Identification and structural analysis of dimeric chicken complement component 3d and its binding with chicken complement receptor 2

Complement component 3d (C3d), the final cleavage product of complement component C3, interacts with CR2 and thus plays a crucial role in linking the innate and adaptive immune systems. Additionally, human C3d executes various functions in its dimeric form, which is more effective than its monomeric form. In this study, we aimed to explored whether chicken C3d (chC3d) exhibits similar characteristics, namely dimerization and binding of dimeric chC3d to chicken CR2 (chCR2). We investigated the interaction and co-localization of chC3d with itself using coimmunoprecipitation and confocal laser scanning microscopy, respectively. Then, dimeric chC3d was detected using native polyacrylamide gel electrophoresis and western blotting, and its equilibrium dissociation constant KD (827 nM) was determined using surface plasmon resonance. Finally, the interaction modes of dimeric chC3d were identified using molecular docking simulations, which revealed that dimeric chC3d could crosslink with chCR2 receptor. Overall, our findings will facilitate future explorations of the chicken complement system.

Rational Design of an Epstein-Barr Virus Vaccine Targeting the Receptor-Binding Site

Epstein-Barr virus (EBV) represents a major global health problem. Though it is associated with infectious mononucleosis and ∼200,000 cancers annually worldwide, a vaccine is not available. The major target of immunity is EBV glycoprotein 350/220 (gp350) that mediates attachment to B cells through complement receptor 2 (CR2/CD21). Here, we created self-assembling nanoparticles that displayed different domains of gp350 in a symmetric array. By focusing presentation of the CR2-binding domain on nanoparticles, potent neutralizing antibodies were elicited in mice and non-human primates. The structurally designed nanoparticle vaccine increased neutralization 10- to 100-fold compared to soluble gp350 by targeting a functionally conserved site of vulnerability, improving vaccine-induced protection in a mouse model. This rational approach to EBV vaccine design elicited potent neutralizing antibody responses by arrayed presentation of a conserved viral entry domain, a strategy that can be applied to other viruses.

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Self-assembling nanoparticles present the conserved gp350 receptor-binding domain

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The nanoparticles elicit more potent neutralizing antibodies than soluble gp350

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These neutralizing antibodies predominantly target the CR2-binding site on gp350

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The nanoparticles elicit potent neutralizing antibodies in mice and non-human primates

Biophysical investigations of complement receptor 2 (CD21 and CR2)-ligand interactions reveal amino acid contacts unique to each receptor-ligand pair

Human complement receptor type 2 (CR2 and CD21) is a cell membrane receptor, with 15 or 16 extracellular short consensus repeats (SCRs), that promotes B lymphocyte responses and bridges innate and acquired immunity. The most distally located SCRs, SCR1-2, mediate the interaction of CR2 with its four known ligands (C3d, EBV gp350, IFNalpha, and CD23). To ascertain specific interacting residues on CR2, we utilized NMR studies wherein gp350 and IFNalpha were titrated into (15)N-labeled SCR1-2, and chemical shift changes indicative of specific inter-molecular interactions were identified. With backbone assignments made, the chemical shift changes were mapped onto the crystal structure of SCR1-2. With regard to gp350, the binding region of CR2 is primarily focused on SCR1 and the inter-SCR linker, specifically residues Asn(11), Arg(13), Ala(22), Arg(28), Ser(32), Arg(36), Lys(41), Lys(57), Tyr(64), Lys(67), Tyr(68), Arg(83), Gly(84), and Arg(89). With regard to IFNalpha, the binding is similar to the CR2-C3d interaction with specific residues being Arg(13), Tyr(16), Arg(28), Ser(42), Lys(48), Lys(50), Tyr(68), Arg(83), Gly(84), and Arg(89). We also report thermodynamic properties of each ligand-receptor pair determined using isothermal titration calorimetry. The CR2-C3d interaction was characterized as a two-mode binding interaction with K(d) values of 0.13 and 160 microm, whereas the CR2-gp350 and CR2-IFNalpha interactions were characterized as single site binding events with affinities of 0.014 and 0.035 microm, respectively. The compilation of chemical binding maps suggests specific residues on CR2 that are uniquely important in each of these three binding interactions.

Mapping of the C3d ligand binding site on complement receptor 2 (CR2/CD21) using nuclear magnetic resonance and chemical shift analysis

Complement receptor 2 (CR2, CD21) is a cell membrane protein, with 15 or 16 extracellular short consensus repeats (SCRs), that promotes B lymphocyte responses and bridges innate and acquired immunity. The most distally located SCRs (SCR1-2) mediate the interaction of CR2 with its four known ligands (C3d, Epstein-Barr virus gp350, interferon-alpha, and CD23). Inhibitory monoclonal antibodies against SCR1-2 block binding of all ligands. To develop ligand-specific inhibitors that would also assist in identifying residues unique to each receptor-ligand interaction, phage were selected from randomly generated libraries by panning with recombinant SCR1-2, followed by specific ligand-driven elution. Derived peptides were tested by competition ELISA. One peptide, C3dp1 (APQHLSSQYSRT) exhibited ligand-specific inhibition at midmicromolar IC(50). C3d was titrated into (15)N-labeled SCR1-2, which revealed chemical shift changes indicative of specific intermolecular interactions. With backbone assignments made, the chemical shift changes were mapped onto the crystal structure of SCR1-2. With regard to C3d, the binding surface includes regions of SCR1, SCR2, and the inter-SCR linker, specifically residues Arg(13), Tyr(16), Arg(28), Tyr(29), Ser(32), Thr(34), Lys(48), Asp(56), Lys(57), Tyr(68), Arg(83), Gly(84), Asn(101), Asn(105), and Ser(109). SCR1 and SCR2 demonstrated distinct binding modes. The CR2 binding surface incorporating SCR1 is inconsistent with a previous x-ray CR2-C3d co-crystal analysis but consistent with mutagenesis, x-ray neutron scattering, and inhibitory monoclonal antibody epitope mapping. Titration with C3dp1 yielded chemical shift changes (Arg(13), Tyr(16), Thr(34), Lys(48), Asp(56), Lys(57), Tyr(68), Arg(83), Gly(84), Asn(105), and Ser(109)) overlapping with C3d, indicating that C3dp1 interacts at the same CR2 site as C3d.

