Regulatory system of guinea-pig complement C3b: tests for compatibility of guinea-pig factors H and I with human factors

Development of an anti-guinea pig CD4 monoclonal antibody for depletion of CD4+ T cells in vivo

The guinea pig serves as a useful animal model for a number of human diseases and has played an important role during development and testing of experimental vaccines and disease therapies. However, the availability of reagents to examine the immunological response in this species is very limited. Monoclonal antibodies (mAb) specific for cell surface proteins or products of immune cells have been useful tools for characterizing and quantifying immune responses in humans and in murine models of human disease, but very few similar reagents are available for characterizing and manipulating the immune response of guinea pigs. A rat IgG2a mAb specific for guinea pig CD4 has previously been described and was shown to inhibit T cell proliferation, but was inefficient at depleting CD4+ T cells in vivo. We hypothesized that the in vivo CD4+ T cell depletion function of this mAb could be improved by expression of the rat IgG2b heavy chain. We show that the purified mAb from an IgG2b class-switch variant, but not the parental IgG2a mAb, significantly depleted CD4+ T cells from secondary lymphoid tissue of guinea pigs. Further, treatment of guinea pigs with the IgG2b mAb at 2.0 mg/kg resulted in depletion of CD4+ T cells from peripheral blood and spleen. The use of this modified antibody to specifically alter the immune response of guinea pigs should prove useful in a number of guinea pig infectious disease models.

Complement activation in thrombotic microangiopathy

The endothelium lining the vascular lumen is continuously exposed to complement from the circulation. When erroneously activated on host cells, complement may generate a deleterious effect on the vascular wall leading to endothelial injury, exposure of the subendothelial matrix and platelet activation. In this review the contribution of complement activation to formation and maintenance of the pathological lesion termed thrombotic microangiopathy (TMA) is discussed. TMA is defined by vessel wall thickening affecting mainly arterioles and capillaries, detachment of the endothelial cell from the basement membrane and intraluminal thrombosis resulting in occlusion of the vessel lumen. The TMA lesion occurs in haemolytic uraemic syndrome (HUS) and thrombotic thrombocytopenic purpura (TTP). HUS is further sub-classified as associated with Shiga toxin-producing Escherichia coli (STEC-HUS) or with complement dysregulation (atypical HUS) as well as other less common forms. The contribution of dysregulated complement activation to endothelial injury and platelet aggregation is reviewed as well as specific complement involvement in the development of HUS and TTP.

Membrane-bound complement regulatory proteins as biomarkers and potential therapeutic targets for SLE

For the last two decades, there had been remarkable advancement in understanding the role of complement regulatory proteins in autoimmune disorders and importance of complement inhibitors as therapeutics. Systemic lupus erythematosus is a prototype of systemic autoimmune disorders. The disease, though rare, is potentially fatal and afflicts women at their reproductive age. It is a complex disease with multiorgan involvement, and each patient presents with a different set of symptoms. The diagnosis is often difficult and is based on the diagnostic criteria set by the American Rheumatology Association. Presence of antinuclear antibodies and more specifically antidouble-stranded DNA indicates SLE. Since the disease is multifactorial and its phenotypes are highly heterogeneous, there is a need to identify multiple noninvasive biomarkers for SLE. Lack of validated biomarkers for SLE disease activity or response to treatment is a barrier to the efficient management of the disease, drug discovery, as well as development of new therapeutics. Recent studies with gene knockout mice have suggested that membrane-bound complement regulatory proteins (CRPs) may critically determine the sensitivity of host tissues to complement injury in autoimmune and inflammatory disorders. Case-controlled and followup studies carried out in our laboratory suggest an intimate relation between the level of DAF, MCP, CR1, and CD59 transcripts and the disease activity in SLE. Based on comparative evaluation of our data on these four membrane-bound complement regulatory proteins, we envisaged CR1 and MCP transcripts as putative noninvasive disease activity markers and the respective proteins as therapeutic targets for SLE. Following is a brief appraisal on membrane-bound complement regulatory proteins DAF, MCP, CR1, and CD59 as biomarkers and therapeutic targets for SLE.

