Functions of Immunoglobulins (humoral immunity II)

Question 1

Antibody function is related to _______!

Answer 1

Structure

*structural differences between the antibody isotypes allow them to confer different functions.

Question 2

What factors are influenced by the sequence difference between immunoglobulin heavy chains?

Answer 2

1) The number of constant domains

2) Number and location of oligosaccharide groups

3) Number and location of interchain disulphide bonds

4) Length of the hinge region

*these differences can confer distinct functions for each immunoglobulin isotype.

Question 3

1) What is a unique feature of IgM and IgA?

2) What role does the J chain play, and how does it impact IgM and IgA?

Answer 3

1) IgM and IgA contain a tailpiece of 18 amino acids that contains a CYSTEINE residue for POLYMERIZATION.

2) An additional polypeptide called the J chain promotes POLYMERIZATION by linking the cysteine residues together. IgM becomes a pentamer and IgA becomes a dimer.

Question 4

1) What advantages does the pentameric structure of IgM provide?

2) What is the function of the dimeric IgA?

Answer 4

1) IgM are generally low affinity BUT they can form PENTAMERS that have 10 antigen-binding sites. This confers overall HIGHER AVIDITY when binding to multivalent antigens.

2) IgA can form DIMERS that function mainly in epithelial surfaces of intestinal and respiratory tracts—and functions largely as a neutralizing antibody (mucous secretions).

Question 5

Which one of the statements is true?

1) Due to the large pentameric size, IgM is generally found in the intercellular spaces within tissues.

2) The J chain segment should not be confused with the J gene segment in immunoglobulins.

Answer 5

2!

For 1) Due to the large pentameric size, IgM is generally found in the BLOODSTEAM (or to a lesser extent in the lymph) RATHER THAN INTERCELLULAR spaces within tissues.

Question 6

1) Which immunoglobulin isotype is predominant in secretions and epithelium lining?

2) Which immunoglobulin isotypes are smaller than IgM? What does this allow for?

3) What does IgE bind to?

Answer 6

1) IgA is a major isotype in secretions and epithelium lining.

2) IgG, IgA, and IgE are smaller and can DIFFUSE OUT OF BLOOD AND INTO TISSUES.

3) IgE binds avidly to receptors on MAST cells that are found beneath the skin/mucosa/connective tissues.

Question 7

Maternal ___ is transported across the placenta directly into the bloodstream of the fetus. Babies at birth already have ___ levels of this isotype, with the ____ range of antigen specificity as the mother.

___ antibodies are secreted in breast milk and are transported across the ____ _______ of newborns where they protect against infectious agents.

Answer 7

IgG; high; same

IgA; gut epithelium

Question 8

Newborns have high levels of circulating IgG antibodies derived from the mother during gestation, enabling the baby to benefit the broad immune experience of the mother.

What happens to this passive protection as the baby ages?

Answer 8

The passive protection falls at about 6 months as the baby’s own immune response takes over.

Total antibody concentrations are low from 6 months to 1 year after birth (increased susceptibility to disease).

Question 9

Signals from the bound antigen to the BCR and from the helper T cell induce the B cell to proliferate and differentiate into plasma cells that secrete antibodies.

What are the three mechanisms used by the antibodies to protect the host?

Answer 9

1) Neutralization
2) Opsonization (& phagocytosis)
3) Complement activation

Question 10

Fill in the blanks regarding the different antibody isotypes:

1) ____ are present on mature B cells with an elusive role in B cell activation.

2) _____ and ____ are key for the neturalization function.

3) ___ important for complement activation.

4) ___ critical for mast cell degranulation (allergy).

Answer 10

1) IgD

2) IgG & IgA

3) IgM

4) IgE

Question 11

Why do we need neutralizing antibodies?

Answer 11

Pathogens can cause damage to host by producing toxins or by directly infecting cells.

Antibodies against pathogens and toxins can PREVENT BINDING of these agents to HOST cellular receptors.

These types of antibodies inhibit or neutralize the infectivity of microbes and toxins and are referred to as “neutralizing antibodies.”

*IgG and IgA possess neutralization functions.

