Difference between revisions of "Complement"

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[[Image:Complement Classical Pathway.png|thumb|right|250px|'''Classical pathway in detail''']]
 
[[Image:Complement Classical Pathway.png|thumb|right|250px|'''Classical pathway in detail''']]
 
<p>This pathway of the complement system is triggered by the binding of antibody to antigen. The only subclasses that can activate complement this way are the
 
<p>This pathway of the complement system is triggered by the binding of antibody to antigen. The only subclasses that can activate complement this way are the
[[IgM]] and certain [[IgG]]. The first step of complement activation is the binding of C1 to two Fc regions of the antibodies (IgM is such a strong activator of complement as it contains '''five''' Fc regions, while IgG contains '''one'''). C1 is actually a complex of C1q, C1r and C1s. C1q looks like a bunch of 6 tulips with each "flower" consisting of a globular protein head and a collagen "stem". C1q is required to trigger the cascade because two of it is the globular heads which binds the two Fc regions. C1r and C1s then become activated when the C1q heads are antibody-bound. When they are activated they form the enzyme C1 esterase (serine protease).
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[[IgM]] and certain [[IgG]]. The first step of complement activation is the binding of C1 to two Fc regions of the antibodies (IgM is such a strong activator of complement as it contains '''five''' Fc regions, while IgG contains '''one'''). C1 is actually a complex of C1q, C1r and C1s. C1q looks like a bunch of 6 tulips with each "flower" consisting of a globular protein head and a collagen "stem". C1q is required to trigger the cascade because two of it is the globular heads binds the two Fc regions. C1r and C1s then become activated when the C1q heads are antibody-bound. When they are activated they form the enzyme C1 esterase (serine protease).
  
 
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Revision as of 11:17, 30 April 2012


Introduction

Complement is so called because it complements the function of antibody. It is a triggered enzyme cascade and there are more than 20 different proteins in the complement cascades, with most being enzymes or pro-enzymes. It can be activated by both the innate and adaptive immune systems and is one of the main innate protective mechanisms of invertebrates. Due to its destructive potential the complement system is heavily regulated but when activated it works largely by forming pore complexes as well as triggering acute inflammation and by promoting phagocytosis by macrophages and neutrophils.

Complement Fixation Pathways

Classical and alternative pathways

Classical Pathway

Classical pathway in detail

This pathway of the complement system is triggered by the binding of antibody to antigen. The only subclasses that can activate complement this way are the IgM and certain IgG. The first step of complement activation is the binding of C1 to two Fc regions of the antibodies (IgM is such a strong activator of complement as it contains five Fc regions, while IgG contains one). C1 is actually a complex of C1q, C1r and C1s. C1q looks like a bunch of 6 tulips with each "flower" consisting of a globular protein head and a collagen "stem". C1q is required to trigger the cascade because two of it is the globular heads binds the two Fc regions. C1r and C1s then become activated when the C1q heads are antibody-bound. When they are activated they form the enzyme C1 esterase (serine protease).

It is the C1 esterase which then first digests components C4 to C4a and C4b, and C2 to C2a and C2b. It is the C4b which first binds to the antigen, and then forms a complex with C2a to produce the active enzyme C3 convertase (classical pathway). The binding of one C1q molecule produces one C1 esterase molecule that can then cause the binding of many hundreds of the C4b¯2a molecules, or the C3 convertase (classical pathway). The role of the convertase is to digest C3 into C3a and C3b. This part of the pathway is self-propagating as the production of C3b can now be amplified by the same mechanism as the alternative pathway (below).

The main action of the C3b molecule is to form the C4b¯2a¯3b complex, or the C5 convertase (classical pathway). The C5 convertase then activates C5 and initiates the membrane attack complex (MAC) as shown below. Other actions include the fragmentation of the C3b due to the actions of Factors I and H which forms C3bi, which provides an opsonin for phagocytosis.

Along with the actions of the fragments mentioned above, Ca fragments C3a, C4a and C5a, and Cb fragment C2b also form a chemotactic response. This brings neutrophils to the area of complement activation through the process of extravasation through the increase in cell adhesion molecules on the endothelium and an increase in vascular permeability; and chemotaxis which is the direct cellular movement. The fragments can also cause mast cell and basophil degranulation. These therefore induce acute inflammation.

Alternative Pathway

Alternative pathway in detail

Is found in animals that do not have antibodies i.e. animals lower than cartilaginous fish. It was discovered after the classical pathway and is thus called the 'alternative pathway'.

