Design of a complement mannose-binding lectin pathway-specific activation system applicable at low serum dilutions.

Recently we showed that alternative pathway (AP) amplification was responsible for more than 80% of specific classical pathway-induced terminal pathway activation under physiological conditions. The present study aimed to design a system for specific lectin pathway (LP) activation applicable at low serum dilutions with a fully functional AP. Comparison between activation of normal human serum (NHS), a mannose-binding lectin (MBL) homozygous D/D-deficient serum, and sera deficient in C1q and C2, all diluted 1 : 2, was essential to document optimal conditions for LP specificity. Mannan on the solid phase of enzyme-linked immunosorbent assay (ELISA) plates was used for activation, showing 0.5 microg mannan/well to give optimal conditions because at this concentration a good signal was preserved for C4 and TCC deposition in NHS, whereas the C3 deposition observed in C2-deficient serum at higher mannan concentrations reached nadir at 0.5 microg/well, indicating a lack of direct AP activation under these conditions. Pooled NHS and C1q-deficient serum gave the same degree of C4 and terminal complement complex (TCC) deposition, whereas deposition of these products was not obtained with MBL-deficient serum. Reconstitution with purified MBL, however, restored the depositions. A blocking anti-MBL monoclonal antibody (mAb) completely abolished the complement deposition, in contrast to a non-inhibiting anti-MBL mAb. Activation of C2-deficient serum induced C4 deposition similar to NHS, but negligible deposition of C3 and TCC, confirming the lack of direct activation of AP. Thus, this assay is unique in being LP-specific at low serum dilution and thus particularly suitable to study LP activation mechanisms and the role of AP amplification under physiological conditions.

Mannan-binding lectin activates C3 and the alternative complement pathway without involvement of C2.

Lectin pathway activation of C3 is known to involve target recognition by mannan-binding lectin (MBL) or ficolins and generation of classical pathway C3 convertase via cleavage of C4 and C2 by MBL-associated serine protease 2 (MASP-2). We investigated C3 activation in C2-deficient human sera and in sera with other defined defects of complement to assess other mechanisms through which MBL might recruit complement. The capacity of serum to support C3 deposition was examined by ELISA using microtiter plates coated with O antigen-specific oligosaccharides derived from Salmonella typhimurium, S. thompson, and S. enteritidis corresponding to serogroups B, C, and D (BO, CO, and DO). MBL bound to CO, but not to BO and DO, and efficiently supported C3 deposition in the absence of C2, C4, or MASP-2. The existence of an MBL-dependent C2 bypass mechanism for alternative pathway-mediated C3 activation was clearly demonstrated using CO, solid-phase mannan, and E. coli LPS. MASP-1 might contribute, but was not required for C3 deposition in the model used. Independent of MBL, specific antibodies to CO supported C3 deposition through classical and alternative pathways. MBL-dependent C2 bypass activation could be particularly important in various inherited and acquired complement deficiency states.

Gastrointestinal ischemia-reperfusion injury is lectin complement pathway dependent without involving C1q.

Complement activation plays an important role in local and remote tissue injury associated with gastrointestinal ischemia-reperfusion (GI/R). The role of the classical and lectin complement pathways in GI/R injury was evaluated using C1q-deficient (C1q KO), MBL-A/C-deficient (MBL-null), complement factor 2- and factor B-deficient (C2/fB KO), and wild-type (WT) mice. Gastrointestinal ischemia (20 min), followed by 3-h reperfusion, induced intestinal and lung injury in C1q KO and WT mice, but not in C2/fB KO mice. Addition of human C2 to C2/fB KO mice significantly restored GI/R injury, demonstrating that GI/R injury is mediated via the lectin and/or classical pathway. Tissue C3 deposition in C1q KO and WT, but not C2/fB KO, mice after GI/R demonstrated that complement was activated in C1q KO mice. GI/R significantly increased serum alanine aminotransferase, gastrointestinal barrier dysfunction, and neutrophil infiltration into the lung and gut in C1q KO and WT, but not C2/fB KO, mice. MBL-null mice displayed little gut injury after GI/R, but lung injury was present. Addition of recombinant human MBL (rhuMBL) to MBL-null mice significantly increased injury compared with MBL-null mice after GI/R and was reversed by anti-MBL mAb treatment. However, MBL-null mice were not protected from secondary lung injury after GI/R. These data demonstrate that C2 and MBL, but not C1q, are necessary for gut injury after GI/R. Lung injury in mice after GI/R is MBL and C1q independent, but C2 dependent, suggesting a potential role for ficolins in this model.

