Short Consensus Repeats Research Articles

Streptococcus pneumoniae evades complement attack and opsonophagocytosis by expressing the pspC locus-encoded Hic protein that binds to short consensus repeats 8-11 of factor H.

Streptococcus pneumoniae is an important cause of upper and lower respiratory tract infections, meningitis, peritonitis, bacterial arthritis, and sepsis. Here we have studied a novel immune evasion mechanism of serotype 3 pneumococci, which are particularly resistant to phagocytosis. On their surfaces the bacteria express the factor H-binding inhibitor of complement (Hic), a protein of the pneumococcal surface protein C family. Using radioligand binding, microtiter plate assays, surface plasmon resonance analysis, and recombinant constructs of factor H, we located the binding site of Hic to short consensus repeats (SCRs) 8-11 in the middle part of factor H. This represents a novel microbial interaction region on factor H. The only other ligand known so far for SCRs 8-11 of factor H is C-reactive protein (CRP), an acute phase protein that binds to the pneumococcal C-polysaccharide. The binding sites of Hic and CRP within the SCR8-11 region were different, however, because CRP did not inhibit the binding of Hic and required calcium for binding. Binding of factor H to Hic-expressing pneumococci promoted factor I-mediated cleavage of C3b and restricted phagocytosis of pneumococci. Thus, virulent pneumococci avoid complement attack and opsonophagocytosis by recruiting functionally active factor H with the Hic surface protein. Hic binds to a previously unrecognized microbial interaction site in the middle part of factor H.

Replacing the SCR domains of vaccinia virus protein B5R with EGFP causes a reduction in plaque size and actin tail formation but enveloped virions are still transported to the cell surface.

A vaccinia virus (VV) recombinant is described in which the outer envelope of extracellular enveloped virus (EEV), cell-associated enveloped virus (CEV) and intracellular enveloped virus (IEV) is labelled with the enhanced green fluorescent protein (EGFP) derived from Aequorea victoria. To construct this virus, EGFP was fused to the VV B5R protein from which the four short consensus repeats (SCRs) of the extracellular domain had been deleted. Cells infected with the recombinant virus expressed a B5R-EGFP fusion protein of 40 kDa that was present on IEV, CEV and EEV, but was absent from IMV. The recombinant virus produced 2- and 3-fold reduced levels of IMV and EEV, respectively. Analysis of infected cells by confocal microscopy showed that actin tail formation by the mutant virus was reduced by 86% compared to wild-type (WT). The virus formed a small plaque compared to WT, consistent with a role for actin tails in promoting cell-to-cell spread of virus. However, the enveloped virions were still transported to the cell surface, confirming that this process is independent of actin tail formation. Lastly, we compared the mutant virus with a recombinant VV in which the B5R SCR domains were deleted and show that, contrary to a previous report, the plaque size of the latter virus was reduced compared to WT. This observation reconciles an inconsistency in the field and confirms that viruses deficient in formation of actin tails form small plaques.

Constitutive Expression and Regulation of Rat Complement Factor H in Primary Cultures of Hepatocytes, Kupffer Cells, and Two Hepatoma Cell Lines

The 155-kd soluble complement regulator factor H (FH), which consists of 20 short consensus repeats, increases the affinity of complement factor I (FI) for C3b by about 15 times. In addition to its cofactor activity, it prevents factor B from binding to C3b and promotes the dissociation of the C3bBb complex. The primary site of synthesis of FH, as well as of FI, is the liver, but the cell types responsible for the hepatic synthesis of both factors have not yet been clearly identified. In contrast to FI-mRNA, which was detectable only in hepatocytes (HC), FH-specific mRNA was identified in both HC and Kupffer cells (KC). As calculated for equal amounts of mRNA isolated from both cell types, FH-specific mRNA was found to be nearly 10-fold higher in KC than in HC, leading to the conclusion that KC are an abundant source of FH. Of the investigated proinflammatory cytokines IL-6, TNF-α, IL-1β, and IFN-γ, only IFN-γ up-regulated FH-specific mRNA up to 6-fold in both primary HC and KC. This was also demonstrable on the protein level. However, FH-specific mRNA was not inducible in the rat hepatoma cell line H4IIE, which did not express FH-specific mRNA and could not be up-regulated in FAO cells that constitutively expressed FH-specific mRNA. This demonstrates that transformed cell lines do not reflect FH regulation in isolated primary HC. In addition to IFN-γ, the endotoxin lipopolysaccharide (LPS) up-regulated FH-specific mRNA nearly 10-fold in KC after stimulation at concentrations of 10 or 1 ng/ml. In contrast, concentrations of up to 2 μg LPS/ml did not show any effect on HC. Our data suggest that LPS does not regulate the expression of FH in HC.