Defining In Vivo Transcription Factor Complexes of the Murine CD21 and CD23 Genes

The expression of the CD21 and CD23 genes is coincident with differentiation from transition 1 B cells (T1) to transition 2 B cells (T2). To define constituents controlling CD21 and CD23 expression, we conducted chromatin immunoprecipitation analyses for candidate transcription factors. We found constitutive binding of Oct-1, NFAT species, YY1, NF-kappaB-p52, Pax5, E2A, and RBP-Jkappa to CD21 sequences and NF-kappaB-p52, Pax5, NFAT species, E2A, and RBP-Jkappa to CD23 promoter sequences. Splenic T and B cell subsets displayed constitutive binding of YY1, NF-kappaB-p52, Pax5, and Oct-1 proteins to CD21 sequences in B cells but no specific binding of NFATc3 or Pax5 in T cells. Similarly, CD23 sequences demonstrated constitutive binding of NF-kappaB-p52 in splenic T and B cells but only Pax5 in B cells. Of the various NFAT species, only a subset were found forming constitutive DNA/protein complexes with the CD21, CD23, and IL-2 gene sequences. Maturing B cells in the marrow possess stable Pax5 complexes on CD19, CD21, and CD23 gene promoters in the nuclei of such cells, even though only CD19 is expressed. The similarity of genetic controlling elements between the CD21 and CD23 genes does not suggest a mechanism for alternative regulation of these genes; however, separation of splenic B cell subsets into T1, T2, marginal zone (MZ), and mature follicular B cells, followed by quantitative RT-PCR, demonstrated the lack of appreciable CD23 transcripts in CD21(+) MZ cells. We propose an alternative derivation of MZ cells as maturing directly from T1 cells, leaving CD23 transcriptionally inactive in that lineage of cells.

Immunophysical exploration of C3d-CR2(CCP1-2) interaction using molecular dynamics and electrostatics

The formation of the complex between the d-fragment of the complement component C3 (C3d) and the modular complement receptor-2 (CR2) is important for cross-linking foreign antigens with surface-bound antibodies and C3d on the surface of B cells. The first two modules of CR2, complement control protein modules (CCPs), participate in non-bonded interactions with C3d. We have used computational methods to analyze the dynamic and electrostatic properties of the C3d-CR2(CCP1-2) complex. The interaction between C3d and CR2 is known to depend on pH and ionic strength. Also, the intermodular mobility of the CR2 modules has been questioned before. We performed a 10 ns molecular dynamics simulation to generate a relaxed structure from crystal packing effects for the C3d-CR2(CCP1-2) complex and to study the energetics of the C3d-CR2(CCP1-2) association. The MD simulation suggests a tendency for intermodular twisting in CR2(CCP1-2). We propose a two-step model for recognition and binding of C3d with CR2(CCP1-2), driven by long and short/medium-range electrostatic interactions. We have calculated the matrix of specific short/medium-range pairwise electrostatic free energies of interaction involved in binding and in intermodular communications. Electrostatic interactions may mediate allosteric effects important for C3d-CR2(CCP1-2) association. We present calculations for the pH and ionic strength-dependence of C3d-CR2(CCP1-2) ionization free energies, which are in overall agreement with experimental binding data. We show how comparison of the calculated and experimental data allows for the decomposition of the contributions of electrostatic from other effects in association. We critically compare predicted stabilities for several mutants of the C3d-CR2(CCP1-2) complex with the available experimental data for binding ability. Finally, we propose that CR2(CCP1-2) is capable of assuming a large array of intermodular topologies, ranging from closed V-shaped to open linear states, with similar recognition properties for C3d, but we cannot exclude an additional contact site with C3d.

A minimum CR2 binding domain of C3d enhances immunity following vaccination

The degradation product of the third (C3) complement component, C3d, links innate and adaptive immunity, and the covalent attachment of C3d to an antigen enhances antigen-specific immune responses. C3d has been hypothesized to enhance immunity by direct interaction with complement receptor 2 (CR2/CD21) on immune cells. However, the domains on C3d important for CR2 binding have been controversial, with various studies reaching contradictory conclusions. In addition, the concept of B-cell activation via CR2 by C3d has been questioned, since mice lacking CR2 still elicit C3d-enhanced immunity following vaccination. Therefore, the goal of this study was to determine if a peptide representing one of the proposed CR2 binding domains of C3d could substitute for the entire protein and enhance antigen-specific immunity. Mice (BALB/c) were vaccinated with the HIV-1 gp120 envelope glycoprotein (Env(gp120)) alone or fused to multiple copies of the murine C3d or a twenty-eight amino-acid peptide (P28) containing a minimum CR2 binding domain. Each immunogen was expressed from DNA plasmid in vivo or injected as purified recombinant protein. The fusion of the P28 peptide to Env(gp120) enhanced both humoral and cell-mediated immune responses with similar efficiency as Env(gp120) conjugated to C3d. The fusion of C3d or P28 to Env(gp120) elicited higher-titer anti-Env specific antibody, enhanced avidity maturation of the elicited antibody, and elicited higher numbers of IFN-gamma and IL-4 secreting cells compared to Env(gp120) immunizations. This CR2-binding domain specific 28 amino acid peptide can substitute for the entire C3d molecule and enhance immunity. These results indicate that the adjuvant properties of C3d are associated with CR2 interaction.

Internalization and molecular interactions of human CD21 receptor

The human CD21 is a receptor for cleavage fragments of the third complement component and for Epstein-Barr virus. Previous mutational studies showed that the cytoplasmic domain of CD21 is absolutely required for internalization of either ligand. With the exception of CD19, CD81, Leu-13 and CD35 that can form a complex with CD21 at the cell surface, no other partner that interacts with the hCD21 transmembrane or the cytoplasmic domain was identified. We investigated the internalization capacity of hCD21 tail mutants in the absence of B cell receptor cross-linking by using stable murine B cell transfectants. We provide evidence that at least two internalization motifs are activated when hCD21 binds a monoclonal antibody. In order to identify the cellular proteins that interact with the hCD21 transmembrane and cytoplasmic domains, we combined a mutational mapping with a two-hybrid system approach both in yeast and in mammalian cells. We identified four novel partners that are involved in intracellular trafficking, sorting or cytoskeleton remodeling and we mapped the hCD21 transmembrane and tail subdomains they interact with. We discuss the potential physiological significance of these findings in the context of hCD21 internalization and intracellular trafficking.

