Lecture 25 - Complement Activation 1

Question 1

Where is complement located?

Answer 1

• In the serum

* In the inactive form (pro-enzyme)

Question 2

In general, how is C’ activated?

Answer 2

Proteolysis

Question 3

What are the generalised effector functions of C’?

Answer 3

1. Lysis of cells (MAC formation)
2. Opsonisation (Enhanced phagocytosis)
3. Inflammation (recruitment of lymphocytes)
4. B cell activation

Question 4

Which cells can by lysed by C’?

Answer 4

• Bacteria
• Infected cells
• Transplanted cells
etc.

Question 5

How many different C’ proteins are there?

Answer 5

More than 30

Question 6

Where are C’ proteins produced?

Answer 6

• Hepatocytes
• Monocytes & Macrophages
• Some epithelial cells

Question 7

Is C’ a major component of the blood?

Answer 7

Yes

They make up 10% of the ‘globulin’ fraction (i.e. the protein component) of the blood

Question 8

Describe the generalised process of the complement cascade

Answer 8

→ Trigger
S → T

Active T converts:
U → V

Active V converts:
W → X

Active X converts:
Y → Z

Question 9

What is the nomenclature of C’ protein?

Answer 9

C1, C2 etc.

Products of a cleaved protein:
 • 'a': smaller fragment
 • 'b': larger fragment
e.g. 
C3 → C3a + C3b

Question 10

Physically, where does activation of the C’ system occur?

Answer 10

On the surface of cells (pathogens or others)

Question 11

How are host cells protected from C’?

Answer 11

Cell surface proteins
• Present on healthy host cells
• Absent on microbes

These proteins regulate C’ activation to minimise host damage

Question 12

Soluble C’ components are often…

Answer 12

Inactive

Question 13

Describe the mechanisms of C’ activation

Answer 13

1. Classical pathway
   • Ag-Ab complexes
   • IgM & IgG
2. Alternative pathway
   • Ab independent
   • C’ directly binds to bacterial surfaces
3. Lectin pathway
   • Mannan binding lectin (MBL)

Question 14

Which pathway of C’ activation is evolutionarily older?

Answer 14

Alternative pathway

Question 15

What are the steps in C’ activation?

Answer 15

1. Initiation
   • 3 different pathways of activation
   • Formation of a C3 convertase complex
2. Early steps
   • Cleavage of C3
   • Formation of the C5 a convertase complex

3. Late steps
 • Cleavage of C5
 • Effector mechanisms:
- lysis
- MAC formation
- inflammation

Question 16

What is the outcome of initiation of C’ activation?

Answer 16

Formation of C3 convertase

The different pathways create different convertases, but they are homologous

Question 17

What are the common steps in C’ activation?

Answer 17

These steps are the same, regardless of which pathways has been initiated

1. C3 cleavage
   C3 → C3a + C3b
2. C5 cleavage
   C5 → C5a + C5b

Question 18

What type of molecule is C3a?

Describe its function

Answer 18

Inflammatory mediator

Recruitment of inflammatory cells

Question 19

What type of molecule is C3b?

Describe its function

Answer 19

Opsonin

• Binds to the microbe surface
• Phagocytes bind C’ receptors, and engulf the pathogen

Question 20

What are the different mechanisms of C3 cleavage?

Answer 20

Specific molecules act as convertases

1. Classical / lectin pathway
   • C4bC2a
2. Alternative pathway
   • C3bBb

Question 21

Describe the different mechanisms of C5 cleavage

Answer 21

The C3 convertases join with C3b to form the C5 convertases

1. Classical / lectin pathway
   • C4b2aC3b
2. Alternative pathway
   • C3bBbC3b

Question 22

Describe the following steps of the alternative pathway:
• Initiation
• Early steps
• Late steps

Answer 22

“Tickover”

– Initiation –

1. Natural low-level hydrolysis of C3
   C3 → C3a + C3b

If there are microbes present:
2. C3b binds to microbial surfaces

– Early steps –

3. ‘B’ binds C3b on microbial surface
4. B cleaved by Factor D
   B → Bb + Ba
5. C3b + Bb come together to form a C3 convertase
6. Properdin binds and stabilises C3bBb (the C3 convertase) on the microbial surface
7. C3 convertase cleaves C3:
   C3 → C3a + C3b

– Late steps –

8. C3b binds C3 convertase to form C5 convertase
   C3bBb + C3b → C3bBbC3b
9. Convertase cleaves C5
   C5 → C5a + C5b

Question 23

How does C3b bind to microbes?

Answer 23

C3b: Thioester bonds

Microbial surface: amino and hydroxyl groups

Question 24

What cleaves ‘B’?