Role of YadA, Ail, and Lipopolysaccharide in Serum Resistance of Yersinia enterocolitica Serotype O:3

Complement attack is a host strategy leading to elimination of pathogens. Yersinia enterocolitica expresses several potential complement resistance factors: the outer membrane proteins YadA and Ail as well as lipopolysaccharide (LPS). To study the contribution of these factors to the survival of Y. enterocolitica serotype O:3 in nonimmune human serum, we constructed 23 mutant strains of Y. enterocolitica O:3 expressing different combinations of YadA, Ail, LPS O antigen, and LPS outer core. Survival of bacteria was analyzed in normal serum (with functional classical, lectin, and alternative complement activation pathways) and EGTA-Mg-treated serum (only alternative pathway functional). Kinetic killing tests revealed that the most potent single-serum resistance factor needed for long-term survival was YadA; Ail was also indispensable, but it provided short-term survival and delayed the bacterial killing. On the contrary, the LPS O antigen and outer core, when in combination with YadA, Ail, or both, had a minor and often negative effect on serum resistance. Bacteria in the exponential phase of growth were more resistant to serum killing than stationary-phase bacteria. After exposing bacteria to EGTA-Mg-treated serum, O antigen could prevent deposition of covalently bound C3b on bacteria at 3 min of incubation, even as a single factor. At later time points (15 and 30 min) it had to be accompanied by YadA, Ail, and outer core. In normal serum, the bacteria were less resistant to C3b deposition. However, no direct correlation between the C3 deposition pattern and bacterial resistance was observed.

Molecular cloning and functional characterization of guinea pig IL-12

IL-12 is a heterodimeric cytokine that plays a central role in cell-mediated immunity. We cloned complete cDNAs of guinea pig homologues of IL-12 p35 and p40 subunits, and compared their functional properties with human IL-12. Both p35 and p40 mRNA were constitutively expressed in the testis and peritoneal macrophages. On immunoblotting, anti-guinea pig p40 antibody detected the constitutive expression of p40 protein in the testis, while in macrophages it was induced in response to lipopolysaccharide. An unidentified 200-kDa macromolecule was also expressed in the testis. All recombinant hybrid heterodimer p70 (guinea pig p70, human p70 and two interspecies heterodimers) exerted proliferative activity toward concanavalin A-primed guinea pig and human lymphoblasts in a dose-dependent manner. A similar tendency was observed in IFN-gamma production in IL-2-treated human lymphocytes. All hybrid heterodimers also induced IFN-gamma mRNA from IL-2-treated guinea pig splenocytes. Thus, unlike the current concept that the p35 subunit determines the species incompatibility of IL-12 in humans and mice, p35 has marginal ability to define its species-specific functional expression between humans and guinea pigs. In addition, constitutive expression of IL-12 or related molecules in the testis indicated a potential role of this molecule in regulation of physiological or pathophysiological conditions in the reproductive system.

Control of C3b and C5b deposition by CD46 (membrane cofactor protein) after alternative but not classical complement activation

C3b and C5b deposition following complement activation, and its regulation by CD46 were studied using xenogenic Chinese hamster ovary (CHO) cells as targets and cytofluorometry. Following activation of the alternative pathway, an initial low level of C3b deposition was observed on CHO cell surfaces after a lag time of approximately 4 min. This was followed by a secondary high level of C3b deposition with a slower rate. C3b deposition was maximal within 15 min. When CD46 was expressed (B2 isoform), the kinetics of C3b deposition were essentially unchanged, but the onset of the secondary high C3b deposition was fully prevented. C5b deposition was also observed on CHO but not on CHO.CD46 cells following activation of the alternative pathway. Activation of the classical pathway on CHO and CHO.CD46 cells, using factor B-depleted human serum and anti-CHO antibodies, resulted in almost identical single-peak C3b deposition profiles. Accordingly, no regulation of C5b deposition by CD46 was evident following activation of the classical pathway. These data indicate that CD46 prevents the C3b deposition amplification loop mediated by the alternative C3 convertase and, consequently, inhibits the formation of the alternative C5 convertase. But CD46 prevents neither the spontaneous tick-over C3b deposition leading to the formation of the alternative C3 convertase nor the formation of the functional classical C3 and C5 convertases.

Altered expression of host-encoded complement regulators on human cytomegalovirus-infected cells

Human cytomegalovirus (HCMV)-infected cells persist in the presence of anti-HCMV antibody, suggesting that HCMV has evolved mechanisms to evade host immune defenses. Insofar as no virus-encoded complement inhibitors have been identified for HCMV, we hypothesized that HCMV infection may alter the expression of host-encoded cell surface complement inhibitors. Herein, we report that cell surface expression of two complement regulator proteins, CD55 and CD46, which are members of the regulators of complement activation (RCA) gene cluster, increased up to eightfold following infection of fibroblasts or glioblastoma cells with HCMV, but not after infection with HSV-1 or adenovirus. However, the cell surface expression of a third complement regulator, CD59, which is not a member of the RCA gene cluster, was not altered during HCMV infection. Functional studies using purified complement components demonstrated that up-regulation of CD55 suppressed the activity of cell-associated C3 convertases on HCMV-infected cells. Furthermore, increased CD55 expression protected infected cells from complement-mediated lysis, an effect which directly correlated with the length of HCMV infection. Increased expression of host-encoded complement regulator proteins may provide protection of HCMV-infected cells from the host immune response in vivo, through increasing the resistance of infected cells to complement-mediated lysis and decreasing the deposition of C3-derived products on the cell surface.