Location and structure of the human FHR-5 gene.

The factor H family of genes has been localised to human chromosome 1q32. This region encodes various proteins involved in complement regulation and is known as the regulators of complement activation (RCA) gene cluster. The factor H genes encode seven known plasma proteins. Using fluorescence in situ hybridisation (FISH), radiation hybrid (RH) mapping and BLAST alignment analysis, we have established that the factor H-related 5 (FHR-5) gene is closely linked to the other factor H gene family members. Analysis of the genomic sequence indicates that the FHR-5 gene is situated between FHR-2 and the non-complement protein factor XIIIb (Fl3B). Like all members of the factor H family. transcription of FHR-5 is in the telomeric direction. Furthermore, the short consensus repeats (SCRs) of FHR-5 are encoded by individual exons and splicing is of type 1. These data allow the generation of a more complete map of the factor H gene family.

Coxsackie B viruses that use human DAF as a receptor infect pig cells via pig CAR and do not use pig DAF.

Coxsackie B viruses (CVB) are enteroviruses belonging to the family Picornaviridae. Serotypes 1, 3 and 5 of CVB bind to the human membrane complement regulator decay-accelerating factor (DAF) and the coxsackievirus/adenovirus receptor (CAR), using either or both as receptors. These viruses are known to infect pig cell lines, but the receptor(s) involved has not been identified. We have recently characterized the pig homologue of DAF and here explore the interactions of human DAF-binding CVB with pig homologues of DAF and CAR. CVB infection of three pig cell lines resulted in cytolysis, which could be not be blocked by anti-pig DAF antibodies. CVB bound to CHO cells transfected with human DAF, but not pig DAF. Modification of pig DAF by incorporation of the fourth short consensus repeat of human DAF did not confer CVB-binding capacity. CVB did bind CHO cells expressing pig or human CAR, and pre-incubation of pig cells with anti-CAR antibody blocked CVB infection.

The Cromer blood group system: a review

The antigens of the Cromer blood group system reside on decay accelerating factor (DAF), a protein belonging to the regulators of complement activation family. The blood group system consists of eight high-incidence antigens and three low-incidence antigens. The molecular basis for the antigens is known and, with the exception of IFC, each antigen is the product of a single nucleotide polymorphism in the DAF gene and has been localized to one of the four short consensus repeat regions on the DAF protein. The red blood cells (RBCs) of people with the Cromer null phenotype, Inab, lack DAF. Antibodies to Cromer antigens are rarely encountered although there is evidence that the antibodies may cause accelerated destruction of transfused RBCs. There is no risk of hemolytic disease of the newborn associated with Cromer system antibodies because the placenta is a rich source of fetally derived DAF, which is thought to adsorb the antibodies.

Species-specific differences in the structure of orthopoxvirus complement-binding protein

Vaccinia virus complement-binding protein (VCP) is secreted from the cells infected with the virus and controls the complement activation reactions. This protein contains four short consensus repeats (SCR), typical of the protein family of complement activation regulators. Organization of the VCP genes/proteins of orthopoxviruses—monkeypox (MPV), variola, cowpox and vaccinia viruses—and their cellular homologues (DAF and C4BP) were studied comparatively. For this purpose, VCP genes of three MPV strains were sequenced. VCP gene sequences of other human-pathogenic orthopoxvirus species and strains determined earlier were involved in the analysis. It has been demonstrated that a premature termination of the MPV VCP open reading frame results in a truncated protein sequence carrying a deletion of the C-terminal SCR4. This is an essential distinction of MPV from other orthopoxvirus species.