Binding of immune complexes to erythrocyte CR1 (CD35): difference in requirement of classical pathway components and indication of alternative pathway-mediated binding in C2-deficiency.

Deficiency of complement components within the classical pathway is associated with increased risk for immune complex disease. However, C2-deficient individuals often have a mild disease and about 50% are healthy. To study the importance of the different components for immune complex clearance, bovine serum albumin (BSA)/anti-BSA complexes were opsonized in human serum and the binding to erythrocyte complement receptor type 1 (CR1, CD35) was measured in vitro. In C2-depleted serum the complexes were opsonized and bound to CR1 but the reaction needed a longer opsonization time than in normal human serum (NHS). In contrast, serum reagent lacking C1q, C4 or C3 did not promote binding in this assay system. We also demonstrated that elevated levels of factor B could restore binding of complexes to erythrocytes in C2-depleted serum via alternative pathway activation. These results indicate that in spite of lack of a complete classical pathway, C2-deficient individuals could retain some immune complex opsonizing activity via the alternative pathway. This finding could contribute to the understanding of differences in association between complement deficiency and immune-complex disease.

In vitro analysis of complement-dependent HIV-1 cell infection using a model system.

Previous studies based on the use of human serum as a source of C have provided evidence for the C-dependent enhancement of cell infection by HIV-1. The present study was undertaken to distinguish C from other serum factors and to identify the proteins and the mechanisms involved in C-dependent cell infection by HIV-1. The classical C activation pathway was reconstituted from the proteins C1q, C1r, C1s, C4, C2, C3, factor H, and factor I; each were purified to homogeneity. A mixture of these proteins at physiological concentrations was shown to reproduce the ability of normal human serum to enhance the infection of MT2 cells by HIV-1 at low doses of virus. This enhancing effect was abolished when heat-inactivated serum and C2- or C3-depleted serum were used, and was restored upon addition of the corresponding purified proteins. A mixture of two synthetic peptides corresponding to positions 10-15 and 90-97 of human C receptor type 2 (CD21) as well as soluble CD4 both inhibited the C-dependent infection process. These data provide unambiguous evidence that HIV-1 triggers a direct activation of the classical C pathway in vitro and thereby facilitates the infection of MT2 cells at low doses of virus. These findings are consistent with a mechanism involving increased interaction between the virus opsonized by C3b-derived fragment(s) and the CD21 cell receptors and subsequent virus entry through CD4 receptors.

Deposition of mannan binding protein and mannan binding protein-mediated complement activation in the glomeruli of patients with IgA nephropathy.

Mannan binding protein (MBP) is a C-type lectin and has a high affinity to mannose and N-acetyl glucosamine. It is also known to activate C4 and C2 without C1 component, which is called 'lectin pathway'. We now report the presence of MBP and MBP-mediated complement activation in renal glomeruli of IgA nephropathy patients using an immunohistochemical method. In 7 of 42 cases with IgA nephropathy, MBP was detected in the glomerular mesangial area and colocalized with IgA1. In 19 cases with other types of IC-mediated glomerulonephritis including lupus nephritis and membranous nephropathy or without nephritis, MBP was not detected in the glomerulus. The C2- and/or C4-positive rate was 87.5% in the MBP-positive group and 20% in the MBP-negative group of IgA nephropathy. In addition, MBP-positive cases showed marked mesangial cell proliferation, lower creatinine clearance (53.4 +/- 10.0 vs. 77. 8 +/- 4.7 ml/min) and higher urinary protein excretion (2.5 +/- 0.9 vs. 0.9 +/- 0.2 g/day) compared with MBP-negative cases. These findings suggested that MBP was involved in glomerular complement activation through the lectin pathway and thus induced glomerular injury of IgA nephropathy. Since oligosaccharide chain alterations such as reduced sialic acid and galactose of IgA1 molecule have been reported in IgA nephropathy patients, MBP might bind to the IgA1 molecule via interaction between MBP and sugar chain.

Requirement for the alternative pathway as well as C4 and C2 in complement-dependent hemolysis via the lectin pathway.