Prediction from sequence comparisons of residues of factor H involved in the interaction with complement component C3b

The amino acid sequence of the region of bovine factor H containing the C3b binding site has been derived from sequencing overlapping cDNA clones. A cDNA sequence encoding 669 amino acids was obtained. Like human and mouse factor H the sequence can be arranged into a number of internally homologous units (CPs), each of which is about 60 amino acids long and is based on a framework of four conserved cysteine residues. Bovine factor H is of the same molecular mass as human and mouse factor H, and is therefore likely to be composed of 20 contiguous CPs. Comparisons with human and mouse factor H indicate that the partial bovine sequence encodes CPs 2-12 inclusive of bovine factor H. Bovine factor H binds to human ammonia-treated C3 (causing thiolester cleavage) [C3(NH3)] and promotes the cleavage of human C3(NH3) in the presence of bovine factor I. Other studies indicate that CPs 2-5 of human factor H encompass the C3b binding and factor I cofactor activity site. Multiple sequence alignments of human factor H, mouse factor H (which also interacts with human C3b) and bovine factor H with CP modules whose structures have been determined experimentally, have been used to predict residues in the hypervariable loops of CPs 2-5 and to identify residues of potential importance in human C3 binding and factor I cofactor activity. Leu-17 and Gly-20 of CP 2, Ser-17, Ala-19, Glu-21, Asp-23 and Glu-25 of CP 3 and Lys-18 of CP 4 are all conserved between the three species. It may be that CPs 3 and 4 interact with C3(NH3) directly, whilst CPs 2 and 5 maintain the correct orientation for CPs 3 and 4 to interact.

A functional analysis of recombinant soluble CD46 in vivo and a comparison with recombinant soluble forms of CD55 and CD35 in vitro

The human cell surface complement regulatory proteins CD46 (MCP), CD55 (DAF) and CD35 (CR1) protect autologous cells from complement-mediated damage by inhibiting C3 and C5 convertases. This regulatory potential has previously been exploited in the treatment of some models of inflammatory injury by the generation of recombinant soluble (rs) proteins, such as rsCD55 and rsCD35 . More recently, we have shown that rsCD46 inhibits complement activation in the fluid phase. In this report, the ability of rsCD46, rsD55 and rsCD35 to regulate human complement activation mediated by the classical pathway in vitro was clearly demonstrated by all three soluble proteins; however, rsCD35 was a more effective inhibitor than either rsCD46 or rsCD55. A combination of rsCD46+ rsCD55 was more potent than either of these proteins alone. Cell lysis via alternative pathway activation in vitro was efficiently regulated by rsCD46 and rsCD35 to a similar extent, whereas rsCD55 was not effective. Assays of rsCD46 in vivo have previously not been possible due to difficulties in expressing sufficient quantities of protein. This limitation has been overcome and now we report the ability of rsCD46 to inhibit immune complex-mediated inflammation in a rat using the reverse passive Arthus reaction model. Administration of rsCD46 significantly reduced the size of lesion, and histological examination showed a reduction in inflammatory infiltrate and edema. These data suggest that rsCD46, in addition to rsCd55 and rsCD35, may be useful a therapeutic agent.

High expression of membrane cofactor protein of complement (CD46) in human leukaemia cell lines: implication of an alternatively spliced form containing the STA domain in CD46 up-regulation