Question 12

Briefly describe the mechanism of action of toxins and the defensive role of antibodies against them.

Answer 12

Man bacteria (and some insects and snakes) cause their damaging effects by producing toxic proteins, which are often composed of several distinct moieties.

Often, one part of the toxin binds to a cellular receptor which enables the molecule to be internalized. Another part of the toxin enters the cytoplasm and poisons cells.

Antibodies INHIBIT toxin BINDING and can prevent (neutralize) the toxic effects.

Question 13

Apart from toxins, what other entities can antibodies neutralize?

Answer 13

Antibodies can neutralize various pathogens, including viruses and bacteria, by binding to them and preventing their harmful effects.

VIRUSES must bind to the host cell’s surface receptor for replication (to get genes inside the cell). Antibodies disrupt this process by binding to viral surface proteins, preventing the virus from attaching or entering the target cell.

BACTERIAL infections require an interaction between the bacteria and cell-surface receptors on the target cell. Antibodies inhibit the adhesion of bacteria to cell surfaces, blocking colonization/uptake.

Question 14

What is the mucosal immune system composed of?

The mucosal immune system is continuously exposed to antigens entering from the environment. Which isotype plays an important role in neutralizing these antigens?

Answer 14

The mucosal immune system compromises the internal body surfaces that are linked by a MUCUS-SECRETING EPITHELIUM.

It also includes the EXOCRINE GLANDS associated with these organs such as lachrymal, salivary and mammary glands.

IgA plays an important role as a neutralizing antibody in the mucosal tissues.

Question 15

What is the lamina propria?

Answer 15

It is a thin layer of connective tissue that lies beneath the epithelium.

*in mucosal tissues of the human body, the arrangement follows the order of the mucus layer, epithelial cells and the lamina propria.

Question 16

What are the different ways IgA protects the mucosal tissues?

Answer 16

1. Secreted IgA on the GUT SURFACE can BIND and neutralize pathogens and toxins.
2. IgA can bind and neutralize antigens internalized in ENDOSOMES.
3. IgA can EXPORT toxins and pathogens FROM the LAMINA PROPRIA while being secreted.
4. IgA can bind to specific molecules on M cells, allowing for transport of the antigens to the lamina propria to specific dendritic cells that lie beneath the epithelial surface, controlling the immune response.

Question 17

(T/F) The mucosal layer allows for dimeric IgA to adhere to it. The antibody can trap any pathogens that may enter the layer.

Answer 17

True!

*method 1

Question 18

Match the steps of IgA secretion at the lamina propria and its binding to the gut surface.

1) Step 1
2) Step 2
3) Step 3

A) The bound complex undergoes transcytosis in which it is transported in a vesicle (endocytosis) across the cell to the apical surface.

B) The poly-Ig receptor is cleaved to leave the extracellular IgA-binding component bound to the IgA molecule (secretory component). Carbs on the secretory component bind to glycoproteins in mucus and hold the IgA at the epithelial surface.

C) The IgA dimer binds the poly-Ig receptor on the basolateral surface of the epithelial cell.

Answer 18

Step 1: The IgA dimer binds the poly-Ig receptor on the basolateral surface of the epithelial cell.

Step 2: The bound complex undergoes transcytosis in which it is transported in a vesicle (endocytosis) across the cell to the apical surface.

Step 3: The poly-Ig receptor is cleaved to leave the extracellular IgA-binding component bound to the IgA molecule (secretory component). Carbs on the secretory component bind to glycoproteins in mucus and hold the IgA at the epithelial surface.

Question 19

What is antibody-mediated opsonization?

Answer 19

Opsonization is the process of attaching opsonins, such as antibodies, to microbial surfaces to target pathogens for phagocytosis.

Phagocytes express a variety of cell surface receptors for the Fc portion of antibodies.

Signals from the Fc receptors promote phagocytosis of the opsonized microbe and activate the phagocytes to destroy the internalized pathogen.

Question 20

Which isotype possesses opsonization function?

Answer 20

Opsonization is largely mediated by IgG antibodies.

Question 21

1) What is the Fc portion of the immunoglobulin?

