Human C3b/C4b receptor (CR1). Demonstration of long homologous repeating domains that are composed of the short consensus repeats characteristics of C3/C4 binding proteins

10 overlapping CR1 cDNA clones that span 5.5 kb were isolated from a tonsillar library and sequenced in whole or in part. A single long open reading frame beginning at the 5' end of the clones and extending 4.7 kb downstream to a stop codon was identified. This sequence represents approximately 80% of the estimated 6 kb of coding sequence for the F allotype of CR1. Three tandem, direct, long homologous repeats (LHRs) of 450 amino acids were identified. Analysis of the sequences of tryptic peptides provided evidence for a fourth LHR in the F allotype of CR1. Amino acid identity between the LHRs ranged from 70% between the first and third repeats to 99% between the NH2-terminal 250 amino acids of the first and second repeats. Each LHR comprises seven short consensus repeats (SCRs) of 60-70 amino acids that resemble the SCRs of other C3/C4 binding proteins, such as complement receptor type 2, factors B and H, C4 binding protein, and C2. Two additional SCRs join the LHRs to a single membrane-spanning domain of 25 amino acids; thus, the F allotype of CR1 probably contains at least 30 SCRs, 23 of which have been sequenced. Each SCR is predicted to form a triple loop structure in which the four conserved half-cystines form disulfide linkages. The linear alignment of 30 SCRs as a semi-rigid structure would extend 1,140A from the plasma membrane and might facilitate the interaction of CR1 with C3b and C4b located within the interstices of immune complexes and microbial cell walls. The COOH-terminal cytoplasmic domain of 43 residues contains a six-amino-acid sequence that is homologous to the sequence in the epidermal growth factor receptor that is phosphorylated by protein kinase C.     

Formation of a hemolytically active cellular intermediate by the interaction between properdin factors B and D and the activated third component of complement

The present studies demonstrate that the factor B-dependent C3 convertase can be affixed to an erythrocyte by use of an intermediate bearing C3b and that this convertase brings the hemolytic reaction to completion with an efficiency comparable to that of classical convertase. The evidence that the EAC43 intermediate was lysed by a new pathway includes requirements for factors B and D and cell-bound C3b for subsequent lysis by the terminal components, C3-C9. The linear stoichiometry of the effective molecule titrations of C3b and factor B, and the first-order kinetics displayed by the generation and decay of the factor B-dependent hemolytic site are characteristics consistent with the one-hit theory as initially developed for the classical complement system. The use of hemolytically active cellular intermediates to examine the reactions occurring with C3b and factors B and D has allowed extension of the one-hit theory to this molecular sequence, development of effective molecule titrations, recognition of the analogies to the functional characteristics of the classical C3 convertase, and discrimination of the probable mechanism of terminal complement activation from reactive lysis.     

