The availability of the human genome sequence allowed us to identify a human complement-related, C1r-like protease gene (c1r-LP) located 2 kb centromeric of the C1r gene (c1r). Compared with c1r, c1r-LP carries a large deletion corresponding to exons 4-8 of c1r. The open reading frame of the C1r-LP cDNA predicts a 50 kDa modular protein displaying 52% amino acid residue identity with the corresponding regions of C1r and 75% identity with a previously described murine C1r-LP. The serine protease domain of C1r-LP, despite an overall similarity with the AGY group of complement serine proteases, has certain structural features characteristic of C2 and factor B, thus raising interesting evolutionary questions. Northern blotting demonstrated the expression of C1r-LP mRNA mainly in the liver and ELISA demonstrated the presence of the protein in human serum at a concentration of 5.5+/-0.9 microg/ml. Immunoprecipitation experiments failed to demonstrate an association of C1r-LP with the C1 complex in serum. Recombinant C1r-LP exhibits esterolytic activity against peptide thioesters with arginine at the P1 position, but its catalytic efficiency (kcat/K(m)) is lower than that of C1r and C1s. The enzymic activity of C1r-LP is inhibited by di-isopropyl fluorophosphate and also by C1 inhibitor, which forms stable complexes with the protease. Most importantly, C1r-LP also expresses proteolytic activity, cleaving pro-C1s into two fragments of sizes identical with those of the two chains of active C1s. Thus C1r-LP may provide a novel means for the formation of the classical pathway C3/C5 convertase.
Complement C7 deficiency (C7D) is associated frequently with recurrent bacterial infections, especially meningitis caused by Neisseria meningitidis. We report in this work the molecular bases of C7D in two unrelated Japanese males. We used exon-specific PCR/single-strand conformation polymorphism analysis as a screening step for mutations. Subsequent direct sequencing of the target exons identified homozygous mutations in exon 16 of case 1 and in exon 15 of case 2. The mutation of case 1 was a homozygous T to A transversion at nucleotide 2250, the third nucleotide of the codon TGT for Cys728, leading to a stop codon TGA (C728X). In case 2, a homozygous 2-bp deletion (2137delTG/2138delGT/2139delTG) caused a frameshift, generating a premature termination codon 4 to 6 nucleotides downstream. Family study in case 1 confirmed the genetic nature of the defect. Moreover, we detected a novel polymorphism in intron 11 that presumably is linked to the mutation responsible for C7D in case 1. Our results indicate that the pathogenesis of C7D is heterogeneous like most of the other deficiencies of complement components.
Abstract Objective Human C‐reactive protein (CRP) binds apoptotic cells and alters blood clearance of injected chromatin in mice. To test whether CRP participates in the pathogenesis of systemic lupus erythematosus (SLE), we examined disease development in lupus‐prone (NZB × NZW)F 1 (NZB/NZW) mice expressing a human CRP transgene (hCRPtg/BW). Methods Mortality was monitored, proteinuria was determined by dipstick, and serum levels of human CRP and anti–double‐stranded DNA (anti‐dsDNA) were determined by enzyme‐linked immunosorbent assay in NZB/NZW and hCRPtg/BW mice. Thin sections of kidneys were analyzed by immunofluorescence microscopy to compare deposition of IgG, IgM, C3, and human CRP, and electron microscopy was used to reveal differences in ultrastructure. In situ hybridization was performed to detect human CRP messenger RNA expression. Results The hCRPtg/BW mice had less proteinuria and longer survival than NZB/NZW mice. They also had lower IgM and higher IgG anti‐dsDNA titers than NZB/NZW mice, although the differences were transient and small. In hCRPtg/BW mice, accumulation of IgM and IgG in the renal glomeruli was delayed, reduced, and more mesangial than in NZB/NZW mice, while end‐stage accumulation of IgG, IgM, and C3 in the renal cortex was prevented. There was less glomerular podocyte fusion, basement membrane thickening, mesangial cell proliferation, and occlusion of capillary lumens in hCRPtg/BW mice, but dense deposits in the mesangium were increased. With disease progression in hCRPtg/BW mice, there was little rise in the plasma CRP level, but CRP in the kidneys became increasingly apparent due to local, disease‐independent, age‐related expression of the transgene. Conclusion In hCRPtg/BW mice, CRP protects against SLE by increasing blood and mesangial clearance of immune complexes and by preventing their accumulation in the renal cortex.
To identify the complement control protein (CCP) module(s) of C2 that are required for C4b recognition, we constructed a panel of C2/factor B chimeras by substituting intact or partial factor B CCP modules for the corresponding ones of C2. Epitope mapping indicated that the anti-C2b mAb 3A3.3, which inhibits binding of C2 to C4b, reacts with the second CCP of C2 and similarly the anti-Ba mAb HA4-1A, which inhibits binding of factor B to C3b, reacts with the second CCP of factor B. The hemolytic activity of the chimeras CP1, CP2, and CP3a containing CCP1, CCP2, and a fragment of CCP3 of factor B, respectively, was substantially decreased compared with that of wild-type C2. The CP3 and CP1-3 chimeras, in which CCP3 and all three CCP modules of factor B, respectively, were substituted, had no hemolytic activity. Loss of activity could be attributed to the resistance of these two chimeras to C1s cleavage, which was probably due to conformational changes of the cleavage site. The combined results indicate that all three CCP modules of C2 contribute structural elements to the C4b-binding site of C2b. This site has been shown previously to be necessary for the initial binding of C2 to C4b which leads to the formation of the classical pathway C3 convertase.
Abstract C-reactive protein (CRP) is an acute phase protein with a well known association with infection and other inflammatory conditions. Studies with use of purified CRP in in vitro assays provided early evidence that CRP has antibacterial activity. Subsequently it was shown that passively administered human CRP can protect mice from lethal infection with Streptococcus pneumoniae. In this study, we extend these observations to an in vivo model of host resistance by using human CRP transgenic mice. CRP transgenic mice experimentally infected with S. pneumoniae lived longer and had significantly lower mortality than their nontransgenic littermates. This increased resistance to infection was associated with q 10- to 400-fold reduction of bacteremia. Furthermore, male transgenics exhibited longer survival time than females, and this difference could be attributed to increased expression of CRP by males, which was mediated by testosterone. This study provides the first unequivocal evidence that CRP plays an important role in vivo in host defense against pneumococcal infections, and shows that sex hormones can affect expression of the human CRP transgene in mice.