Structure of the Epstein-Barr virus major envelope glycoprotein

Epstein-Barr virus (EBV) infection of B cells is associated with lymphoma and other human cancers. EBV infection is initiated by the binding of the viral envelope glycoprotein (gp350) to the cell surface receptor CR2. We determined the X-ray structure of the highly glycosylated gp350 and defined the CR2 binding site on gp350. Polyglycans shield all but one surface of the gp350 polypeptide, and we demonstrate that this glycan-free surface is the receptor-binding site. Deglycosylated gp350 bound CR2 similarly to the glycosylated form, suggesting that glycosylation is not important for receptor binding. Structure-guided mutagenesis of the glycan-free surface disrupted receptor binding as well as binding by a gp350 monoclonal antibody, a known inhibitor of virus-receptor interactions. These results provide structural information for developing drugs and vaccines to prevent infection by EBV and related viruses.

The 15 SCR Flexible Extracellular Domains of Human Complement Receptor Type 2 can Mediate Multiple Ligand and Antigen Interactions

Complement receptor type 2 (CR2, CD21) is a cell surface protein that links the innate and adaptive immune response during the activation of B cells. The extracellular portion of CR2 comprises 15 or 16 short complement regulator (SCR) domains, for which the overall arrangement in solution is unknown. This was determined by constrained scattering and ultracentrifugation modelling. The radius of gyration of CR2 SCR 1-15 was determined to be 11.5 nm by both X-ray and neutron scattering, and that of its cross-section was 1.8 nm. The distance distribution function P(r) showed that the overall length of CR2 SCR 1-15 was 38 nm. Sedimentation equilibrium curve fits gave a mean molecular weight of 135,000 (+/- 13,000) Da, in agreement with a fully glycosylated structure. Velocity experiments using the g*(s) derivative method gave a sedimentation coefficient of 4.2 (+/- 0.1) S. In order to construct a model of CR2 SCR 1-15 for constrained fitting, homology models for the 15 SCR domains were combined with randomised linker peptides generated by molecular dynamics simulations. Using an automated procedure, the analysis of 15,000 possible CR2 SCR 1-15 models showed that only those models in which the 15 SCR domains were flexible but partially folded back accounted for the scattering and sedimentation data. The best-fit CR2 models provided a visual explanation for the versatile interaction of CR2 with four ligands C3d, CD23, gp350 and IFN-alpha. The flexible location of CR2 SCR 1-2 is likely to facilitate interactions of C3d-antigen complexes with the B cell receptor.

Characterization of human complement receptor type 2 (CR2/CD21) as a receptor for IFN-alpha: a potential role in systemic lupus erythematosus

Human complement receptor type 2 (CR2/CD21) is a B lymphocyte membrane glycoprotein that plays a central role in the immune responses to foreign Ags as well as the development of autoimmunity to nuclear Ags in systemic lupus erythematosus. In addition to these three well-characterized ligands, C3d/iC3b, EBV-gp350, and CD23, a previous study has identified CR2 as a potential receptor for IFN-alpha. IFN-alpha, a multifunctional cytokine important in the innate immune system, has recently been proposed to play a major pathogenic role in the development of systemic lupus erythematosus in humans and mice. In this study, we have shown using surface plasmon resonance and ELISA approaches that CR2 will bind IFN-alpha in the same affinity range as the other three well-characterized ligands studied in parallel. In addition, we show that IFN-alpha interacts with short consensus repeat domains 1 and 2 in a region that serves as the ligand binding site for C3d/iC3b, EBV-gp350, and CD23. Finally, we show that treatment of purified human peripheral blood B cells with the inhibitory anti-CR2 mAb 171 diminishes the induction of IFN-alpha-responsive genes. Thus, IFN-alpha represents a fourth class of extracellular ligands for CR2 and interacts with the same domain as the other three ligands. Defining the role of CR2 as compared with the well-characterized type 1 IFN-alpha receptor 1 and 2 in mediating innate immune and autoimmune roles of this cytokine should provide additional insights into the biologic roles of this interaction.

Redox regulation of CD21 shedding involves signaling via PKC and indicates the formation of a juxtamembrane stalk

Soluble CD21 (sCD21), released from the plasma membrane by proteolytic cleavage (shedding) of its extracellular domain (ectodomain) blocks B cell/follicular dendritic cell interaction and activates monocytes. We show here that both serine- and metalloproteases are involved in CD21 shedding. Using the oxidant pervanadate to mimic B cell receptor activation and thiol antioxidants such as N-acetylcysteine (NAC) and glutathione (GSH) we show that CD21 shedding is a redox-regulated process inducible by oxidation presumably through activation of a tyrosine kinase-mediated signal pathway involving protein kinase C (PKC), and by reducing agents that either directly activate the metalloprotease and/or modify intramolecular disulfide bridges within CD21 and thereby facilitate access to the cleavage site. Lack of short consensus repeat 16 (SCR16) abolishes CD21 shedding, and opening of the disulfide bridge between cys-2 (Cys941) and cys-4 (Cys968) of SCR16 is a prerequisite for CD21 shedding. Replacing these cysteines with selenocysteines (thereby changing the redox potential from -180 to -381 mV) results in a loss of inducible CD21 shedding, and removing this bridge by exchanging these cysteines with methionines increases CD21 shedding.