Human membrane cofactor protein (MCP, CD46) is a receptor for the measles virus and serves as a complement regulator which protects host cells from autologous complement attack. MCP is highly polymorphic due to a variety of mRNA splice products. The levels of MCP expression on T and myeloid cell lines are usually two-eightfold higher than those on their normal counterparts, whereas Burkitt's lymphoma B cell lines express less MCP than B cell lineages carrying no EB virus. The molecule has a Ser/Thr-rich (ST) domain adjacent to the functional domain, namely short consensus repeats (SCR). The ST domain and a cytoplasmic tail (CYT) contribute to the MCP polymorphism. The ST domain is encoded by three exons (A, B and C) and major ST isoforms are STABC, STBC and STC. The authors investigated the relationship between the expression levels and isoform usage of MCP by flow cytometry using specific antibodies against STA and STC, by reverse transcriptase-polymerase chain reaction (RT-PCR) with size markers for each splice variant, and by RT-PCR/Southern blotting using a specific probe for STA. The results were (1) the profiles of mean shifts of myeloid and T cell lines were STC < STA on flow cytometry while those of B cell lines and normal blood cells were STA < STC; (2) all cell lines tested by RT-PCR expressed the messages for the isoforms STBC/CYT1, STC/CYT1, STBC/CYT2, and STC/CYT2. The band for STABC/CYT2 overlapped that for STC/CYT1, and the band for STABC/CYT1 was marginal in all cell lines examined; (3) semi-quantitative analysis of the STABC isoforms by Southern blotting indicated the presence of high levels of the STABC messages in myeloid and T-cell lines in comparison with B lymphoid cells and normal leucocytes. Thus, the quantity of MCP expressed parallels the STABC message level, which is up-regulated in T and myeloid leukaemia cell lines.

Homologous C3 deposition and homotypic cell adhesion in a human myeloid cell line, P39

It has been accepted that decay-accelerating factor (DAF) and membrane cofactor protein (MCP) on human cells block C3 deposition, thereby preventing homologous complement attack. In this study, we discovered that a human myeloid cell line, P39, was a target for human C3 even though it expressed normal DAF and MCP. This homologous C3 deposition was induced by serum containing Mg2+ and EGTA (Mg(2+)-EGTA serum) selectively on a P39 subline [P39(+)cells] having the capacity to form cell aggregates. Another P39 subline [P39(-)cells] growing as a separated form did not induce homologous C3 deposition. Multiple C3 fragments, C3b and C3bi, were fixed on P39(+) cells and a significant amount of C5a was released. Several distinct C3 fragment-membrane acceptor molecule complexes were immunoprecipitated with anti-C3c antibody from surface-labeled P39(+) cells treated with Mg(2+)-EGTA serum and from unlabeled cells incubated with 125I-labeled C3 and Mg(2+)-EGTA serum. Two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed 90, 60 and < or = 40 kDa C3 acceptors on P39(+) cells. On these cells, some of the C3 bound to these acceptors remained in the form of C3b, which can form C3/C5 convertases. P39(+) cells differed phenotypically from P39(-) cells in that P39(+) cells expressed intercellular adhesion molecule-1 (ICAM-1), whereas P39(-) cells did not. Both cells were lymphocyte function-associated antigen 1 (LFA-1)+/CR3- counter-receptors for ICAM-1. However, homotypic cell adhesion was not completely inhibited by antibodies against ICAM-1 and LFA-1, suggesting that the homotypic cell aggregation of P39(+) cells is due only in part to ICAM-1 and LFA-1. In addition, C3 deposition, the expression of ICAM-1, and cell aggregation were enhanced by both tumor necrosis factor-alpha and interferon-gamma. Although the principal causative mechanisms remain obscure, C3 deposition and cell adhesion appear in parallel in this cell line and may be involved in the modulation of cell-mediated immune reactions.

Membrane cofactor protein (MCP, CD46) in seminal plasma and on spermatozoa in normal and "sterile" subjects

A sperm protein of molecular mass 43 kDa (the spermatozoa membrane cofactor protein, smMCP) and a seminal plasma protein of 60 kDa (ssMCP) were identified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) followed by immunoblotting with four monoclonal antibodies (mAb) against membrane cofactor protein (MCP, CD46). These proteins served as factor I cofactors for the cleavage of methylamine-treated C3 (C3ma), the activity of which was blocked by M75, an MCP cofactor-activity-blocking mAb. Thus, these semen proteins are antigenic and functional homologous of MCP. On SDS-PAGE analysis these MCP migrated as single-band proteins which differed from the two-band forms of MCP expressed on other cells. smMCP was N-glycosylated but not O-glycosylated, while ssMCP was O-glycosylated: after deglycosylation of these proteins bands were detected at 38-40 kDa and 43 kDa on SDS-PAGE, respectively. These semen MCP are therefore, structurally different from the conventional MCP. ssMCP in both normal and "sterile" subject groups was determined by sandwich enzyme-linked immunosorbent assay. Seminal plasma in the two groups contained 250-700 ng/ml ssMCP. The difference between the two groups was marginal, although samples from normal subjects tended to show higher concentrations of ssMCP than samples from "sterile" subjects. No molecular difference was observed with ssMCP and smMCP in the two groups by SDS-PAGE/immunoblotting analysis. Immunohistochemical analysis suggested that MCP was positive in glandular epithelial cells and the lumen of the prostate, and in most intra-lumen cells of the testis. Using antibody M177, solubilized prostate and testis were analyzed by immunoblotting and compared with other cell MCP. The major band of MCP in the testis, but not in the prostate, was of 60 kDa, which aligned with ssMCP. No band of testis or prostate MCP, however, aligned with smMCP. ssMCP may be produced in the testis, while the origin of smMCP remains unknown. We hypothesize that ssMCP is important in the survival of spermatozoa, protecting them against local secretion of immunoglobulin and complement in the female genital tract, and that smMCP, which is expressed on acrosome-reacted spermatozoa, plays an essential role in the interaction of spermatozoa with oocytes.

