1 Introduction To Immunology

Question 1

*Q: What is the purpose of the immune system? What does it also detect? What type of process is this?

Answer 1

A: The environment is full of microorganisms - the immune system is a complex cellular and protein network that has evolved to protect the host from pathogenic microbes.

Tissue damage is also recognised by cells of the immune system-> type of HOMEOSTASIS

Question 2

Q: What does the failure of the immune system lead to? (2) When the regulation of the immune system becomes unbalanced, what can it lead to? (2)

Answer 2

A: increased susceptibility to infection and sometimes cancer.

autoimmune disease and allergy.

Question 3

Q: What is the normal function of the immune system? What enables it to do this? (2) What’s more important?

Answer 3

A: Identify and eliminate harmful microorganisms and harmful substances such as toxins:
By distinguishing self from non-self proteins
AND
By identifying danger signals (eg inflammatory signals)

you need both to trigger an immune response

Question 4

Q: What reproduces faster, virus or bacteria?

Answer 4

A: Bacteria

Question 5

*Q: Describe the evolutionary arms race between pathogen and host. (3)

Answer 5

A: The pathogen exerts selection on the host and the host exerts selection on the pathogen.

The pathogen reproduces much faster than the host and hence can evolve faster.

Therefore, the host relies on a flexible and rapid immune response.

Question 6

Q: Which human genes are involved in the immune system? (2) How have they been selected?

Answer 6

A: Our most polymorphic genes - HLA, KIR- this variation has been selected for by exposure of populations to infectious disease.

Question 7

*Q: What is the initial immune response called? Summarise the time-course of a primary immune response to a virus with a diagram. (3 lines) Explain the role of 3 cells involved.

Answer 7

A: The initial response is the innate immune response.

Early peak of type 1 interferon (interferes with the replication of the virus)
Peak in NK cells (can recognise infected cells and lyse them)
These responses help to flatten out virus replication.

To eliminate the virus you need more specific immune responses from the adaptive immune system - this takes a little more time.

Rise in Cytotoxic T Lymphocytes (recognise and lyse infected cells)
CTLs start producing antibodies against the virus

Graph: days after viral infection against magnitude of response with lines for: type 1 interferon (alpha and beta)= peak day 2, natural killer (NK) cells= peak day 4, cytotoxic T lymphocytes (CTLs)=plateaus day 7/8, antibody, (virus titer)

Question 8

*Q: What is the primary response?

Answer 8

A: the first time the host has seen this particular virus

Question 9

*Q: Describe the innate immune response. When is it present from? What does it rely on? When the infection occurs, are the components ready? What’s the range for specificity? Which type of molecular patterns does it recognise?

Answer 9

A: Present from birth

Relies on pre-formed and rapidly synthesised components

If an infection happens, the components are already there to deal with it.

Limited specificity (non antigen specific)

Only recognises molecular patterns to do with danger (non self)

Question 10

*Q: Describe the acquired/adapted immune response. When is it acquired? What does it depend on? Is it specific or non specific?

Answer 10

A: Acquired after exposure to the pathogen- Gives immunological memory

Depends on CLONAL SELECTION

Slow - takes days

Antigen Specific

Question 11

*Q: What is clonal selection? What is clonal expansion?

Answer 11

A: selection of appropriate lymphocyte to fight the pathogen

expansion of the clone of lymphocytes which recognises the particular pathogen

Question 12

Q: What are examples of anatomical barriers for innate immunity? (3)

Answer 12

A: Skin

Mucus - trapping microbes

Cilial propulsion on epithelia

Question 13

Q: What are examples of physiological barriers for innate immunity? (5)

Answer 13

A: Low pH

Secretion of lysozyme

Interferons

Anti-microbial peptides

complement

Question 14

Q: When do antibodies develop?

Answer 14

A: don’t develop until you’ve been exposed to the pathogen so it’s totally part of acquired immunity

Question 15

Q: What triggers the innate immune response? 2 types?