Mannan-binding lectin (MBL) is a C1q-like molecule opsonic for several micro-organisms. MBL can activate C4, C2, and later acting complement components in the presence of serine proteases similar to but distinct from C1r and C1s via the lectin pathway of complement activation. We report here that mannan-coated MBL-sensitized erythrocytes are lysed via the lectin pathway in human serum-Mg-EGTA. The surprising occurrence of MBL-initiated lysis in the absence of calcium contrasts with the calcium requirement for C1q-initiated activation of C4 and C2. C2 is required, and lysis is significantly enhanced when indicator cells presensitized with C4 and then coated with mannan (EAC4-M) are used. The alternative pathway also is required, since lysis is lost when either factor D or factor B is removed and is restored upon reconstitution with the purified protein. Even though MBL is a C-type lectin, it is retained on mannan-coated erythrocytes in the absence of calcium. This contrasts with the absence of calcium-independent retention on mannan immobilized on polystyrene plates or beads, and helps explain the MBL-initiated hemolysis in Mg-EGTA. These investigations show that the alternative pathway as well as C4 and C2 of the classical pathway are required for complement-dependent hemolysis via the lectin pathway and provide a method for assay of lectin pathway-mediated complement activity in human serum that should be useful in unraveling the molecular interactions of this pathway.

A macrophage invasion mechanism of pathogenic mycobacteria.

Tuberculosis is the leading cause of death due to an infectious organism, killing an estimated 3 million people annually. Mycobacterium tuberculosis, the causative agent of tuberculosis, and other pathogenic mycobacteria require entry into host macrophages to initiate infection. An invasion mechanism was defined that was shared among pathogenic mycobacteria including M. tuberculosis, M. leprae, and M. avium but not by nonpathogenic mycobacteria or nonmycobacterial intramacrophage pathogens. This pathway required the association of the complement cleavage product C2a with mycobacteria resulting in the formation of a C3 convertase. The mycobacteria-associated C2a cleaved C3, resulting in C3b opsonization of the mycobacteria and recognition by macrophages.

Contribution of the complement control protein modules of C2 in C4b binding assessed by analysis of C2/factor B chimeras.

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.

Incomplete functional deficiencies of the fourth (C4) and second (C2) components of complement in a patient with linear frontoparietal scleroderma and his family. Deficiencies determined by a gene not linked to human leukocyte antigen system.

BACKGROUND: In a previous study, a patient suffering from linear frontoparietal scleroderma and some of his family members were found to have an incomplete functional deficiency of the second component (C2) of complement (C). In this study, the proband and the rest of his family members were investigated for functional deficiencies of C2 and the fourth component of C (C4). A search for null alleles of C2 (C2*Q0) and C4 (C4*Q0) was made to find out whether their occurrence is responsible for incomplete functional deficiencies. HLA analysis was performed to find out whether deficiencies are linked to HLA alleles known to be associated with C4*Q0 and C2*Q0. Possible large deletions at C4 and 21-hydroxylase (21-OH) gene loci were also investigated in some family members. OBSERVATIONS: The proband had a combined functional deficiency of C4 and C2. Some of his family members had a partial functional deficiency of C4, some of C2 and some of C4 and C2; none had null alleles of C2 (C2*Q0), factor B (B*Q0) or C4B (C4B*Q0). C4*Q0 or functional C4 deficiency in this family was not associated with HLA-A1;B8;DR3 alleles. C2 deficiency was also not associated with HLA antigens known to be associated with type I and II C2 deficiencies. No gene deletion or unusual polymorphism at C4A and 21-OHA loci could be seen by restriction fragment length polymorphism (RFLP) studies. CONCLUSIONS: Combined and isolated partial functional deficiencies of C4 and C2 observed in the proband and many of his family members were not caused by C activation or null alleles. They were not linked to HLA system and were reminiscent of those observed previously in a family in which C4 deficiency was determined by a gene not linked to the HLA system.

Unique C1 inhibitor dysfunction in a kindred without angioedema. I. A mutant C1 INH that inhibits C1-s but not C1-r.

