Complement system

The more than 30 proteins of the human complement system are dissolved in the blood plasma or cell-bound and serve to defend against microorganisms (e.g. bacteria , fungi, parasites). However, they also have strong cell-destroying properties and, if they act unregulated, can be responsible for tissue damage in the course of many diseases (e.g. glomerulonephritis , hemolytic-uremic syndrome , myocardial infarction , systemic lupus erythematosus , rheumatoid arthritis ).

term

The term “complement” was introduced by Paul Ehrlich around 1890 . According to his theory, the immune system was made up of cells with specific receptors that can recognize antigens . After contact with the antigen, these receptors are formed and released into the blood for distribution. Ehrlich called these receptors, now called antibodies , amboceptors. Their function is to recognize both the antigen and a heat-sensitive component of the blood serum (which Ehrlich referred to as complement), as they complement the function of the cellular immune defense. Even though Ehrlich coined the term complement, the actual description of complement goes back to Jules Bordet : He discovered that complement can work both in conjunction with antibodies and on its own.

Mode of action

The main task of the complement system is to cover the surface of pathogens in order to enable the phagocytes to destroy those pathogens that they would otherwise not recognize ( opsonization ). In addition, it triggers a number of inflammatory reactions that help fight the infection . The fragments of some complement proteins act as chemokines that attract more phagocytes to the focus of infection. Another function is the direct destruction of bacteria by inserting pores in their cell membranes .

A large part of the complement proteins are so-called zymogens . These are proteins, in this case proteases, which in turn are activated by limited proteolysis. These zymogens are usually found all over the body without any reaction. In the event of an infection, however, they are activated locally and activate further zymogens by splitting them. This triggers a cascade of zymogen activations, whereby a few molecules activated early are activated later, which leads to an amplification of the response.

Components of the complement system

The following proteins are directly involved in the signal pathways of the complement system: the complement factors C1 to C9 , mannose-binding lectin (MBL) and the serine proteases C1r and C1s or MASP-1 to 3 ( MBL-associated serine proteases ). By protease -mediated cleavage of complement factors C1 to C5 and bearings together with the factors C6 to C9 produced a number of proteins and protein complexes. These include, for example, the anaphylatoxins C3a, C5a and C4a with vasodilating, bronchoconstrictive and chemotactic effects ( inflammatory reaction ) and the Membrane Attack Complex (MAC). Negative regulators of the system are the C1 inhibitor, factor H, factor I, C4bp, CD35, CD46, CD55 , CD59 and vitronectin. Properdin and Cobra Venom Factor act as activators.

Process and effect of complement activation

Reaction cascade of the complement system: classic, alternative and lectin activation pathway, amplification, terminal pathway and MAK.

There are three ways in which the complement system is activated:

The classic way

Nine glycoproteins (C1-C9) are involved in the classic activation pathway of the complement system. These have molecular weights of 24 to 410 kDa and are secreted into the bloodstream after formation in the liver , and to a small extent also in lymphocytes , macrophages and fibroblasts , where they make up about 10% of the globulin fraction. The complement factor C1 is the first complement protein of the classical path and consists of the six-member collectin C1q and two molecules C1s and two molecules C1r (Fig. Below). C1q has several binding domains for antigen- bound antibodies (IgG and IgM). For the activation of the serine proteases bound to C1q (C1r and C1s) two Ig-Fc regions 40  nm apart are necessary. That is why one molecule is sufficient for IgM antibodies, whereas for IgG antibodies several, ideally six, molecules are required; IgA, IgE or IgD antibodies cannot activate the classic route. Free antibodies therefore do not lead to activation. However, C1q can also bind directly to the surface of pathogens and thus initiate the classic route without the help of antibodies.

Classic activation can also be triggered by DNA , collagen and CRP ( C-reactive protein ).

After activation, the serine protease C1s then catalyzes the two start reactions of the classic route. One cleavage of C2 into C2a and C2b and another of C4 into C4a and C4b. C2a and C4b combine to form the C4b2a complex and thus form the “C3 convertase of the classic route”. C4b2a3b forms the C5 convertase, which cleaves C5 into C5a and C5b. C3a and C5a diffuse and in turn act as anaphylatoxin .

In the classic activation of the complement system, in addition to C4a and C4b, C4d is also split off, which can bind covalently to the endothelium on which the complement reaction took place. The function of the C4d is not yet understood, but it is used in biopsy as a marker and diagnostic tool for antibody-induced transplant rejection.