Extended flexible linker structures in the complement chimaeric conjugate CR2-Ig by scattering, analytical ultracentrifugation and constrained modelling: implications for function and therapy

Complement receptor 2 (CR2; CD21) is a membrane-bound regulator of complement activation, being comprised of 15 or 16 short complement repeat (SCR) domains. A recombinant glycosylated human CR2 SCR 1-2 domain pair was engineered with the Fc fragment of a mouse IgG1 antibody to create a chimaera CR2-Ig containing the major ligand binding domains. Such a chimaera has therapeutic potential as a complement inhibitor or immune modulator. X-ray and neutron scattering and analytical ultracentrifugation identified its domain structure in solution, and provided a comparison with controversial folded-back crystal structures for deglycosylated CR2 SCR 1-2. The radius of gyration R(G) of CR2-Ig was determined to be 5.39(+/-0.14) nm and 5.29(+/-0.01) nm by X-ray and neutron scattering, respectively. The maximum dimension of CR2-Ig was determined to be 17 nm. The molecular mass of CR2-Ig ranged between 101,000 Da and 107,000 Da as determined by neutron scattering and sedimentation equilibrium, in good agreement with the sequence-derived value of 106,600 Da. Sedimentation velocity gave a sedimentation coefficient of 4.49(+/-0.11) S. Stereochemically complete models for CR2-Ig were constructed from crystal structures for the CR2 SCR 1-2 and mouse IgG1 Fc fragments. The two SCR domains and the Fc fragment were joined by randomised conformational peptides. The analysis of 35,000 possible CR2-Ig models showed that only those models in which the two SCR domains were arranged in an open V-shape in random orientations about the Fc fragment accounted for the scattering and sedimentation data. It was not possible to define one single conformational family of Fab-like fragment relative to the Fc fragment. This flexibility is attributed to the relatively long linker sequence and the absence of the antibody light chain from CR2-Ig. The modelling also confirmed that the structure of CR2 SCR 1-2 is more extended in solution than in its crystal structure.

Solution structure of the complex between CR2 SCR 1-2 and C3d of human complement: an X-ray scattering and sedimentation modelling study

Complement receptor type 2 (CR2, CD21) forms a tight complex with C3d, a fragment of C3, the major complement component. Previous crystal structures of the C3d-CR2 SCR 1-2 complex and free CR2 SCR 1-2 showed that the two SCR domains of CR2 form contact with each other in a closed V-shaped structure. SCR 1 and SCR 2 are connected by an unusually long eight-residue linker peptide. Medium-resolution solution structures for CR2 SCR 1-2, C3d, and their complex were determined by X-ray scattering and analytical ultracentrifugation. CR2 SCR 1-2 is monomeric. For CR2 SCR 1-2, its radius of gyration R(G) of 2.12(+/-0.05) nm, its maximum length of 10nm and its sedimentation coefficient s20,w(o) of 1.40(+/-0.03) S do not agree with those calculated from the crystal structures, and instead suggest an open structure. Computer modelling of the CR2 SCR1-2 solution structure was based on the structural randomisation of the eight-residue linker peptide joining SCR 1 and SCR 2 to give 9950 trial models. Comparisons with the X-ray scattering curve indicated that the most favoured arrangements for the two SCR domains corresponded to an open V-shaped structure with no contacts between the SCR domains. For C3d, X-ray scattering and sedimentation velocity experiments showed that it exists as a monomer-dimer equilibrium with a dissociation constant of 40 microM. The X-ray scattering curve for monomeric C3d gave an R(G) value of 1.95 nm, and this together with its s20,w(o) value of 3.17 S gave good agreement with the monomeric C3d crystal structure. Modelling of the C3d dimer gave good agreements with its scattering and ultracentrifugation parameters. For the complex, scattering and ultracentrifugation experiments showed that there was no dimerisation, indicating that the C3d dimerisation site was located close to the CR2 SCR 1-2 binding site. The R(G) value of 2.44(+/-0.1) nm, its length of 9 nm and its s20,w(o) value of 3.45(+/-0.01) S showed that its structure was not much more elongated than that of C3d. Calculations with 9950 models of CR2 SCR 1-2 bound to C3d through SCR 2 showed that SCR 1 formed an open V-shaped structure with SCR 2 and was capable of interacting with the surface of C3d. We conclude that the open V-shaped structures formed by CR2 SCR 1-2, both when free and when bound to C3d, are optimal for the formation of a tight two-domain interaction with its ligand C3d.

Mutational analysis of the complement receptor type 2 (CR2/CD21)-C3d interaction reveals a putative charged SCR1 binding site for C3d

We have characterized the interaction between the first two short consensus repeats (SCR1-2) of complement receptor type 2 (CR2, CD21) and C3d in solution, by utilising the available crystal structures of free and C3d-bound forms of CR2 to create a series of informative mutations targeting specific areas of the CR2-C3d complex. Wild-type and mutant forms of CR2 were expressed on the surface of K562 erythroleukemia cells and their binding ability assessed using C3dg-biotin tetramers complexed to fluorochrome conjugated streptavidin and measured by flow cytometry. Mutations directed at the SCR2-C3d interface (R83A, R83E, G84Y) were found to strongly disrupt C3dg binding, supporting the conclusion that the SCR2 interface reflected in the crystal structure is correct. Previous epitope and peptide mapping studies have also indicated that the PILN11GR13IS sequence of the first inter-cysteine region of SCR1 is essential for the binding of iC3b. Mutations targeting residues within or in close spatial proximity to this area (N11A, N11E, R13A, R13E, Y16A, S32A, S32E), and a number of other positively charged residues located primarily on a contiguous face of SCR1 (R28A, R28E, R36A, R36E, K41A, K41E, K50A, K50E, K57A, K57E, K67A, K67E), have allowed us to reassess those regions on SCR1 that are essential for CR2-C3d binding. The nature of this interaction and the possibility of a direct SCR1-C3d association are discussed extensively. Finally, a D52N mutant was constructed introducing an N-glycosylation sequence at an area central to the CR2 dimer interface. This mutation was designed to disrupt the CR2-C3d interaction, either directly through steric inhibition, or indirectly through disruption of a physiological dimer. However, no difference in C3dg binding relative to wild-type CR2 could be observed for this mutant, suggesting that the dimer may only be found in the crystal form of CR2.

Complement receptors and the shaping of the natural antibody repertoire

Complement and complement receptors have been known for several decades to play important roles in immune effector mechanisms related to pathogen elimination and tissue inflammation. In addition, studies over the last 10 years have clearly demonstrated a key role for the complement C3d activation fragment receptor designated CR2 (complement receptor type 2) in the switched-isotype, high-affinity and memory humoral immune responses to T-dependent foreign antigens. More recent studies have extended those observations to include a key role for CR2 and C3d in the humoral immune response to T-independent foreign antigens. Conversely, as these studies have proceeded, a parallel series of analyses have linked defects in expression or function of complement C4 and other classical pathway activation pathway proteins, as well as CR2 and the closely related CR1, to the loss of self tolerance to nuclear antigens such as double-stranded DNA and chromatin in systemic lupus erythematosus. With regard to the topic of this issue, it is now becoming increasingly clear that CR2 also plays a major role in the development of the natural antibody repertoire. Specifically, in the absence of this receptor natural IgM and IgG develop in the naïve animal that demonstrate clearly altered recognition patterns for specific natural antibody targets. This repertoire change is important physiologically in at least one setting because these CR2-dependent natural antibodies are necessary for the recognition of ischemic self tissues. In addition, it is possible that certain of the phenotypes manifest by CR2-deficient mice may be strongly influenced not only by effects on later stages of B cell activation and maturation, as commonly thought, but also by alterations in the pre-existing pool of natural antibodies that are influenced by this receptor. This review will examine the evidence that has accumulated over the last few years supporting these hypotheses.