Answer 24

Factor D

Question 25

What is the structure of the C3 convertase in the following pathways:
• Classical
• Lectin
• Alternative

Answer 25

Classical
• C4bC2a

Lectin
• C4bC2a

Alternative:
• C3bBb

Question 26

What is the structure of the C5 convertase in the following pathways:
• Classical
• Lectin
• Alternative

Answer 26

Classical:
• C4bC2aC3b

Lectin
• C4bC2aC3b

Alternative:
• C3bBbC3b

Question 27

What is the function of Factor D?

Answer 27

Cleaves B:
B → Bb + Ba

When B is bound to C3b

Question 28

What is the function of Factor B?

Answer 28

Inactive form

Factor B binds to C3b on the microbe surface in the alternative pathway

Factor B is then cleaved by Factor D:
B → Bb + Ba

Question 29

What is Factor Bb?

Answer 29

Active form of Factor B

Formed by cleavage of Factor B by Factor D

Forms part of the C3 convertase

Question 30

What is the function of Properdin?

Answer 30

Binds and stabilises C3 convertase on the microbial surface in the alternate pathway

→ stabilisation of the C3 convertase

Question 31

How is the alternative pathway regulated?

Answer 31

1. Factor I & Factor H
   • C3b is rapidly degraded by these factors
2. Complement regulatory proteins
   • When C3b binds healthy host cells it is rapidly inactivated by these proteins

Question 32

What degrades C3b?

Answer 32

Factor I and Factor H

Question 33

What is the “Pathogen sensing complex”?

Answer 33

C1 complex

Involved in initiation of the Classical pathway

Question 34

Describe how C1q is activated

Answer 34

Activated by binding:
1. IgM or IgG 
 • binds heavy domain
 • Ig has bound pathogens already
 • Must bind at least two Ig heavy chains

2. CRP
   • CRP binds bacterial surfaces at phosphocholine residues

Question 35

Describe the classical pathway
• Initiation
• Early steps
• Late steps

Answer 35

– Initiation –

1. C1q binds CRP or Ig on bacterial surface
2. C1r cleaves C1s to form an active serene protease (C1s)

– Early steps –

3. C4 binds Ig-bound C1q
4. Activated C1s cleaves C4
   C4 → C4b + C4a
5. C4b binds covalently to the surface of pathogen
6. C4b binds C2
7. C2 cleaved by C1s
   C2 → C2a + C2b
8. C2a associates with C4a to form C3 convertase:
   C4bC2a
9. Cleavage of C3 by C4bC2a
   C3 → C3a + C3b

– Late steps –

10. C3b that has just been cleaved binds to C4bC2a to form C5 convertase:
    C4bC2aC3b
11. Cleavage of C5 by C4bC2aC3b
    C5 → C5a + C5b

Question 36

Which Ig best activates C1q?

Answer 36

In order of efficacy:
IgM
IgG1, IgG3

Question 37

What is the structure of the C1 complex?

Answer 37

Composed of:
 • C1q (6 strands)
- recognises foreign stuff
- collagen-like tails
- globular heads

• C1r(2)
• C1s(2)
- serine proteases involved in activation of the complex

Question 38

What are the Ig requirements for C1 complex activation?

Answer 38

• C1 complex must bind at least two Igs

* Ig must be bound to the bacterial surface

Question 39

Why must Ig be bound to the surface of the pathogen to activate the C1 complex?

Answer 39

Soluble IgM (pentamer):
 • Inaccessible Fc

Soluble IgG:
• Fc portions not adjacent

Antigen bound IgM:
• There was a conformational change
• Fc exposed

Antigen-bound IgG:
• Fc portions adjacent

Question 40

What allows C1 to bind IgM when bound to the surface?

Answer 40

Binding stimulates a conformational change in IgM

Fc portion is now exposed

Question 41

Which part of the C1 complex actually binds Ig?

Answer 41

C1q globular heads

Question 42

What is active C1s?

How does it become activated?

Answer 42

Active serine protease

Activation:

1. Binding of C1q to Ig
2. C1r cleaves C1s
3. C1s now active

Question 43

What are the homologous comounds for:
 • Factor B
 • Factor Bb
 • C4bC2a
 • C4bC2aC3b

Answer 43

Factor B = C2

Factor Bb = C2a

C3 convertase:
C3bBb = C4bC2a

C5 convertase:
C3bBbC3b = C4bC2aC3b

Question 44

What type of molecule is C5a?