Functional properties of the allotypes of mouse complement regulatory protein, factor H: difference of compatibility of each allotype with human factor I

Three allotypes of mouse factor H, H.1, H.2, and H.3 were purified from the sera of mice with different factor H allotypes, and their functional properties were investigated. The three allotypes all bound to heparin, DNA, Con A, and methylamine-treated mouse C3 (C3(MA)mo) with similar affinities for each protein immobilized, showed identical mobilities on SDS-PAGE, and were reacted well with rabbit polyclonal antibody against H.1 and H.2. Factor I-cofactor activity of these factor H allotypes was measured using highly purified material of mouse, guinea-pig, and human origin. In a homologous system, these allotypes expressed indistinguishable mouse factor I (Imo)-cofactor activity for the cleavage of C3(MA)mo. Imo-cofactor activity was again indistinguishable in these allotypes when methylamine-treated human C3 (C3(MA)hu) or methylamine-treated guinea-pig C3 (C3(MA)gp) was substituted for the C3(MA)mo substrate. The cofactor activity of these factor H allotypes, however, was augmented 4-5 times if C3(MA)hu) was used instead of C3(MA)mo, and was barely detected if C3(MA)gp was employed. In contrast, differences in the potency of the cofactor activity for the three allotypes were revealed if human factor 1 (Ihu) was substituted for Imo: the order of the efficiency for the cleavage of C3(MA)hu was H.2 > H.1 = H.3. These results, taken together with the finding that the homologous combinations of mouse and human factors H and I expressed greater activity for the cleavage of C3(MA)hu than did the heterologous combinations of factor H and factor I, suggest that mouse factor H allotypes discriminate species of protease factor I but not those of substrate (C3(MA), and H.2 possesses the best compatibility for Ihu in C3(MA)hu inactivation.

Membrane cofactor protein

MCP serves to down-regulate the activation of complement on host tissue. It performs this function by serving as a cofactor for the factor I-mediated cleavage of C3b and C4b. MCP is most likely an intrinsic regulator, i.e., it primarily protects its home cell. The wide tissue distribution of MCP mirrors this critical function of host cell protection. With the exception of erythrocytes, every cell and tissue examined expresses this protein. MCP is represented as two broad heterogeneous bands on SDS-PAGE with M(r)s of 51,000-58,000 and 59,000-68,000. The quantity of each form expressed is inherited in an autosomal codominant fashion. In most cells and cell lines, four isoforms of MCP predominate and arise by alternative splicing of a single MCP gene. All forms possess four repeating modules of--60 aminoacids, an area enriched in serines, threonines, and prolines [(STP), probable site of O-linked glycosylation], a short area of unknown function, a transmembrane domain, and a cytoplasmic tail. The isoforms differ, however, in the length and composition of the STP region and in the cytoplasmic tail. Alternative splicing of a single exon within the STP region determines the protein phenotype. Alternative splicing at the COOH_terminus gives rise to two distinct cytoplasmic tails. The biological significance of these structural variations in the STP and cytoplasmic tail regions is being investigated.

The mouse factor H allotypes with multiple amino acid replacement, H.1 and H.2 show indistinguishable co-factor activity for factor I

The authors report the functional analysis of the purified mouse factor H allotypes H.1 and H.2, which were clearly distinguished from each other by an immunodiffusion test. Both allotypes acted as a co-factor for factor I in cleaving mouse C3b and we found no significant difference between their activities. The results strongly suggest that the function of mouse factor H for the co-factor activity has been well conserved between two allotypes.