The electrostatic nature of C3d-complement receptor 2 association

The association of complement component C3d with B or T cell complement receptor 2 (CR2 or CD21) is a link between innate and adaptive immunity. It has been recognized in experimental studies that the C3d-CR2 association is pH- and ionic strength-dependent. This led us to perform electrostatic calculations to obtain a theoretical understanding of the mechanism of C3d-CR2 association. We used the crystallographic structures of human free C3d, free CR2 (short consensus repeat (SCR)1-2), and the C3d-CR2(SCR1-2) complex, and continuum solvent representation, to obtain a detailed atomic-level picture of the components of the two molecules that contribute to association. Based on the calculation of electrostatic potentials for the free and bound species and apparent pK(a) values for each ionizable residue, we show that C3d-CR2(SCR1-2) recognition is electrostatic in nature and involves not only the association interface, but also the whole molecules. Our results are in qualitative agreement with experimental data that measured the ionic strength and pH dependence of C3d-CR2 association. Also, our results for the native molecules and a number of theoretical mutants of C3d explain experimental mutagenesis studies of amino acid replacements away from the association interface that modulate binding of iC3b with full-length CR2. Finally, we discuss the packing of the two SCR domains. Overall, our data provide global and site-specific explanations of the physical causes that underlie the ionic strength dependence of C3d-CR2 association in a unified model that accounts for all experimental data, some of which were previously thought to be contradictory.

B cell signaling is regulated by induced palmitoylation of CD81

Signaling through the B cell antigen receptor (BCR) is amplified and prolonged by coligation of the BCR to the CD19/CD21/CD81 coreceptor complex. Coligation is induced during immune responses by the simultaneous binding of complement-tagged antigens to the complement receptor, CD21, and to the BCR. Enhanced signaling is due in part to the ability of the CD19/CD21/CD81 complex to stabilize the BCR in sphingolipid- and cholesterol-rich membrane microdomains termed lipid rafts. The tetraspanin CD81 is essential for the raft-stabilizing function of the coreceptor. Here we show that coligation of the BCR and the CD19/CD21/CD81 complex leads to selective, rapid, and reversible palmitoylation of CD81 and that palmitoylation is necessary for the raft stabilizing function of the CD19/CD21/CD81 complex. Inducible palmitoylation may represent a novel mechanism by which tetraspanins function to facilitate lipid raft-dependent receptor signaling.

EBV attachment stimulates FHOS/FHOD1 redistribution and co-aggregation with CD21: formin interactions with the cytoplasmic domain of human CD21

CD21 is a multifunctional receptor for Epstein-Barr virus (EBV), for C3dg and for CD23. Upon engagement of immune complexes CD21 modulates immunoreceptor signaling, linking innate and adaptive immune responses. The mechanisms enabling CD21 to independently relay information between the exterior and interior of the cell, however, remain unresolved. We show that formin homologue overexpressed in spleen (FHOS/FHOD1) binds the cytoplasmic domain of human CD21 through its C terminus. When expressed in cells, EGFP-FHOS localizes to the cytoplasm and accumulates with actin in membrane protrusions. Plasma membrane aggregation, redistribution and co-localization of both proteins are stimulated when EBV (ligand) binds CD21. Though widely expressed, FHOS RNA is most abundant in the littoral cell, a major constituent of the red pulp of human spleen believed to function in antigen filtration. Formins are molecular scaffolds that nucleate actin by a pathway distinct from Arp2/3 complex, linking signal transduction to actin reorganization and gene transcription. Thus, ligand stimulation of FHOS-CD21 interaction may transmit signals through promotion of cytoskeletal rearrangement. Moreover, formin recruitment to sites of actin assembly initiated by immunoreceptors could be a general mechanism whereby co-receptors such as CD21 modulate intracellular signaling.

Complement receptor 2 and autoimmunity

Complement receptor 2 (CR2/CD21) plays a major role in the immune response by linking innate and adaptive immunity to foreign pathogens and proteins. In addition, several lines of evidence strongly support a role for CR2 in the maintenance of tolerance to self-antigens. Both the absence of CR2 expression (along with the alternatively spliced gene product CR1) and the presence of a dysfunctional CR2 protein are tightly associated with the development of autoreactivity to nuclear antigens. Altered levels of expression of CR2 in patients with systemic lupus erythematosus support a clinically relevant role for this phenotype. Several possible mechanisms could underlie the loss of self-tolerance related to CR2, but the effect is most likely related to the failure of one or more specific checkpoints that limit autoreactivity during B cell development and immune reactions.

B cell activation leads to shedding of complement receptor type II (CR2/CD21)

Complement receptor type II (CR2/CD21) is the major receptor for C3d fragments on immune complexes. CD21 also serves as the receptor for Epstein-Barr virus in humans. On mature B cells, CD21 reduces the threshold of BCR signaling together with CD81, Leu13 and CD19, but it also occurs on other cells of the immune system where it performs unknown functions. A soluble form of CD21 (sCD21) is shed from the cell surface and is found in human blood plasma. An as-yet-unknown protease is thought to be responsible for this shedding. Altered levels of sCD21 occur in plasma in certain clinical conditions. We show here by mass spectrometry that sCD21 in human plasma of healthy donors is predominantly a short form of CD21 without the exon-11-encoded sequences. Whereas the N terminus of sCD21 was found unmodified, the C terminus is truncated, implying that only the extracellular portion of CD21 is shed. Peripheral blood B cells, but not T cells, contribute to the plasma CD21-pool. CD21 shedding is induced by stimulation with PMA plus Ca(2+) ionophore, or by stimulation of the BCR with anti-IgM+anti-CD40.