Describe its function

Answer 44

Powerful inflammatory mediator

Recruits inflammatory cells

Question 45

Describe the lectin pathway

Answer 45

– Initiation –

1. MBL binds sugars on the surface of microbes with lectin domains
2. MASP associated with MBL cleaves C4
   C4 → C4a + C4b
3. C4b binds covalently to surface of pathogen
4. C2 binds C4b and is cleaved:
   C2 → C2a + C2b
5. C2a associates with C4b to form the C3 convertase
6. C3 cleaved by C4bC2a
   C3 → C3a + C3b

– Late steps –

7. C3b associates with C4bC2a to form C5 convertase:
   C4bC2aC3b
8. Cleavage of C5 by C4bC2aC3b
   C5 → C5a + C5b

Question 46

Where is MBL normally found?

What is it similar to?

Answer 46

In the serum

Similar to C1q

Question 47

What is MASP?

Answer 47

MBL-associated serine protease

Question 48

What is the homologous factor to C1s in the lectin pathway?

Answer 48

MASP (MBL-associated serine protease)

Question 49

Describe how C3b can feedback positively on itself

Answer 49

C3b produced by any of the three pathways at the cleavage stage can interact with Factors B and D

→ more C3b produced through the alternative pathway

Question 50

Is C’ heat stable or heat labile?

Answer 50

Heat labile

Only active at 37°

Question 51

How is amplification achieved in the C’ cascade?

Answer 51

A signal molecule will activate many of the next molecule in the cascade, and so on and so forth

Question 52

Which C’ pathway is formally an effector mechanism of humoral immunity?

Answer 52

Classical pathway

Because it involves Ag-Ab immune complexes

Question 53

Describe the structure of C1q

Answer 53

6 collagen-like tails

6 globular heads
• bind Fc on Ab that have bound a pathogen

Question 54

What can C1q bind?

Answer 54

• Ab that have bound pathogens

* CRP

Question 55

How does CRP bind pathogens?

Answer 55

CRP binds phosphocholine residues on bacterial surfaces

Question 56

What is the structure of MBL?

Answer 56

(Mannose binding lectin)

MASP1 and 2
• Serine proteases

Collagen like domain

Lectin domains:
• Globular heads

Question 57

Where is MBL found normally?

Answer 57

In the serum

Question 58

What does MBL bind?

Which bit of MBL binds?

Answer 58

Sugars found on the surface of microbial cells (and not human cells)

The Lectin domains (globular heads) bind the sugars

Question 59

Compare the molecule that performs cleavage of C4 in the following pathways:
• Classical
• Lectin pathway

Answer 59

Classical: C1s

Lectin: MASP

Question 60

Is there any cross over between the Classical/lectin pathways and the Alternative pathway?

Answer 60

Yes

C3b produced through the Classical / Lectin pathways can go back and feed the Alternative pathway

Question 61

What happens to the cleavage products of C5?

Answer 61

C5b: Formation of MAC

C5a: Inflammation

Question 62

Describe the process of formation of the MAC

Answer 62

1. Cell bound C5b from common cleavage step
2. C5b binds C6 and C7
3. C5bC6C7 inserts into the cell membrane
4. C8 binds, one of its subunit inserts into membrane

→ transient lysis of cells

5. C5bC6C7C8 causes polymerisation of C9

→ formation of MAC

Question 63

What are the physical properties of C6 and C7?

Answer 63

Hydrophobic

Question 64

What is the structure of C8?

Answer 64

Trimer

Question 65

How big is the pore of the MAC?

Answer 65

100 Angstroms

Made up of poly-C9

Question 66

How does the MAC bring about cell death?

Answer 66

• Osmotic rupture

* Triggers apoptosis

Question 67

What is the function of C5bC6C7C8?

Answer 67

Transiently able to lyse cells (to some degree)

More importantly, leads to the polymerisation of C9 to form the MAC

Question 68

Discuss the role of CRP in the C’ cascade

Answer 68

CRP bound to microbial surfaces can trigger the classical pathway (like IgM and IgG)

1. CRP bound to phosphocholine residues on microbial surfaces
2. C1q binds CRP and is activated
3. C1(r2s2) activated to become active serine protease
4. C4 binds C1q bound to CRP
5. C1s cleaves C4
6. C4b binds covalently to microbe surface
7. C2 binds C4b
8. C2 cleaved by C1s to form C2a
   – C3 convertase formed –
9. C4bC2a cleaves C3 to form C3a and C3b
10. C3b binds C4bC2a to form C5 convertase
11. C5 cleaved to form C5a and C5b
    → effector functions

Question 69

Describe how the following bind to the surface of the pathogen:
 • MBL
 • C3b
 • C4b
 • CRP

Answer 69

MBL:
• Lectin binding domains bind to mannose (sugars) on the pathogen surface

C3b:
• Thioester on C3b binds hydroxyl and amino groups on pathogen surface

C4b:
• Binds covalently to pathogen surface

CRP:
• Phosphocholine on pathogen