C5orf30 is a negative regulator of tissue damage in rheumatoid arthritis

The variant rs26232, in the first intron of the chromosome 5 open reading frame 30 (C5orf30) locus, has recently been associated with both risk of developing rheumatoid arthritis (RA) and severity of tissue damage. The biological activities of human C5orf30 are unknown, and neither the gene nor protein show significant homology to any other characterized human sequences. The C5orf30 gene is present only in vertebrate genomes with a high degree of conservation, implying a central function in these organisms. Here, we report that C5orf30 is highly expressed in the synovium of RA patients compared with control synovial tissue, and that it is predominately expressed by synovial fibroblast (RASF) and macrophages in the lining and sublining layer of the tissue. These cells play a central role in the initiation and perpetuation of RA and are implicated in cartilage destruction. RASFs lacking C5orf30 exhibit increased cell migration and invasion in vitro, and gene profiling following C5orf30 inhibition confirmed up-regulation of genes involved in cell migration, adhesion, angiogenesis, and immune and inflammatory pathways. Importantly, loss of C5orf30 contributes to the pathology of inflammatory arthritis in vivo, because inhibition of C5orf30 in the collagen-induced arthritis model markedly accentuated joint inflammation and tissue damage. Our study reveal C5orf30 to be a previously unidentified negative regulator of tissue damage in RA, and this protein may act by modulating the autoaggressive phenotype that is characteristic of RASFs.Rheumatoid arthritis is a chronic systemic autoimmune disease characterized by a symmetrical, inflammatory arthropathy that frequently results in damage to synovial-lined joints with consequent pain, stiffness, and reduced functional capacity. The prevalence of RA is 0.8–1% in Western Europe and North America, and it is believed to arise from an interplay between genetics and the environment. Smoking is known to be a major risk factor particularly for anticitrullinated protein antibody-positive RA (1), whereas consumption of alcohol reduces both the risk and the severity of RA (2). The severity of RA varies from a mild condition with little joint damage to an unremitting condition that leads to extensive bone and cartilage damage. The radiological severity of damage to the hands and feet is widely used to measure outcome of RA and has been shown to have a significant genetic component (3, 4). Loci genetically associated with radiological damage include DRB1 (5), CD40 (6) and TRAF1/C5 (7), IL-4 (8), and IL-15 (9).A genome-wide association study involving 12,277 RA cases and 28,975 controls, all of European descent, reported association of rs26232 in the first intron of chromosome 5 open reading frame 30 (C5orf30) with risk of RA (10). Importantly linkage disequilibrium did not extend to genes in the flanking regions, indicating that the association was arising from C5orf30. This association was subsequently replicated in a British study of 6,108 RA cases and 13,009 controls (11). In a study of three large European RA populations (n = 1,884), we reported an allele dose association of rs26232 with radiological damage (12).The biological activities of human C5orf30 are unknown, and the precise roles it plays in RA have not yet been reported. There is indirect evidence linking human C5orf30 with immune function via its association with intracellular UNC119 (13); the latter increasing both T-cell activation by up-regulating Lck/Fyn activity and Src kinases regulating macrophages activation (14, 15). There are, however, no studies of the biological functions of human C5orf30 and, in view of the genetic association with RA susceptibility and severity, we have undertaken in silico analysis and both in vitro and in vivo experiments to determine its functional activities in RA. Here, we report C5orf30 to be a yet unidentified negative regulator of tissue damage in RA, acting by modulating the autoaggressive phenotype that is characteristic of RA synovial fibroblasts (RASF). It is highly expressed in the synovium of RA patients compared with healthy and osteoarthritis (OA) predominately by RASF in the lining and sublining layer. These cells play an important role in the initiation and perpetuation of RA and are implicated in cartilage destruction (16). Targeting C5orf30 expression by using siRNA technology resulted in increased invasiveness, proliferation and migration of RASFs in vitro, and modulated expression of genes in RA-relevant pathways including migration and adhesion. Importantly, loss of C5orf30 contributes to the pathology of inflammatory arthritis in vivo, because inhibition of C5orf30 in the collagen-induced arthritis (CIA) model mice markedly accentuated joint inflammation and cartilage destruction. These data confirm C5orf30 as a previously unidentified regulator of tissue destruction in RA.     

Pathways of cell activation in spondyloarthropathies

The initiating event in cell activation is unknown in most autoimmune diseases. The role of infection is clear in some cases, especially in reactive arthritis; however, there is little evidence of a specific organism in other spondyloarthropathies. Common pathways of cell-cell interaction and activation manifest in inflammation, but subtle differences may exist. The presence of T cells, macrophages, and B-lymphocytes suggest an autoimmune mechanism; the arthritogenic peptide theory has been proposed. Furthermore, the association of spondyloarthropathies with HLA-B27 suggests it may be important in synovial T-cell activation. Other cell types involved in the process of bone and cartilage destruction, including fibroblasts and osteoclasts, may also be activated. Endothelial activation and angiogenesis may be a critical primary event in these diseases. Finally, trauma (physical or psychological) in the form of stress may be an important factor; the nervous system and neuropeptides may play a role in cell activation and initiation of arthritis.