We have described hereditary incomplete deficiency of the fourth component of complement (C4) in 10 members of a large kindred. C4 deficiency in this kindred is not linked to C4 loci in the HLA region. C4 synthesis is decreased, and C4 catabolism is normal in kindred members with low serum C4 levels. We have discovered a uniquely dysfunctional C1 inhibitor in all C4-deficient members of this kindred. C1 inhibitor dysfunction is revealed by incubating sera of affected members with EDTA, which destroys all C4 activity in these sera, but not in normal sera or sera from individuals with partial C4 deficiencies. The M(r) of C1 inhibitor purified from affected members is normal, but approximately 50% of this C1 inhibitor resists cleavage by trypsin (0.14 microM) at arg444, suggesting a substitution at this position. Moderate increases in trypsin, however, result in cleavage of the resistant molecules, which would not be expected if arg444 were the site of the mutation. All molecules in C1 inhibitor purified from affected members' plasma bind to activated C1s (C1-s), but approximately 50% of molecules in these preparations do not bind to activated C1r (C1r). These findings show that affected kindred members have a unique mutation in C1 inhibitor. The mutant C1 inhibitor does not prevent the activation of C1s by C1-r when serum Ca2+ is chelated by EDTA, but its inhibition of C1-s is normal in vivo, as shown by normal C2 levels, normal C4 catabolism, and absence of angioedema in C4-deficient members. The nature of the mutation, its selective failure to inhibit C1-r, and its relationship to decreased C4 synthesis remain to be defined.

Molecular heterogeneity of the fourth component of complement (C4) and its genes in vitiligo.

In view of evidence suggesting vitiligo is an autoimmune disease, we investigated whether vitiligo is associated with inherited deficiencies of the fourth (C4) and second (C2) component of complement and with certain human leukocyte antigens (HLA). Analysis of functional activities of C4 and C2 in sera of patients with vitiligo (n = 42) showed that 17% of them had a heterozygous C4 deficiency and 5% had a heterozygous C2 deficiency. In the normal control group (n = 30), 3% had a heterozygous C4 deficiency and none had a C2 deficiency. C4 typing by Western blot analysis showed the frequency of the C4A*Q0 allele in the vitiligo patient group to be close to normal. However, the frequency of one C4B*Q0 allele was three times higher, and that of two C4B*Q0 alleles five times higher in the vitiligo patient group than the reported frequencies in normal control groups. Southern blot analysis of Taq1 digests of DNA using C4 and 21-hydroxylase probes showed that two patients with two C4B*Q0 alleles had a deletion of a 21-OHA-C4B segment. In the other patients, having one or two C4B*Q0 alleles, these null alleles probably occurred due to a loss of C4 gene expression. HLA analysis did not show any allelic association of C4A*Q0 or C4B*Q0 with any HLA antigen in vitiligo, but confirmed the previous findings of a negative association with HLA-DR3 and a positive association with HLA-DR4. These results suggest that abnormalities of the C4B gene and the above-mentioned associations with HLA antigens may be some of the risk factors in vitiligo.

Functional properties of heterogeneous human asialo-C4 and its isotypes C4A and C4B.

The fourth component of human complement (C4) is encoded at two separate but closely linked loci within the MHC on the short arm of chromosome 6. Thus, there are two types of C4 protein in most individual and pooled normal human sera (NHS): C4A and C4B. Incubation of individual sera, pooled NHS, or purified heterogeneous C4 (C4A/C4B) with bacterial sialidase at 37 degrees C increased C-mediated hemolysis of antibody-sensitized sheep erythrocytes 1.54- to 1.93-fold. Comparative studies of Tmax of human C2, using asialo-C4 or buffer-treated C4 on EAC1gp and extrapolation to time 0 indicated a z value 4-fold higher with asialo-C4. This indicated that more hemolytically active C42 complexes are available with sialidase-treated C4 compared to untreated C4. There was no appreciable difference in the % 125I-C4 bound to EAC1gp (sialidase- or buffer-treated). Sera from two different blood donors with C4A3 phenotype (C4BQ0), two different donors with C4B1 phenotype (C4AQ0), and serum from an individual heterozygous deficient at both C4A3 and C4B1 regions (A3, AQ0; B1, BQ0) were investigated. The C4 allotypes, purified from these sera, were treated with sialidase; the C4A3 was enhanced in hemolytic assays by sialidase-treatment (1.52- to 2.3-fold), whereas the C4B1 allotype was not enhanced. Fluorometric determinations revealed that approximately the same percentage of sialic acid was released from sialidase-treated C4A3 and C4B1. Therefore, the increase in hemolytic titer observed after treatment of NHS or purified heterogeneous C4 with sialidase is a property of C4A3 but not a property of C4B1.