2) Which cells express Fc receptors?

3) What are the roles of these receptors?

Answer 21

1) The Fc portion of the immunoglobulin refers to the CARBOXY-TERMINAL regions of the two heavy chains.

2) Macrophages and neutrophils express Fc receptors.

3) Fc receptors recognize the Fc portion of immunoglobulins and regulate phagocytosis of opsonin-coated particles.

Question 22

Many Fc receptors facilitate immune responses.

However, the ______ receptor is the major Fc receptor for phagocytosis of opsonized pathogens.

Answer 22

FcγRI

*it binds to opsonized pathogen

Question 23

Why do we not want phagocyte activation to occur all the time?

Answer 23

Phagocyte activation can initiate an inflammatory response and cause tissue damage. So we want to ensure that phagocytes are activated only in response to pathogen.

Question 24

How do Fc receptors on phagocytes distinguish between free antibodies or antibodies bound to pathogen?

Answer 24

Bound antibody is distinguishable from free antibody by its STATE OF AGGREGATION (state of clustering of Fc receptors)

Free antibodies bind Fc receptors with LOW affinity and cannot cross-link Fc receptors on macrophages.

Antigen-bound antibody binds Fc receptors with HIGH avidity and induces cross-linking of Fc receptors, sending signals to trigger cell activation and phagocytes.

Question 25

Briefly describe the process of antibody-mediated opsonization and phagocytosis.

Answer 25

1) Opsonization of microbe by IgG
2) Binding of opsonized microbes to phagocytes Fc receptors (FcγRI)
3) Fc receptors signals activate phagocytes
4) Phagocytosis of microbe
5) Killing of ingested microbe

Question 26

Some particles are too large for phagocytes to ingest. What happens in these cases?

Answer 26

Large parasites can be attacked by EOSINOPHILS (non-phagocytic cells).

Eosinophils can bind to the surface of the IgE-coated parasites via the FcεRI receptor which triggers release of granule contents that are toxic to the large parasite.

Question 27

NK cells are large granular lymphoid cells that have _____ on their surfaces.

When NK cells encounter cells coated with ____, they rapidly kill the target cells.

Answer 27

FcγRIII

IgG

*FcγRIII recognizes IgG1 and IgG3 subclasses.

Question 28

Briefly describe how IgG causes antibody-dependent cell-mediated cytotoxicity (ADCC).

Answer 28

1) Antibody binds antigens on the surface of target cells.

2) Fc receptors on NK cells recognize bound antibody.

3) Cross-linking of Fc receptors signals the Nk cell to kill the target cell.

4) The target cell dies by apoptosis. The cytoplasmic granules of NK contain perforin and granzymes - which mediates killing similarly to cytotoxic T cells.

Question 29

1) What are mast cells?

2) Where are they largely found?

Answer 29

1) Mast cells are large cells containing cytoplasmic granules that contain a mixture of chemical mediators such as histamine that act rapidly to make local blood vessels more permeable.

2) They are largely found in CONNECTIVE TISSUES just beneath epithelial surfaces.

Question 30

Mast cells bind to ___ through the very high affinity _____ receptor. Antigen crosslinking of bound antibodies triggers rapid _______, releasing _______ mediators into the surrounding tissue.

These mediators then recruit ____ and _____ required for host defence to sites of infection.

Answer 30

IgE; FcεRI; de-granulation; inflammatory

cells; proteins

Question 31

(T/F) IgM and IgG can activate the alternative complement system.

Answer 31

False!

They activate the CLASSICAL pathway.

Question 32

Why is IgM efficient at activating complement?

Answer 32

One reason is its PENTAMERIC structure.

In plasma, the pentameric IgM has a PLANAR conformation that does not bind C1q (the first complement protein in the classical pathway).

Binding to the pathogen surface deforms the IgM pentamer so that it looks like a STAPLE. This distortion exposes binding sites for the C1q heads.

Question 33

The binding of C1q to a ______ IgM molecule or _____ or more IgG molecules leads to the activation of the downstream events of the classical complement cascade.

Answer 33

pentameric; two

*need at least two IgG molecules for C1q to bind.