Examples? (2,3) Receptors? (1,3)

Answer 15

A: Pathogens have various molecular structures which aren’t present on normal cells - the immune system can take advantage of these differences and respond to these patterns.

-Pathogen Associated Molecular Patterns PAMPs (E.g. dsRNA in cytoplasm, bacterial cell wall components) ->
Pattern-recognition Receptor = TLRs (Toll-like receptors)

-Danger Associated Molecular Patterns DAMPs (E.g. Monosodium urate, high extracellular [ATP], reactive oxygen species) -> Pattern-recognition Receptors = NLRs - NOD-like receptors, RLRs - RIG-I-like receptors, AIM2

Question 16

Q: Why is high extracellular [ATP] a sign of danger?

Answer 16

A: because ATP isn’t useful outside cells.

Question 17

Q: What does the innate immune response do? (2) Main consequences? (3)

Answer 17

A: Destroys invading nucleic acids (e.g. viruses) in the cytoplasm

Activates interleukins which, in turn, activate inflammatory pathways

Evokes type 1 interferons - bind to receptors on nearby cells and induces an antiviral state.

Main consequences: Suppresses pathogen replication, buys time, kick starts the acquired immune response

Question 18

Q: What is the acute phase inflammatory response? What does it involve? (2) What triggers 1?

Answer 18

A: innate response to tissue damage

Fever - indicative of acute phase inflammatory response (This is triggered by activation of interleukin-1)

Followed by production of acute phase proteins

Question 19

Q: What are acute phase proteins? What are 3 acute phase proteins? Where are they produced?

Answer 19

A: soluble pattern recognition receptors

C-reactive protein, Serum amyloid protein, Mannan-binding lectin

liver

Question 20

Q: What do the acute phase proteins do? Describe each one. What happens following binding? (2)

Answer 20

A: C-reactive protein and serum amyloid protein - bind to molecules found on the cell wall of some bacteria and fungi.

Mannan-binding lectin - binds to mannose sugar molecules which are not often found in mammalian cells.

Once these proteins are bound, phagocytes have receptors which can recognise these proteins and proceed to ingest the infectious agent.

binding can also trigger responses - it helps activate the complement system

Question 21

Q: Describe cytokines. (2) What causes a cell to produce them?

Answer 21

A: Large family of soluble molecules - they are proteins that transmit information between cells

Some sort of stimulus

Question 22

Q: How do cytokines act? (4) Important for?

Answer 22

A: diffuse to nearby cells, bind to specific receptors and send a signal to the cell to alter the pathogen gene expression. Proteins will either be upregulated or downregulated leading to the biological effect

proliferation of lymphocytes

Question 23

Q: 3 examples of granular leukocytes?

Answer 23

A: Natural Killer (NK) Cells, Macrophages, Granulocytes (3 types)

Question 24

Q: What are natural killer (NK) cells? What do they do?

Answer 24

A: Type of cytotoxic lymphocyte

Identify and kill virus-infected cells and tumour cells

Question 25

Q: What are macrophages? What do they do?

Answer 25

A: Mononuclear phagocytes, Release cytokines as signals of danger

Question 26

Q: What are the 3 types of granulocytes? What do they do? Phagocytic? Which is most common?

Answer 26

A: Basophils- Least abundant type of granulocyte, Not phagocytic, Release histamines,

Neutrophils- Also called polymorphonuclear neutrophils (PMN), Nucleus is multi-lobed, Phagocytic ** most common

Eosinophils- Bi-lobed nucleus, Important in immune response to parasites,

Question 27

*Q: Define antigen.

Answer 27

A: a molecule that reacts with antibodies or T cells

Question 28

*Q: Define antibody. Bind to?

Answer 28

A: an immunoglobulin molecule in the blood and body fluids which binds specifically to an antigen

Question 29

*Q: Define an immunogen.