The activation of C1 is controlled by a plasma protein, the C1 inhibitor, which binds to the active enzyme part of C1 (C1r / s) and thereby separates it from C1q. Factors I, H and C4b-binding protein cleave activated C3.

The Lectin Way

In the lectin pathway, the mannose-binding lectin (MBL) binds to mannose or fikolin to N-acetylglucosamine on the pathogenic surface (e.g. bacterial peptidoglycan ) and activates the MBL-associated serine proteases MASP-1, MASP-2 and MASP -3. These catalyze the same reactions as in the classic way. Here, too, C4b and C2a form a C4b2a heterodimer and thus likewise the “C3 convertase of the classic route”.

Alternative route scheme

${\ displaystyle {\ begin {aligned} C3 + H_ {2} \ mathrm {O} \ longrightarrow C3 & (H_ {2} \ mathrm {O}) \\ & \ downarrow \ longleftarrow factor \ B \\ C3 & (H_ { 2} \ mathrm {O}) B \\ & \ downarrow \ longleftarrow factor \ D \\ C3 & (H_ {2} \ mathrm {O}) Bb + Ba \\ C3 \ longrightarrow & \ downarrow \\ C3a & + C3b \ \ & \ downarrow \ longleftarrow factor \ B, factor \ D \\ C3b & Bb + Ba \\ C3 \ longrightarrow & \ downarrow \ quad \ quad \ \ swarrow factor \ H, factor \ I \\ C3a & + C3b \ longrightarrow inactive \ C3b \\ & \ downarrow \ longleftarrow factor \ B, factor \ D \\ C3b & Bb + Ba \\ & \ downarrow \ longleftarrow C3b \\ C3b & Bb3b \\ & \ downarrow \\ C5 \ & \ longrightarrow C5a \\ & \ downarrow \\ C & 5b \\ & \ downarrow \ longleftarrow C6, \ C7, \ C8 \\ C5b & 678 \\ & \ downarrow \ longleftarrow nC9 \\ nC5b & 6789 \\ {\ text {Membranan}} & {\ text {handle complex}} \ end {aligned }}}$

The alternative way

The alternative path leads to the formation of the " C3 convertase of the alternative path ". This path is triggered by the spontaneous decay of the unstable complement factor C3 into C3a and C3b. C3a diffuses and has a chemotactic and inflammatory effect as anaphylatoxin. C3b binds covalently to a cell surface. Free C3b is inactivated by factor H and factor I. If C3b binds to the body's own cells, it is also inactivated or broken down relatively quickly by regulatory proteins. On the other hand, it remains active on pathogenic surfaces and binds factor B, which is cleaved into Ba and Bb by factor D (plasma protease). The resulting complex C3bBb is known as the “C3 convertase of the alternative route”. It is very unstable and disintegrates if it is not stabilized by properdin.

C3 convertase elicited reactions

The C3 convertases, C3bBb and C4b2a, formed in the alternative, classic and lectin pathway, now split C3 into C3b and C3a with high activity. The resulting C3b molecules now essentially have three options:

1. They cannot find a suitable surface to which they can bind and are inactivated by CD46.
2. The molecules attach themselves to the cell surface of a target cell and thus lead to another “start” of the alternative path. A positive feedback arises. They also act as opsonins and mark the target cell as a worthwhile target for phagocytosis .
3. Some of the molecules bind to a C3 convertase (C4b2a or C3bBb). The resulting trimolecular complexes C4b2a3b and "C3bBb3b + properdin" no longer cleave C3, but C5. Therefore they are now referred to as “ C5 convertases of the classical or alternative way ”.

The membrane attack complex.

The two products of the C5 cleavage act on the one hand as anaphylatoxin and chemotactic attractant (C5a) and on the other hand they also initiate the formation of the membrane attack complex (MAC) (C5b). The “anchor” C5b recruits the factors C6, C7 and C8 one after the other. The resulting C5b678 complex then starts the polymerization of C9. After the aggregation of up to 18 C9 monomers, the C5b678poly9 complex represents the finished membrane attack complex, which attacks the target cell through pore formation in the cell membrane and leads to its lysis.