  • C3b has a binding site that anchors it to any surface
    • The surfaces of certain activators stabilise the otherwise short-lived C3b in the absence of antibody
      • Gram-negative bacteria, yeasts and fungi are the most efficient activators
  • When active C3b is bound to particle surfaces, it is protected from inactivation by another complement component, properdin
  • C3b can then bind Factor B producing the complex C3bB
  • C3bB is the only substrate for a plasma enzyme known as Factor D.
  • Factor D splits a small peptide (the Ba peptide) from Factor B
    • This generates C3b¯Bb. (C3 convertase)
    • C3b¯Bb acts on C3 to generate more C3b
    • C3b then generates more C3b¯Bb
      • An efficient positive feedback loop
  • C3b¯Bb can also bind C3b to form C3bB¯b3b.
  • C3bB¯b3b splits C5 into:
    • C5a, a small pro-inflammatory peptide
    • C5b, the initiator of the MAC

  • At the same time as C3bB¯b3b is being formed, Factors I and H are acting to breakdown C3b to iC3b
    • The C3b being broken down may be:
      • As single C3b or in the complex C3b¯Bb.
      • In plasma or on bacterial surfaces.
  • iC3b is inactive in the complement cascade but is a major target for phagocytes
    • Phagocytes have large numbers of iC3b receptors (complement receptors) which give opsonisation when engaged.

Mannose Binding Lectin pathway in detail

The main effects of alternative complement activation are therefore:

  1. To coat bacteria with iC3b
  2. To induce an acute inflammatory response via C3a and C5a.
    • Chemotactic for neutrophils
    • Induce the production of the cytokines (IL-1β and TNFα) responsible for acute inflammation

Mannose Binding-Lectin Pathway

Lectins are proteins that bind carbohydrates e.g. collectins. They bind carbohydrates that have a terminal mannose residue and are called mannose-binding lectins.

  • Secreted by the liver into plasma.
  • The action of lectin binding to carbohydrate activates plasma-associated proteases called mannose-binding lectin associated proteases (MASPs)
    • These act on C4 and C2 in the same way as C1 esterase, and on C3 in much the same manner as C3 convertase

Membrane Attack Complex

Membrane Attack Complex

This is the lytic pathway of complement function and can be initiated via either C3bB¯b3b or C4b2¯a3b.

  1. Split C5 into:
    • C5a is pro-inflammatory.
    • C5b the first molecule of the MAC (very short-lived and biologically active)
  2. C5b rapidly attaches to cell surfaces and binds to one C6 molecule
  3. C5bC6 binds one C7 molecule
    • C5bC6 binds to cell membrane via C7
  4. C5b67 binds one C8 molecule
    • C8 inserts into the cell membrane
  5. C9 molecules bind and polymerize within the cell membrane (1-16 C9 molecules)

The polymerization of C9 results in a small pore being formed which causes cell lysis by osmotic shock.

Complement Inhibitors

To prevent inappropriate activation of the complement system there is a range of control mechanisms/compunds.

Decay accelerating factor (DAF)

Is both secreted onto and present on cell membranes and hastens the degradation of C1 esterase. Exerts control on the classical pathway.

Factors I and H

Break down C3b and controls positive feedback by inhibiting C3b¯Bb thus preventing the complement cascade from running to exhaustion each time it is activated.

Complement receptor 1 (CR1)

Is present on many cell types especially erythrocytes and functions to bind C3d (the breakdown product of C3b) resulting from the action of Factors I and H. It binds potentially inflammatory immune complexes in plasma and these are then transported to the liver where they are phagocytosed by the hepatic macrophages and removed.

CD59

This binds the first molecule of C9 when it inserts into a cell membrane and prevents the polymerisation of C9 and therefore pore formation and cell lysis. It acts as a protective mechanism for the host cells.

Functions

Opsonisation

Once activated the complement system deposits a shell of protein on the bacterial cell surface. C4b, C3b, C5b and C7 molecules contain active binding sites that anchor the complex to the surface and the major protein on the cell surface is iC3b (some of the smaller C3 breakdown products (e.g. C3d) are also present).

Complement fragments (C2b, C3a, C4a and especially C5a) released after complement activation are chemotactic for phagocytes and iC3b acts as a target for phagocytosis. Phagocytes have receptors that bind avidly with the complement fragments. Complement-mediated opsonisation of microorganisms is several thousand times more efficient that innate receptors.

Inflammation

The smaller complement peptides are very efficient at inducing inflammation i.e. C3a and C5a. They attract granulocytes to the site of complement activation as well as stimulating their degranulation.

Cell Lysis

The components (C5 – C9) can kill pathogens directly by causing cell lysis. This is effective against encapsulated bacterial infection like Neisseria and Meningococci.

Links


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