Answer 29

A: antigens that initiate an immune response

Question 30

Q: What are the 5 classes of immunoglobulins? Which makes up the most in serum Ig?

Answer 30

A: all are a class of proteins

IgG* 75%

IgM 10%

IgA

IgE

IgD v low

Question 31

Q: What are IgG? Length of half life?

Which response are they part of?

Answer 31

A: Monomeric antibody
Long half life in serum
Crosses the placenta from mother to foetus to give the new born immunity against infection.
Part of secondary immune response

Question 32

Q: What are IgM? What shape are they? How many binding sites does it have? What are they good at? What response are they important in?

Answer 32

A: Pentamer - star shaped
Multivalent antibody - 10 binding sites
Good at agglutinating (clumping together) pathogens
Important in primary immune response

Question 33

Q: What are IgA? What are they found in? What do they contain- what does this do?

Answer 33

A: Dimer Found in body secretions (mucosal surfaces)
Contains secretory .component - protects it from degradation on mucosal surfaces which usually have proteases present (hostile environment)

Question 34

Q: What are IgE involved in? How do they act?

Answer 34

A: Involved in allergic responses

Binds to basophils and mast cells and triggers the release of histamines.

Question 35

Q: What are IgD involved in?

Answer 35

A: Predominantly involved in membrane bound form on B lymphocytes in signalling

Question 36

Q: How does an antibody recognise an antigen?

Answer 36

A: that antibody’s binding site makes a perfect fit with a region (EPITOPE) on the antigen.

Question 37

Q: What is the epitope of the antigen?

Answer 37

A: the part of the antigen that is bound by the antibody

Question 38

Q: What are the 4 mechanisms that an antibody kills a virus?

Answer 38

A: Binds to virus - prevents attachment to cell

Opsonisation - virus is coated in antibody so it can be more easily phagocytosed.

Complement - mediated lysis of membrane bound virus

Antibody-Dependent Cell-Mediated Cytotoxicity (ADCC) - mediated by NK-like cells - if the cell is infected, there will be viral proteins in the membrane - the cell becomes coated with antibody - NK cells have receptors which can recognise these antibodies and lyse the infected cells.

Question 39

Q: What are the cells of the acquired immune system? 2 types?

Answer 39

A: Lymphocytes - agranular leukocytes (majority are in the lymph)

T-cell = Thymus derived 
B-cell = Bone marrow derived 

There are many subtypes of these molecules which are distinguished by CD markers

Question 40

Q: What are the 3 types of antigen-specific lymphocytes?

Answer 40

A: B cell (humoural)

Helper T-cell

Cytotoxic T-cell (CTL)

Question 41

*Q: What is active immunity? (2)

Answer 41

A: the type of immunity that is actively developed in an individual in response to a pathogen or vaccination - it is an acquired response to the antigen

Question 42

*Q: What is passive immunity? Give an example.

Answer 42

A: the transfer of pre-formed antibodies into a person to give them defence against a pathogen
IgG from mother to baby gives the baby passive immunity

Question 43

*Q: What is the difference between the primary and secondary immune response? (2)

Answer 43

A: Secondary = subsequent exposure to the same pathogen

Secondary Response - BIGGER response + FASTER

Question 44

Q: How do the B cell and T cell antigen receptors differ?

Answer 44

A: B-cell antigen receptor is a membrane bound antibody- These bind INTACT antigens

There are 2 protein chains (a and b) which together make the T cell antigen receptor (TCR) - These only bind DIGESTED (PROCESSED) antigen fragments

Question 45

*Q: How does the TCR recognise an antigen?

Answer 45

A: TCR recognises a complex of: Antigen Peptide + HLA (MHC) Molecule

Question 46

*Q: What is the MHC? Role? AKA?

Answer 46

A: Major Histocompatibility Complex - these molecules present processed antigens to T lymphocytes

The MHC is humans is also known as the HLA (Human Leukocyte Antigen)

Question 47

Q: How is clonal diversity generated in humans?