Expression and regulation of complement factors H and I in rat and human cells: some critical notes

The complement factors I (FI) and H (FH) are complement regulatory proteins. FI, a highly glycosylated serine protease of 88 kDa cleaves the α-chains of both complement components C3b and C4b, thereby inactivating them. Complement FH, a glycoprotein of 150 kDa which is composed of 20 short consensus repeats synergizes with FI by increasing the affinity of FI for C3b in the C3b/FH complex by about 15-fold as compared to free C3b. Furthermore, FH prevents factor B from binding to C3b and promotes the dissociation of the C3bBb complex. Both, FI and FH are mainly synthesized in the liver. According to the quantification of specific mRNA of both factors, various amounts are produced by different liver cell types, i.e. hepatocytes (HC) and Kupffer cells (KC). Investigations of cultured primary HC and KC from rat liver showed that FI is exclusively synthesized and secreted by HC whereas FH is synthesized by both HC and KC. Using quantitative-competitive PCR for the quantification of FH-specific mRNA, its constitutive rate of synthesis was found to be nearly ten times higher in KC than in HC. An extrahepatic source of both proteins are human umbilical vein endothelial cells (HUVEC) in which the synthesis of FI is upregulated by IL-6 which is in accord with the upregulation observed in rat HC and two rat hepatoma cell lines (FAO and H4IIE). Three other proinflammatory cytokines, IL-1β, IFN-γ and TNF-α, were alone or in combination, without any effect on the regulation of FI. This demonstrates that the regulation of FI is similar in HUVEC and HC. These results are in contrast to a previously described IFN-γ-mediated upregulation of FI in HUVEC and suggest, in accordance with other investigations on extrahepatic sources of FI (e.g. myoblasts), that IFN-γ has probably no prominent role in the regulation of FI. Instead, IL-6 appears to be the main upregulating cytokine of FI mRNA and of FI protein synthesis in HC as well as in rat and human hepatoma cells and in HUVEC. Of note are experiments by others and us who could not identify FI-specific mRNA in peripheral blood-derived monocytes, granulocytes, or B- and T-cells of man or rat and in rat peritoneal macrophages. FI-specific mRNA could also not be detected in B- or T-cell lymphoma cells, whereas FH-specific mRNA was easily detectable in both human and rat monocytes, and in rat peritoneal macrophages. These data support the notion that FI in contrast to FH is not expressed by cells of the monocyte-macrophage lineage or by other leukocytes of peripheral blood, at least in the absence of additional stimulants.

Targeting of Functional Antibody-Decay-accelerating Factor Fusion Proteins to a Cell Surface

Recombinant soluble complement inhibitors hold promise for the treatment of inflammatory disease and disease states associated with transplantation. Targeting complement inhibitors to the site of complement activation and disease may enhance their efficacy and safety. Data presented show that targeting of decay-accelerating factor (DAF, an inhibitor of complement activation) to a cell surface by means of antibody fragments is feasible and that cell-targeted DAF provides significantly enhanced protection from complement deposition and lysis compared with soluble untargeted DAF. An extracellular region of DAF was joined to an antibody combining site with specificity for the hapten dansyl, at the end of either C(H)1 or C(H)3 Ig regions. The recombinant IgG-DAF chimeric proteins retained antigen specificity and bound to dansylated Chinese hamster ovary cells. Both soluble C(H)1-DAF and C(H)3-DAF were effective at inhibiting complement-mediated lysis of untargeted Chinese hamster ovary cells at molar concentrations within the range reported by others for soluble DAF. However, when targeted to a dansyl-labeled cell membrane, C(H)1-DAF was significantly more potent at inhibiting complement deposition and complement-mediated lysis. Cell-bound C(H)1-DAF also provided cells with protection from complement lysis after removal of unbound C(H)1-DAF. Of further importance, the insertion of a nonfunctional protein domain of DAF (the N-terminal short consensus repeat) between C(H)1 and the functional DAF domain increased activity of the fusion protein. In contrast to C(H)1-DAF, C(H)3-DAF was not significantly better at protecting targeted versus untargeted cells from complement, indicating that a small targeting vehicle is preferable to a large one. We have previously shown that for effective functioning of soluble complement inhibitor CD59, binding of CD59 to the cell surface close to the site of complement activation is required. Significantly, such a constraint did not apply for effective DAF function.