CR2 units of CR2 complexes are possibly associated with nucleophilic agents through reactive covalent links

The human complement receptor type 2 (CR2/CD21), a transmembrane glycoprotein, associates with a variety of surface antigens and proteins in the cell membrane. We examined the possibilities that the CR2 units of CR2 complexes are associated through internal covalent links reactive with nucleophilic agents, e.g. H(2)O or methylamine, and that CR2-positive cells process anti-CR2 monoclonal antibodies (MoAbs). Data from immunoblotting and cytofluorimetry with CR2-binding site-specific MoAbs show that: (i) CR2-positive Raji cells release soluble CR2 isoforms into the medium when incubated in phosphate buffered saline; (ii) despite affecting the detection of one soluble CR2 isoform, methylamine treatment of soluble CR2 allows the detection of another of its isoforms; (iii) limited pre-treatment of cells with methylamine reveals a more heterogeneous CR2-positive cell population or enhances the detection of CR2; (iv) cell treatment with CR2-binding site-specific MoAbs enhances the detection of CR2 isoform(s). The data suggest that CR2 is shed mainly as a soluble CR2 complex, in which the CR2 units link covalently and react with nucleophilic agents. Raji cells may process bound fragments (145 kDa) that are recognised by and become bound by anti-CR2 MoAb.

Structure of complement receptor (CR) 2 and CR2-C3d complexes

Using X-ray crystallography, we have determined the structure of the first two short consensus repeats (SCRs) of human complement receptor (CR) 2 in complex with C3d. These studies revealed: (i) a primary site of interaction for C3d within SCR2 of CR2, (ii) a hydrophobic patch holding SCR1 to SCR2 in a rigid V-shape, (iii) a dimer formed by interactions between SCR1 of each molecule, (iv) several non-linear sequences on C3d that interact with CR2 and (v) mutations of C3d amino acids within the co-crystal interface that resulted in decreased binding. In addition, a polymorphism that results in decreased C3d binding and introduces a new glycosylation site predicted to disrupt the dimer interface was found in the New Zealand White autoimmune mouse strain. Although the co-crystal complex results are in agreement with a subset of prior studies, our additional findings, which demonstrate an extended SCR1-SCR2 structure in solution and differences in the kinetics of ligand-receptor interactions with longer forms of CR2, have suggested a more complex receptor-ligand interaction. To characterize this interaction further, several approaches directed at the determination of solution phase interactions as well as the analysis of the three-dimensional structure of CR2 alone and key CR2 mutants will be necessary.

The crystal structure of human CD21: Implications for Epstein-Barr virus and C3d binding

Human complement receptor type 2 (CD21) is the cellular receptor for Epstein-Barr virus (EBV), a human tumor virus. The N-terminal two short consensus repeats (SCR1-SCR2) of the receptor interact with the EBV glycoprotein gp350/220 and also with the natural CD21 ligand C3d. Here we present the crystal structure of the CD21 SCR1-SCR2 fragment in the absence of ligand and demonstrate that it is able to bind EBV. Based on a functional analysis of wild-type and mutant CD21 and molecular modeling, we identify a likely region for EBV attachment and demonstrate that this region is not involved in the interaction with C3d. A comparison with the previously determined structure of CD21 SCR1-SCR2 in complex with C3d shows that, in both cases, CD21 assumes compact V-shaped conformations. However, our analysis reveals a surprising degree of flexibility at the SCR1-SCR2 interface, suggesting interactions between the two domains are not specific. We present evidence that the V-shaped conformation is induced by deglycosylation of the protein, and that physiologic glycosylation of CD21 would result in a more extended conformation, perhaps with additional epitopes for C3d binding.

CD19, CD21, and CD22: multifaceted response regulators of B lymphocyte signal transduction

B lymphocyte development and function depend upon the activity of intrinsic and B cell antigen receptor (BCR)-induced signals. These signals are interpreted, amplified, fine-tuned, or suppressed through the precise actions of specialized cell surface coreceptors, or "response regulators," that inform B cells of their extracellular environment. Important cell surface response regulators include the CD19/CD21 complex, CD22, and CD72. CD19 establishes a novel Src-family protein tyrosine kinase (PTK) amplification loop that regulates basal signaling thresholds and intensifies Src-family PTK activation following BCR ligation. In turn, CD22 limits the intensity of CD19-dependent, BCR-generated signals through the recruitment of potent phosphotyrosine and phosphoinositide phosphatases. Herein we discuss our current understanding of how CD19/CD21 and CD22 govern the emergence and intensity of BCR-mediated signals, and how alterations in these tightly controlled regulatory activities contribute to autoimmunity in mice and humans.

Epitope mapping using the X-ray crystallographic structure of complement receptor type 2 (CR2)/CD21: identification of a highly inhibitory monoclonal antibody that directly recognizes the CR2-C3d interface

Complement receptor type 2 (CR2)/CD21 is a B lymphocyte cell membrane C3d/iC3b receptor that plays a central role in the immune response. Human CR2 is also the receptor for the EBV viral membrane glycoprotein gp350/220. Both C3d and gp350/220 bind CR2 within the first two of 15-16 repetitive domains that have been designated short consensus/complement repeats. Many mAbs react with human CR2; however, only one currently available mAb is known to block both C3d/iC3b and gp350/220 binding. We have used a recombinant form of human CR2 containing the short consensus/complement repeat 1-2 ligand-binding fragment to immunize Cr2(-/-) mice. Following fusion, we identified and further characterized four new anti-CR2 mAbs that recognize this fragment. Three of these inhibited binding of CR2 to C3d and gp350/220 in different forms. We have determined the relative inhibitory ability of the four mAbs to block ligand binding, and we have used overlapping peptide-based approaches to identify linear epitopes recognized by the inhibitory mAbs. Placement of these epitopes on the recently solved crystal structure of the CR2-C3d complex reveals that each inhibitory mAb recognizes a site either within or adjacent to the CR2-C3d contact site. One new mAb, designated 171, blocks CR2 receptor-ligand interactions with the greatest efficiency and recognizes a portion of the C3d contact site on CR2. Thus, we have created an anti-human CR2 mAb that blocks the C3d ligand by direct contact with its interaction site, and we have provided confirmatory evidence that the C3d binding site seen in its crystal structure exists in solution.

