucus are examples of what?

Answer 236

Chemical components of first line of defense

Question 237

Stages of the inflammatory response

Answer 237

Vasodilation
Increased permeability
Phagocyte migration
Phagocytosis
Tissue repair

Question 238

Immediately following tissue damage, what happens to blood vessels?

Answer 238

Vessels dilate which increased blood flow to the area increases permeability.

Question 239

How does increased permeability contribute to the inflammatory response?

Answer 239

Permits substances normally retained in the blood to pass through the walls of the vessels to the injured tissue.

Question 240

Edema is the result of what inflammatory response?

Answer 240

Permeability

Question 241

Which two chemicals are responsible for vasodilation and increased permeability in injured tissue?

Answer 241

Histamine and cytokines

Question 242

What produces histamine?

Answer 242

Injured cells and the complement system

Question 243

What produces cytokines?

Answer 243

Activated fixed macrophages

Question 244

When do phagocytes generally arrive at the site of injury?

Answer 244

Within an hour

Question 245

What do phagocytes do at an injury site to initiate their response?

Answer 245

Stick to inner surface of endothelium of vessels in response to cytokines.

Question 246

How do phagocytes arrive at injured tissue?

Answer 246

Squeeze through endothelial cells of blood vessels and then begin destroying invading microorganisms.

Question 247

What does tissue repair do?

Answer 247

Replace dead or damaged cells with new ones.

Question 248

Tissue is repaired when stroma or parenchyma produce what?

Answer 248

New cells

Question 249

What is the difference between the stoma and the parenchyma cells?

Answer 249

Stroma - connective tissue

Parenchyma - functioning part of tissue

Question 250

What is a fever?

Answer 250

Systemic response of the body to injury

Question 251

What part of the brain controls the body temperature?

Answer 251

Hypothalamus

Question 252

What is one chemical that the hypothalamus responds to?

Answer 252

Cytokines

Question 253

What does the hypothalamus do in response to cytokines?

Answer 253

Increases body temperature

Question 254

How does the hypothalamus increase body temperature?

Answer 254

Sends out chemicals that constrict vessels, increase metabolism and cause shivering.

Question 255

What are the three things the hypothalamus does to increase body temperature?

Answer 255

Constricts blood vessels, increase metabolism, cause shivering.

Question 256

What is the initial phase of a fever?

Answer 256

Chill

Question 257

What happens during a chill that starts a fever?

Answer 257

Body temp is rising, skin is cold, shivering continues.

Question 258

During a chill, body temp is rising, skin is cold, shivering continues until what?

Answer 258

The temp that the hypothalamus sets is reached.

Question 259

When does the chill of a fever disappear?

Answer 259

When the temp set by the hypothalamus is reached.

Question 260

When the infecting agent is eliminated from the body, what part of the fever process stops?

Answer 260

Cytokine signaling to the hypothalamus

Question 261

When cytokines cease signaling the hypothalamus during a fever, what does the hypothalamus do?

Answer 261

Reset to 37° C

Question 262

What phase of a fever starts when the hypothalamus resets to normal body temp?

Answer 262

Crisis phase

Question 263

What is the crisis phase of a fever?

Answer 263

Skin warms, person sweats to shed heat, temp returns to normal.

Question 264

In what phase of a fever do these happen? Skin warms, person sweats to shed heat, temp returns to normal.

Answer 264

Crisis phase

Question 265

What are three benefits of a fever?

Answer 265

Lower growth of microbes
Intensifies effect of antiviral and antimicrobial agents
Speeds up body’s reactions (may help tissues heal faster)

Question 266

The following are benefits of what physiologic action?
Lower growth of microbes
Intensifies effect of antiviral and antimicrobial agents
Speeds up body’s reactions (may help tissues heal faster)

Answer 266

Fever

Question 267

Name the four parts of an antibody

Answer 267

Heavy chains
Light chains
Variable regions
Constant regions

Question 268

How are the heavy and light chains bonded in an antibody?