Complement Complex

Complement component C3d enhances the adaptive immune response to foreign antigens by simultaneously binding to the antigen and to complement receptor type 2 on B lymphocytes. Interaction with C3d requires the first two of 15 or 16 short consensus repeats (SCR) of CR2. Now Szakonyi et al. have determined the crystal structure of the SCR1 and SCR2 domains of human CR2 in complex with C3d at a resolution of 2.0 angstroms. The interface is between C3d and SCR2 and involves mostly main-chain interactions. The SCR domains form a V-shape with side-chain packing. This structure is likely to facilitate targeted drug design. G. Szakonyi, J. M. Guthridge, D. Li, K. Young, V. M. Holers, X. S. Chen, Structure of complement receptor 2 in complex with its C3d ligand. Science 292 , 1725-1728 (2001). [Abstract] [Full Text]

Structure of complement receptor 2 in complex with its C3d ligand.

Complement receptor 2 (CR2/CD21) is an important receptor that amplifies B lymphocyte activation by bridging the innate and adaptive immune systems. CR2 ligands include complement C3d and Epstein-Barr virus glycoprotein 350/220. We describe the x-ray structure of this CR2 domain in complex with C3d at 2.0 angstroms. The structure reveals extensive main chain interactions between C3d and only one short consensus repeat (SCR) of CR2 and substantial SCR side-side packing. These results provide a detailed understanding of receptor-ligand interactions in this protein family and reveal potential target sites for molecular drug design.

Molecular Analysis of the Epidermal Growth Factor-like Short Consensus Repeat Domain-mediated Protein-Protein Interactions: DISSECTION OF THE CD97-CD55 COMPLEX

Epidermal growth factor-like (EGF) and short consensus repeat (SCR) domains are commonly found in cell surface and soluble proteins that mediate specific protein-protein recognition events. Unlike the immunoglobulin (Ig) superfamily, very little is known about the general properties of intermolecular interactions encoded by these common modules, and in particular, how specificity of binding is achieved. We have dissected the binding of CD97 (a member of the EGF-TM7 family) to the complement regulator CD55, two cell surface modular proteins that contain EGF and SCR domains, respectively. We demonstrate that the interaction is mediated solely by these domains and is characterized by a low affinity (86 microm) and rapid off-rate (at least 0.6 s(-1)). The interaction is Ca(2+) -dependent but is unaffected by glycosylation of the EGF domains. Using biotinylated multimerized peptides in cell binding assays and surface plasmon resonance, we show that a CD97-related EGF-TM7 molecule (termed EMR2), differing by only three amino acids within the EGF domains, binds CD55 with a K(D) at least an order of magnitude weaker than that of CD97. These results suggest that low affinity cell-cell interactions may be a general feature of highly expressed cell surface proteins and that specificity of SCR-EGF binding can be finely tuned by a small number of amino acid changes on the EGF module surface.

Immune evasion of Borrelia burgdorferi by acquisition of human complement regulators FHL-1/reconectin and Factor H.

To understand immune evasion mechanisms of Borrelia burgdorferi we compared serum-resistant B. afzelii and serum-sensitive B. garinii isolates for their capacity toacquire human complement regulators. Here we demonstrate that the two borrelial genospecies show different binding of the two important human complement regulators, FHL-1/reconectin and Factor H. All serum-resistant B. afzelii isolates bound FHL-1/reconectin and also Factor H, and all analyzed serum-sensitive B. garinii isolates showed no or a significantly lower binding activity. Using recombinant deletion mutants, the binding domains were localized to the C terminus of FHL-1/reconectin to short consensus repeats 5-7. The borrelial binding proteins were located in the surface of the bacteria as demonstrated by immunofluorescence staining of intact, serum-exposed bacteria and by enrichment of outer membrane proteins. The surface-attached complement regulators maintained complement regulatory activity as demonstrated in a cofactor assay. By ligand blotting two different borrelial binding proteins were identified that were responsible for the surface attachment of FHL-1/reconectin and Factor H. These borrelial complement regulators acquiring surface proteins (CRASP) were further characterized as either CRASP-1, a 27.5-kDa molecule which preferentially binds FHL-1/reconectin and which was present in all serum-resistant borreliae, or CRASP-2, a 20/21-kDa protein which interacts preferentially with Factor H and the expression of which was more restricted, being detected in four of the six isolates analyzed. In summary, we describe a new immune evasion mechanism of B. burgdorferi, as these bacteria acquire human complement regulators to control complement activation on their surface and to prevent formation of toxic activation products.