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.

Structural Studies in Solution of the Recombinant N-Terminal Pair of Short Consensus/Complement Repeat Domains of Complement Receptor Type 2 (CR2/CD21) and Interactions with Its Ligand C3dg

Human complement receptor type 2 (CR2, CD21) is a cell surface receptor that binds three distinct ligands (complement C3d, Epstein-Barr virus gp350/220, and the low-affinity IgE receptor CD23) via the N-terminal two of fifteen or sixteen short consensus/complement repeat (SCR) domains. Here, we report biophysical studies of the CR2 SCR 1-2 domain binding to its ligand C3dg. Two recombinant forms of CR2 containing the SCR 1-2 and SCR 1-15 domains were expressed in high yield in Pichia pastoris and baculovirus, respectively. Circular dichroism spectroscopy showed that CR2 SCR 1-2 receptor possessed a beta-sheet secondary structure with a melting temperature of 59 degrees C. Using surface plasmon resonance, kinetic parameters for the binding of either CR2 SCR 1-2 or the full-length SCR 1-15 form of CR2 showed that the affinity of binding to immobilized C3d is comparable for the SCR 1-15 compared to the SCR 1-2 form of CR2. Unexpectedly, both the association and dissociation rates for the SCR 1-15 form were slower than for the SCR 1-2 form. These data show that the SCR 1-2 domains account for the primary C3dg binding site of CR2 and that the additional SCR domains of full-length CR2 influence the ability of CR2 SCR 1-2 to interact with its ligand. Studies of the pH and ionic strength dependence of the interaction between SCR 1-2 and C3d by surface plasmon resonance showed that this is influenced by charged interactions, possibly involving the sole His residue in CR2 SCR 1-2. Sedimentation equilibrium studies of CR2 SCR 1-2 gave molecular weights of 17 000, in good agreement with its sequence-derived molecular weight to show that this was monomeric. Its sedimentation coefficient was determined to be 1.36 S. The complex with C3d gave molecular weights in 50 mM and 200 mM NaCl buffer that agreed closely with its sequence-derived molecular weight of 50 600 and showed that a 1:1 complex had been formed. Molecular graphics views of homology models for the separate CR2 SCR 1 and SCR 2 domains showed that both SCR domains exhibited a distribution of charged groups throughout its surface. The single His residue is located near a long eight-residue linker between the two SCR domains and may influence the linker conformation and the association of C3d and CR2 SCR 1-2 into their complex. Sedimentation modeling showed that the arrangement of the two SCR domains in CR2 SCR 1-2 is highly extended in solution.

Structure and flexibility of the multiple domain proteins that regulate complement activation

In this review we summarise more than 10 years of biophysical exploration into the structural biology of the regulators of complement activation (RCA). The five human proteins responsible for regulation of the early events of complement are homologous and are composed largely from building blocks called "complement control protein (CCP) modules". Unlike most multiple domain proteins they do not contain any of the other widely occurring module types. This apparent simplicity of RCA structure, however, is belied by their sophistication of function. In fact, the structures of the individual CCP modules exhibit wide variations on a common theme while the extent and nature of intermodular connections is diverse. Some neighbouring modules within a protein stabilise each other and some co-operate to form specific binding surfaces. The degree of true "modularity" of CCPs is open to debate. The study of RCA proteins clearly illustrates the value of combining complementary structural biology techniques. The results could have implications for folding, evolution, flexibility and structure-function relationships of other molecules in the large, diverse and little understood category of multiple domain proteins.

The CD19/CD21 complex functions to prolong B cell antigen receptor signaling from lipid rafts

The CD19/CD21 complex functions to significantly enhance B cell antigen receptor (BCR) signaling in response to complement-tagged antigens. Recent studies showed that following antigen binding the BCR translocates into plasma membrane lipid rafts that serve as platforms for BCR signaling. Here, we show that the binding of complement-tagged antigens stimulates the translocation of both the BCR and the CD19/CD21 complex into lipid rafts, resulting in prolonged residency in and signaling from the rafts, as compared to BCR cross-linking alone. When coligated to the BCR, the CD19/CD21 complex retards the internalization and degradation of the BCR. The colocalization and stabilization of the BCR and the CD19/CD21 complex in plasma membrane lipid rafts represents a novel mechanism by which a coreceptor enhances BCR signaling.

Immunomodulatory functions of murine CR1/2

C3-fragments generated upon complement activation play an important role in the formation and regulation of immune responses. Receptors interacting with various activation fragments of this versatile complement component are expressed on a wide variety of cell types, such as lymphocytes, macrophages, dendritic cells, follicular dendritic cells, granulocytes, erythrocytes, consequently C3-products may influence several biological functions at different sites of the body, where complement activation takes place. In the last decade, genes, protein structure and functions played by murine complement receptors CR1 and CR2 (mCR1/2) have been deciphered. In this review, we wish to relate these properties, and fit it into the context of events following in vivo complement activation. We separately address the roles played by murine mCR1/2 as BCR coreceptor and as BCR independent structure, and propose a mchanism for the utilization of antigen-C3d conjugates bound on B cells. Finally, we raise some of the questions that remain to be elucidated in order to get a more precise picture of the functions of mCR1/2.

Structure and expression of ovine complement receptor type 2

The structure of sheep complement receptor type 2 (CR2) was characterised by cDNA cloning, protein sequencing and immunoprecipitation. The primary structure of sheep CR2 is similar to known mammalian homologues but the higher-order structure is unusual. Two distinct CR2 isoforms occur, one of which is ubiquitinated in the cytoplasmic domain, and the two molecular forms are expressed at the cell surface as non-covalently associated dimers. The percentage of sheep B-cells that express CR2 changes during development and varies between different body compartments. CR2+ and CR2 B-cell subsets also differ in the expression of other surface markers and in functional properties. Differential expression of CR2 may, therefore, delineate B-cells that arose by alternative developmental pathways, or it could be a marker for B-cells at different phases of antigen exposure.

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.

Complement receptor type two (CR2,CR21): a target for influencing the humoral immune response and antigen-trapping

Cellular receptors for complement C3 fragments deposited on antigens are important bricks in the wall defending against microbial pathogens. The part of complement receptor type 2 (CR2; CD21) deals with enhancing humoral immune responses and with long-term trapping of C3d-coated antigen by follicular dendritic cells. CR2 is also pivotal for Epstein-Barr virus (EBV) infection. Here, the current understanding, how CR2 interacts with its ligands C3d, EBV, and CD23 is summarized. The potential to target CR2 for clinical therapy or immunization purposes are discussed.