The soluble complement fragments C3a, C4a and C5a trigger a local inflammatory reaction. By binding to the complement receptors of the basophilic granulocytes, they lead to the release of histamine , heparin and leukotrienes . The activation of complement receptors on endothelial cells , smooth muscle cells, monocytes , eosinophils and mast cells leads to bronchoconstriction , vasodilation , increase in vascular permeability and recruitment (through C5a) of granulocytes and monocytes on vascular walls, which is the prerequisite for their migration into the inflammatory area. C3a mainly promotes tissue repair mechanisms. C5a stimulates the inflammatory response. The anaphylatoxins thus form an important link between innate and adaptive immune defense .

Medical importance

Many of the functions of complement have been discovered through the appearance of diseases in deficiencies in complement factors or regulators:

• C1 inhibitor: A congenital or acquired C1-INH deficiency can lead to an excessive complement reaction, as it plays a role in the occurrence of angioedema ( hereditary angioedema (HAE), acquired angioedema (AAE)). The strong release of anaphylatoxins (C3a, C5a) leads to swelling of the airways, and the skin and intestines are also affected.
• C2 and C4: Immune complex diseases occur in people with C2 deficits or defects in the "early" components C1q, C1r, C1s or also C4. Complete congenital C1q deficiency is the strongest genetic risk factor for developing systemic lupus erythematosus (SLE).
• C3: A deficiency of component C3 leads to the frequent occurrence of bacterial infections (e.g. with Neisseria).
• If factor H is missing due to a mutation , there is an uncontrolled activation of the alternative path on the basement membrane of the kidney corpuscles and on the Bruch's membrane of the eye. The C3 deposits lead to chronic kidney disease ( membranoproliferative glomerulonephritis type II ), which can also be associated with impaired vision. A more common cause of this disease is an autoantibody that is directed against the C3bBb complex, stabilizes it and thus activates the alternative path.
• If the so-called GPI anchors on blood cells are defective , they can no longer protect themselves from being destroyed by the complement system and paroxysmal nocturnal hemoglobinuria occurs .

literature

• Charles A. Janeway Jr. u. a .: immunology. 5th edition. Spectrum Academic Publishing House, Heidelberg / Berlin 2002, ISBN 3-8274-1078-9 .
• Löffler, Petrides: Biochemistry and Pathobiochemistry . 7th edition. Springer-Verlag, 2004
• Siegenthaler, Blum: Clinical Pathophysiology . 9th edition. Thieme-Verlag, Zurich 2006
• Prabhu Nesargikar, B. Spiller, R. Chavez: The complement system: History, pathways, cascade and inhibitors . In: European Journal of Microbiology and Immunology . tape 2 , no. 2 , June 2012, ISSN  2062-509X , p. 103–111 , doi : 10.1556 / EuJMI.2.2012.2.2 , PMID 24672678 , PMC 3956958 (free full text) - ( akademiai.com [accessed on March 28, 2020]). 

Web links

• Further page (English)
• Basics of immunology 17th lecture: The complement system. As a PDF file under 16. The complement system. Immunológiai és Biotechnológiai Intézet, UNIVERSITY OF PÉCS [1]

Individual evidence

1. ^ GJ Arlaud et al .: Structural biology of C1 . In: Biochemical Society Transactions . No. 30 , 2002, pp. 1001-1006 ( Article ).  , Fig .: Modular structures of C1q, C1r and C1s and macroscopic model of the C1 complex
2. ↑ CA Diebolder, FJ Beurskens, RN de Jong, RI Koning, K. Strumane, MA Lindorfer, M. Voorhorst, D. Ugurlar, S. Rosati, AJ Heck, JG van de Winkel, IA Wilson, AJ Koster, RP Taylor, EO Saphire, DR Burton, J. Schuurman, P. Gros, PW Parren: Complement is activated by IgG hexamers assembled at the cell surface. In: Science Volume 343, Number 6176, March 2014, pp. 1260-1263, ISSN  1095-9203 . doi: 10.1126 / science.1248943 . PMID 24626930 .
3. ↑ Bohana-Kashtan O., Ziporen L., Donin N., Kraus S., Fishelon Z .: Cell signals transduced by complement. In: Molecular Immunology . No. 41 , 2004, p. 583–597 , doi : 10.1016 / j.molimm.2004.04.007 . 
4. ^ Sontheimer R. et al .: C1q: Its Functions within the Innate and Adaptive Immune Responses and its Role in Lupus Autoimmunity. In: Journal of Investigative Dermatology . No. 125 , 2005, pp. 14-23 , doi : 10.1111 / j.0022-202X.2005.23673.x .