Answer 268

Disulfide bonds

Question 269

Two longer amino acids on the inside of an antibody monomer are?

Answer 269

Heavy chains

Question 270

Which chains of an antibody consist of the inner half of each arm and the stem region?

Answer 270

Heavy chains

Question 271

In an antibody, which chains in are connected to each other and to the light chains via disulfide bonds?

Answer 271

Heavy chains

Question 272

In an antibody, which chains make up the outer region of the arm and are connected to the heavy chain?

Answer 272

Light chains

Question 273

By what bond are light chains connected to heavy chains in an antibody?

Answer 273

Disulfide bonds

Question 274

The antigen-binding sites of an antibody are located on what chains?

Answer 274

On both the light and heavy chains

Question 275

The antigen-binding sites of an antibody are called what?

Answer 275

Variable regions

Question 276

T/F Antibodies produced by different B cells have different amino acid sequences in their variable region.

Answer 276

True

Question 277

What is a constant region on an antibody?

Answer 277

The remainder of the heavy and light chains outside of the antigen-binding sites.

Question 278

The remainder of the heavy and light chains outside of the antigen-binding sites on an antibody are called what?

Answer 278

Constant regions

Question 279

Antibodies produced by different B cells have different amino acids in their variable regions but the same what?

Answer 279

Amino acids in their constant regions.

Question 280

Which region in an amino acid carries the same amino acids when produced by different B cells?

Answer 280

Constant region

Question 281

The antibody-mediated immune response intensifies when?

Answer 281

After a second exposure to an antigen.

Question 282

Which response, the primary or secondary is slower and less intense?

Answer 282

Primary

Question 283

After initial exposure to an antigen, there are no detectable antibodies for how long?

Answer 283

4-7 days, slow rise afterwards

Question 284

Which class of antibodies are produced first in the adaptive immune response?

Answer 284

IgM

Question 285

What class of antibodies following the production of IgM in the primary response of the adaptive immune response?

Answer 285

IgG

Question 286

When does antibody production peak in the primary response?

Answer 286

10-17 days

Question 287

What’s another name for the secondary immune response?

Answer 287

The anamnestic response

Question 288

Which response, the primary or secondary is faster and more intense?

Answer 288

The secondary

Question 289

Compared to the primary response, in how many days does the secondary response begin antibody production?

Answer 289

2-7 days

Primary = 4-7 days

Question 290

Antibody production lasts many days in what part of the antibody-mediated immune response?

Answer 290

Secondary

Question 291

In which phase of antibody-mediated immune response, the primary or secondary, is the level of antibodies higher?

Answer 291

Secondary

Question 292

What cells are responsible for the difference in the immune response from the primary to secondary in the antibody-mediated immune respone?

Answer 292

B and T cells

Question 293

When stimulated by an antigen, which cells rapidly differentiate into antibody-producing cells?

Answer 293

B cells

Question 294

Which cells are also necessary for establishing memory in the antibody-mediated immune response?

Answer 294

T cells

Question 295

In what phase of the antibody-mediated immune response are memory cells present?

Answer 295

The secondary. The primary is required to generate them.

Question 296

In what part of the immune system hierarchy are vaccinations listed?

Answer 296

Adaptive-immunity: artificially acquired, active immunity

Question 297

The difference in magnitude between the primary and secondary responses in antibody-mediated immunity is why what artificially-induced process can work?

Answer 297

Vaccinations

Question 298

The objective of vaccination is to introduce an antigen to induce the primary response to create what type of cells?

Answer 298

Memory cells

Question 299

T/F The entire antigen is required to stimulate an immune response by the body.

Answer 299

False. Only antigens associated with the pathogen are required to stimulate an immune response (e.g. macromolecules proteins/carbs)

Question 300

The goal of vaccination is to introduce antigens without introducing the pathogen to stimulate which immune response?

Answer 300

Primary response

Question 301

In vaccination, an antigen is introduced without the entire pathogen to stimulate the primary response. If encountered again, it hopefully stimulates what response?

Answer 301

The secondary response