A mutational analysis of the vaccinia virus B5R protein.

A mutational analysis of the vaccinia virus (VV) B5R protein is presented. This protein is related to the regulators of complement activation (RCA) superfamily, has four short consensus repeats (SCRs) that are typical of this superfamily and is present on extracellular enveloped virus (EEV) particles. Here we have constructed VV mutants in which the cytoplasmic tail (CT) of the B5R protein is progressively truncated, and domains of the B5R protein [the SCR (short consensus repeat) domains, the transmembrane anchor region or the CT] are substituted by corresponding domains from the VV haemagglutinin (HA), another EEV protein. Analysis of these mutant viruses showed that loss of the B5R CT did not affect the formation of intracellular enveloped virus (IEV), actin tails, EEV or virus plaque size. However, if the SCR domains of the B5R protein were replaced by the corresponding region of the HA, the virus plaque size was diminished, the formation of actin tails was decreased severely and the titre of infectious EEV released from cells was reduced approximately 25-fold compared to wild-type virus and 5-fold compared to a virus lacking the entire B5R gene. Thus the linkage of HA to the B5R transmembrane and CT is deleterious for the formation and release of EEV and for cell-to-cell virus spread. In contrast, deletion or substitution of the B5R CT did not affect virus replication, although the amount of cell surface B5R was reduced compared to control.

Characterization of factor H-related cell membrane molecules expressed by human B lymphocytes and neutrophil granulocytes

The human factor H protein family comprises six plasma glycoproteins. Earlier we described a membranal factor H-related (mFHR) molecule that is expressed by human B lymphoblastoid cell lines and exerts cofactor activity. In our present study we screened human blood cells for the presence of mFHR proteins and further characterized these molecules. By cytofluorimetry it is shown that the factor H-specific rabbit antiserum reacts strongly with B cells and neutrophil granulocytes, but not with T cells and monocytes. On B lymphocytes mFHR is shown to be down-regulated upon activation of the cells via sIg. In experiments studying which short consensus repeat (SCR) domains are part of the cell membrane proteins we found that antibodies raised against SCRs 1–4, 19–20 and FHR-3 bound to neutrophils but not to B cells. While mFHRs derived both from B cells and granulocytes are shown to bind heparin, their size and structure are different as revealed by Western blotting. A further characteristic of the granulocyte-derived mFHR is its sensitivity to the PI-specific PLCγ enzyme. These data demonstrate the existence of new members of the FHR protein family, as two distinct, membranal forms are identified. Based on the differences, the B cell derived molecule is termed mFHR-1 and the neutrophil derived protein mFHR-2.

Antibody binding to a conformation-dependent epitope induces L-selectin association with the detergent-resistant cytoskeleton.

L-Selectin mediates leukocyte rolling on endothelium and immobilized leukocytes. Its regulation has been the subject of much study, and the conformation of the molecule may play an important role in its function. Here we report that a conformational change in L-selectin, induced by an anti-lectin domain mAb (LAM1-116) and recognized by another mAb directed to a conserved epitope on L-selectin (EL-246), predisposed L-selectin to cytoskeletal association. This effect was due to direct binding of the mAb, not to overt signaling events, and was specific to LAM1-116. Nineteen other anti-L-selectin mAbs directed against the lectin, epidermal growth factor, or short consensus repeat domains lacked this activity. The induced conformational change occurred at 37 degrees C, at 4 degrees C, in the presence of sodium azide and tyrosine kinase inhibitors herbimycin A and genistein, and with soluble detergent-extracted L-selectin. In the presence of LAM1-116, EL-246 induced cytoskeletal association of L-selectin in the absence of Ab cross-linking as visualized by L-selectin staining after low dose detergent treatment of the cells. We propose that the conformational change described herein regulates L-selectin-mediated events by exposing a high avidity binding site that, when engaged, triggers association of L-selectin with the cytoskeleton, which may lead to stronger tethers with physiological ligands.

