C4B gene influences intestinal microbiota through complement activation in patients with paediatric-onset inflammatory bowel disease.

Complement C4 genes are linked to paediatric inflammatory bowel disease (PIBD), but the mechanisms have remained unclear. We examined the influence of C4B gene number on intestinal microbiota and in-vitro serum complement activation by intestinal microbes in PIBD patients. Complement C4A and C4B gene numbers were determined by genomic reverse transcription-polymerase chain reaction (RT-PCR) from 64 patients with PIBD (Crohn's disease or ulcerative colitis). The severity of the disease course was determined from faecal calprotectin levels. Intestinal microbiota was assessed using the HITChip microarray. Complement reactivity in patients was analysed by incubating their sera with Yersinia pseudotuberculosis and Akkermansia muciniphila and determining the levels of C3a and soluble terminal complement complex (SC5b-9) using enzyme immunoassays. The microbiota diversity was wider in patients with no C4B genes than in those with one or two C4B genes, irrespective of intestinal inflammation. C4B and total C4 gene numbers correlated positively with soluble terminal complement complex (TCC, SC5b-9) levels when patient serum samples were stimulated with bacteria. Our results suggest that the C4B gene number associates positively with inflammation in patients with PIBD. Multiple copies of the C4B gene may thus aggravate the IBD-associated dysbiosis through escalated complement reactivity towards the microbiota.

Factor H family proteins: on complement, microbes and human diseases.

At present, the human Factor H protein family represents seven multidomain, multifunctional serum proteins. This group includes the complement and immune regulators Factor H, the Factor H-like protein 1 (FHL-1) and five Factor H-related proteins proteins (FHR-1, -2, -3, -4 and -5). Each is exclusively composed of individually folded protein domains, termed short consensus repeats (SCRs) or complement control modules. Structure-function analyses allowed the localization of the complement regulatory domain of Factor H and FHL-1 in the N-terminal region within SCRs 1-4. In addition, multiple binding sites for C3b, heparin and microbial surface proteins were localized in the N-terminus, within the middle region and also in the C-terminus of Factor H and FHL-1. Recent results show a central role for the C-terminus of Factor H, i.e. SCRs 19-20. These particular domains are conserved in all FHRs identified so far, include contact points for C3b, heparin and microbial surface proteins and represent a 'hot-spot' for gene mutations in patients that suffer from the Factor H-associated form of haemolytic uraemic syndrome.

Factor H and disease: a complement regulator affects vital body functions.

Factor H is a multidomain and multifunctional protein. As a complement regulator factor H determines the fate of newly formed C3b and controls formation and stability of C3 convertases both in the fluid phase and on cell surfaces. In addition, this plasma protein displays functions outside complement control as it has been suggested to act as an adhesion protein, to be a ligand for the cellular integrin receptor CR3 (CD11b/CD18) and to display chemotactic activity. Genetic and pathophysiological analyses describe a role for factor H in vital body functions. Depletion or the absence of factor H due to genetic reasons leads to unrestricted C3 consumption. A reduced amount of factor H in plasma or mutations within the factor H gene may lead to glomerulonephritis (type II MPGN) or hemolytic uremic syndrome (HUS). Certain pathogenic organisms have been shown to evade complement attack by binding factor H from the host. Such specific factor H binding components have been demonstrated on the surface of microbes, e.g., Streptococcus pyogenes and Neisseria gonorrhoeae. Here, we summarize the current knowledge how abnormalities in function of the central complement regulator factor H are associated with human diseases.

Lack of functional similarity between complement factor H and anticardiolipin cofactor, beta 2-glycoprotein I (apolipoprotein H).

Beta 2-glycoprotein I (beta 2-GPI) is a 50 kDa protein in human plasma composed of five repeating complement control protein modules thereby closely resembling complement factor H which has 20 such units. Both beta 2-GPI and factor H (150 kDa) have binding sites for negatively charged polyions. beta 2-GPI has been shown to act as a cofactor for antiphospholipid antibodies upon their binding to anionic phospholipids. In factor H the polyanion recognition site participates in the discrimination between alternative pathway activating and non-activating surfaces. In light of the structural similarity between beta 2-GPI and factor H we have examined whether beta 2-GPI has a role in the alternative complement pathway recognition process. Both activators (zymosan) and non-activators (sheep erythrocytes) of the alternative complement pathway were coated with C3b. Radiolabelled factor H was observed to recognize C3b on both surfaces, whereas beta 2-GPI bound to neither. In competition experiments beta 2-GPI could not prevent the association of 125I-H with either non-activator or activator bound C3b. Conversely, factor H could not replace beta 2-GPI as a cofactor for antiphospholipid antibodies upon their binding to anionic phospholipids. It is concluded that beta 2-GPI and factor H, despite similarities in structure, exhibit distinct, non-overlapping functions.