A simple radial immunohemolysis assay for the measurement of functional complement C2 activity / O ensaio simples de imunohemolise radial para medir da atividade funcional do complemento 2

This study describes a simple radial immunohemolysis method for determining the hemolytic activity of the second component of complement (C2) in human serum. The assay is based on the recovery of hemolytic activity of normal serum which has been pretreated to anactivate endogenous C2 and thenmixed with test serum containing an unknown amount of C2. The pretreated serum, designated R2 reagent, is obtained by heating normal human sera under carefully standardized conditions of temperature, time, volume and type of test tube. R2 reagent is incorporated into agarose together with hemolysin-sensitized erythrocytes, and spread om a plate. The test serum is placed in wells cut in the agarose and, after appropriate incubation, the diameters of the hemolytic areas are measuremed.The area of hemolysis is directly proportional to the logarithm of the serum concentration.As a standard for C2 functional activity, dilutions of a pool of normal sera are tested on the same plate. The method is specific for C2 and can deted as little as 20% of the C2 in normal serum (abouth 6 *g C2 protein/ml). The error in reproducibility is about 3% of the mean.in normal serum, the lower confidence limit of the distribution of the C2 values (based on a sample of 80 individuals) corresponded to 70 % of undiluited serum. This method is sultable for use in clinical laboratories since it is simple, rapid quantitative ans inexpensive, and does not require special equipement

Biologic activity of a C2-derived peptide. Demonstration of a specific interaction with guinea pig lung tissues.

A synthetic peptide derived from the carboxy terminus of C2b has been investigated for its ability to induce the contraction of guinea pig lung parenchymal strips. This peptide is known to enhance vascular permeability in guinea pig and human skin, and to induce contraction of estrous rat uterus. This C2 peptide (C2 207-223) is active from 5 x 10(-5) M to 5 x 10(-4) M and is not tachyphylactic to itself. No cross-activity between C2 207-223 and C5a or C3a could be demonstrated. C2 207-223 is not inhibited by antihistamines or cyclooxygenase inhibitors. These data indicate that the peptide exerts its action via a mechanism distinct from those of the C3a and C5a anaphylatoxins.

The C4 and C2 but not C1 components of complement are responsible for the complement activation triggered by the Ra-reactive factor.

Ra-reactive factors (RaRF) are the name of a group of C-dependent bactericidal factors that bind specifically to Ra chemotype strains of Salmonella. These factors are present in the sera of a wide variety of vertebrates and have common characteristics. Here we investigate the C components required for the C activation induced by mouse RaRF, by using hemolysis of Ra LPS-coated E (ELPS) as a model system. It was found that C1-depleted and C1q-depleted sera were as effective as the undepleted serum in the lysis of ELPS sensitized with RaRF. Addition of the C1 component or C1q subcomponent to the depleted sera did not increase the effect. On the other hand, C4 and C2 components were found to be essential for the lysis of RaRF-sensitized ELPS. Activities of C4 and C2 remained on the sensitized cells even after washing the cells, suggesting that the classical C3 convertase, C4b2a, is generated on the RaRF-sensitized ELPS.

Angioedema induced by a peptide derived from complement component C2.

Synthetic peptides that correspond to the COOH-terminal portion of C2b enhance vascular permeability in human and guinea pig skin. In human studies, 1 nmol of the most active peptide of 25-amino acid residues produced substantial local edema. A pentapeptide and a heptapeptide corresponding to the COOH-terminal sequence of C2b each induced contraction of estrous rat uterus in the micromole range; a peptide of 25 amino acids from this region induced a like contraction of rat uterus at a concentration 20-fold lower than the smaller peptides. The vascular permeability of guinea pig skin was enhanced by doses of these synthetic peptides in a similar fashion as that observed for the concentration of rat uterus. The induction of localized edema by intradermal injection in both the guinea pig and the human proceeds in the presence of antihistaminic drugs, suggesting that there is a histamine-independent component to the observed increase in vascular permeability. Cleavage of C2 with the enzymic subcomponent of C1, C1s, yields only C2a and C2b, and no small peptides, whereas cleavage of C2 with C1s and plasmin yields a set of small peptides. These plasmin-cleaved peptides are derived from the COOH terminus of C2b, and they induce the contraction of estrous rat uterus.