Human Factor H-related Protein 5 (FHR-5): A NEW COMPLEMENT-ASSOCIATED PROTEIN

A novel human plasma protein has been identified as a universal component of complement deposits, when complement is detected immunohistochemically in vivo. The protein is homologous to complement factor H and related proteins and has been designated factor H-related protein 5 (FHR-5). FHR-5 was identified by a monoclonal antibody raised using pathologic human glomerular preparations as the immunogen. FHR-5 was purified by affinity chromatography from complement-lysed erythrocytes, and the peptide sequence was obtained. The cDNA was cloned from a human liver library, and FHR-5 was deduced to be a protein containing 551 amino acids organized into nine short consensus repeat motifs. The short consensus repeats of FHR-5 show homology to Factor H and to other Factor H-related proteins, with some unique features demonstrated. Recombinant FHR-5, expressed in insect cells, was shown to bind C3b in vitro. The strong association of FHR-5 with tissue complement deposits in vivo suggests that this additional member of the Factor H family of proteins has a function in complement regulation.

Adhesion receptors on haematopoietic progenitor cells.

Adhesion receptors on haematopoietic progenitor cells.

The Complement Regulator Factor H Binds to the Surface Protein OspE of Borrelia burgdorferi

Spirochete bacteria of the Borrelia burgdorferi sensu lato complex cause Lyme borreliosis. The three pathogenic subspecies Borrelia garinii, Borrelia afzelii, and Borrelia burgdorferi sensu stricto differ in their disease profiles and susceptibility to complement lysis. We investigated whether complement resistance of Borreliae could be due to acquisition of the main soluble inhibitors of the alternative complement pathway, factor H and the factor H-like protein 1. When exposed to nonimmune EDTA-plasma, the serum-resistant B. afzelii and B. burgdorferi sensu stricto strains bound factor H/factor H-like protein 1 to their surfaces. Assays with radiolabeled proteins showed that factor H bound strongly to the B. burgdorferi sensu stricto strain. To identify factor H ligands on the borrelial surface, we analyzed a panel of outer surface proteins of B. burgdorferi sensu stricto with the surface plasmon resonance technique. The outer surface lipoprotein OspE was identified as a specific ligand for factor H. Using recombinant constructs of factor H, the binding site for OspE was localized to the C-terminal short consensus repeat domains 15-20. Specific binding of factor H to B. burgdorferi sensu stricto OspE may help the pathogen to evade complement attack and phagocytosis.

Antibody Neutralization of the Extracellular Enveloped Form of Vaccinia Virus

The extracellular enveloped form (EEV) of vaccinia virus (VV) is important for the long-range dissemination of the virus inside the host. Early work suggested that both IMV and EEV infectivity could be inhibited by antibodies, although two other studies reported that EEV was resistant to neutralization. Here, we readdressed this question, using four VV-immune antisera and their purified IgG, and showed that EEV infectivity can be inhibited by antibody produced from a live infection in plaque-reduction assays, although EEV is more resistant to neutralization by convalescent antibodies than is IMV. In parallel, indirect immunofluorescent staining and confocal microscopy showed that antibody aggregated EEV and prevented it from binding to cells. Using the IgG and Fab fragments prepared from this antiserum, we tested whether EEV made by VV mutants lacking genes A33R, A34R, A36R, A56R, B5R, F12L, or F13L can be inhibited in plaque-reduction assays. Although vΔB5R was slightly more resistant than other mutants, none of these mutants escaped neutralization completely, suggesting that multiple virus proteins are involved in the inhibition. Using an antibody specific to B5R protein and B5R mutants with consecutive short consensus repeat (SCR) domains deleted, the neutralization epitopes on B5R were mapped to within the SCR domain 1.