Answer 47

A: During B and T cell development - RANDOM GENETIC RECOMBINATIONS take place within each cell among multiple copies of:

B cells - Immunoglobulin gene segments
T cells - TCR gene segments

-> end up with a very large repertoire of different receptors which can respond to a large variety of antigens

Question 48

Q: Describe the clonal nature of the adaptive immune response?

Answer 48

A: Each lymphocyte carries a single, unique antigen receptor

There are millions of lymphocytes, hence, millions of different antigen receptors in the body.

Lymphocytes which have a binding site that is complementary to an antigen will proliferate and survive.

The majority of lymphocyte clones die out.

Question 49

Q: What are naïve lymphocytes?

Answer 49

A: lymphocytes which have never come into contact with their antigen before

Question 50

Q: What causes selective expansion of a clone of a T or B cell?

Answer 50

A: antigen will bind to the surface receptors on the B cell (Ig) or T cell (TCR)

Question 51

Q: What happens to lymphocytes that have proliferated during the primary immune response?

Answer 51

A: Most will DIE after fulfilling their function

Some lymphocytes survive as memory cells

Question 52

Q: How does the immune system clear the pathogen during the primary immune response?

Answer 52

A: Cytotoxic T Lymphocytes (CTLs) kill infected cells by injecting lethal enzymes

Antibodies bind to the pathogen and direct phagocytes to come and ingest them

Question 53

Q: Summarise using a flow diagram the primary immune response in terms of lymphocytes.

Answer 53

A: antigen
|
\ /
Naïve lymphocytes (polyclonal) ———–> activation -> clonal expansion -> effector lymphocytes

Question 54

Q: What is the role of a APC? How do they form?

Answer 54

A: transport the antigens from the tissues into secondary lymphoid organs

Antigens meet T cells in secondary lymphoid organs

Antigen-presenting cells capture, process and present antigens to T lymphocytes

APCs are good at activating T cell responses- Immune response

Question 55

*Q: How is the lymphatic system organised?

Answer 55

A: Lymphatic Vessels: Venules, Veins, Ducts

Lymphatic Tissues: Nodules, Nodes, Tonsils, Peyer’s Patches

Lymphatic Organ: Spleen, Thymus

Question 56

*Q: What does the lymphatic system do to aid immune responses?

Answer 56

A: lymphatic system drains body fluid from between tissue cells via lymph nodes through which lymphocytes recirculate-> T lymphocytes have the chance to interact with antigens

Question 57

Q: Are innate or acquired responses faster?

Answer 57

A: innate

Question 58

Q: Draw a diagram showing the cells and humoral factors involved in innate and acquired immunity.

Answer 58

A: cells:
innate- neutrophils, NK cells
both- macrophages, monocytes, dendritic cells, mast cells
adaptive- macrophages

soluble factors:
innate- antimicrobial peptides
both- complement, cytokines
adaptive- antibodies

Question 59

*Q: Define T lymphocyte. (where is it produced and what does it participate in). Where do most circulate?

Answer 59

A: a lymphocyte of a type produced or processed by the thymus gland and actively participating in the immune response

98% in lymph

Question 60

*Q: Define B lymphocyte. (where is it not produced and what is it responsible for).

Answer 60

A: a lymphocyte not processed by the thymus gland, and responsible for producing antibodies

Question 61

*Q: Describe lymphocyte cells. (2)

Answer 61

A: mononuclear, part of leukocyte/WBC lineage

Question 62

*Q: What are the surface markers found on T lymphocytes?

Answer 62

A: CD3 (all cells), CD4 (subset), CD8 (different subset)

Question 63

*Q: What are the surface markers found on B lymphocytes?

Answer 63

A: CD19, CD20

Question 64

Q: What are APC also called?

Answer 64

A: dendritic cells