Characterization of C3dg binding to a recess formed between short consensus repeats 1 and 2 of complement receptor type 2 (CR2; CD21)

To allow for a better characterization of the ligand binding structures of human complement receptor type 2 (CR2; CD21), we have established an IgG1 kappa mouse mAb, FE8, that interferes efficiently with binding of C3dg and EBV to CR2. In contrast to mAb OKB7, the only well-characterized mAb with similar specificity, mAb FE8 blocked binding of soluble C3dg or particles carrying multiple copies of surface-bound C3dg to CR2 or induced complete removal of these ligands from the receptor. In vitro EBV infection of B lymphocytes, on the other hand, was abrogated by mAbs FE8 and OKB7 with similar dose-response characteristics. As FE8 was shown to recognize a discontinuous epitope, a series of overlapping peptides derived from SCR1 and -2 and immobilized on cellulose was screened with FE8. The results suggest that up to five discontinuous sequences contributed to the epitope. The sequence 63-EYFNKYS-69, located between the two SCR units, reacted most intensively. Two other sequences, 16-YYSTPI-21 and 105-NGNKSVWCQANN-116, are located between Cys1 and Cys2 of SCR1 and around Cys3 of SCR2, respectively. Based on the solution structure for two factor H SCRs, a three-dimensional model of SCR1 and -2 was generated. The FE8 binding peptide sequences were located in relative proximity to each other, bounding the recess formed between SCR1 and -2. This potential of mAb FE8 is currently unique and may be exploited for interfering with conditions of unwanted recognition of C3dg-coated structures by the immune system.

Angiomyoid and follicular dendritic cell proliferative lesions in Castleman's disease of hyaline-vascular type: a study of 10 cases

Castleman's disease of hyaline-vascular type (HV CD) may rarely be associated with a confusing variety of stromal cell overgrowths and neoplasms. We report here on the pathologic and clinical findings of 10 such cases. In addition to the usual complex histoimmunophenotype of the stroma of HV CD and some unusual features that mimicked neoplasms, we observed focal proliferations of angiomyoid (five cases) and follicular dendritic cell type (five cases). The former were nonneoplastic growths featuring compact tangles of spindle cells, exhibiting immunoreactivity for smooth muscle actin and interpreted as vessel-related pericytes and myoid cells. The latter were neoplastic growths of oval to spindle cells intermixed with lymphocytes; the tumor cells grew in long, intersecting bundles, featured various degree of atypia, and expressed the markers of follicular dendritic cells (CD21, CD35, KiM4p). The two types were clinically distinct. Four of five patients with angiomyoid proliferations were young women, who presented with an abdominal mass and were cured by surgery; that is, they had a clinical profile similar to that of patients with the stroma-rich variant of HV CD. The follicular dendritic cell proliferations were in older patients of either gender presenting with masses at various sites, recapitulating the profile of follicular dendritic cell tumors arising independently from HV CD; in three patients with long-term follow-up, recurrences or metastases developed at various intervals from the initial diagnosis (1 1/6, 3 1/2, and 11 years), and one patient died as a result. This study confirms the potential for, and the variety of, stromal cell proliferations in HV CD. Because their biologic behavior differs, correct identification of these various proliferative lesions is clinically important.

Pep34, a synthetic peptide whose sequence corresponds to the intracytoplasmic domain of the Epstein-Barr virus receptor (CR2, CD21), regulates human B lymphocyte proliferation triggered through CR2

CR2 is involved in regulation of human B lymphocyte proliferation by interacting, through distinct domains, with extracellular, cell surface or intracellular components. Contribution of CR2 intracytoplasmic domain in CR2 regulatory functions remains unclear. Thus, we used pep34, a 34 amino acid synthetic peptide whose sequence corresponds to CR2 intracytoplasmic domain. Pep34 was incorporated into B lymphocytes which were then activated by EBV or C3d through CR2. Our data demonstrate that pep34 inhibits 100% B lymphocyte proliferation triggered by EBV or C3d. Irrelevant peptide had no effect. When B lymphocyte proliferation was triggered by a multipotent B cell activator as SAC, pep34 did not exert any inhibitory effect. Our data demonstrate that pep34 inhibits B lymphocyte proliferation only when lymphocytes are triggered through CR2. Thus, this strongly supports that despite its short length. CR2 intracytoplasmic domain participates to regulatory functions of this receptor.

Characterization of rat complement receptors and regulatory proteins. CR2 and Crry are conserved, and the C3b receptor of neutrophils and platelets is distinct from CR1

In the mouse, CR1 and CR2 on B lymphocytes are encoded by alternatively spliced Cr2 gene transcripts. Immune adherence receptors that bind C3b are present on mouse platelets and unstimulated neutrophils, but they are not CR1. In this study, rabbit anti-mouse CR1/CR2 Ab immunoprecipitated a 145- to 150-kDa CR2 protein from rat platelets, neutrophils, and splenocytes, but not a approximately 200-kDa CR1 protein. By Northern analysis, cDNA for mouse CR2 hybridized to mRNA of 3.7 and 5.2 kb from both mouse and rat splenocytes. The murine decay-accelerating factor and membrane cofactor protein analogue Crry was present in rat platelets, neutrophils, E, and splenocytes as two distinct proteins of 65 to 70 kDa and 75 to 85 kDa. Rat platelets, neutrophils, and splenocytes contained a novel 200-kDa cell membrane protein that specifically bound to a rat C3b-Sepharose column. We have named this protein C3bR-200. C3bR-200 was not identified by anti-mouse CR1/CR2 or anti-human CR1 Ab. Rat E lacked C3bR-200. Rat neutrophils and splenocytes also contained an 80-kDa C3b-binding protein that was distinct from Crry, which we have named C3bR-80. Therefore, CR2 and Crry are present in the rat, and have similar qualities to those from the mouse, except that CR2 is located on rat platelets and neutrophils, which is not the case in the mouse. Rat platelets, neutrophils, and splenocytes have a 200-kDa C3b-binding protein, C3bR-200, that is likely to be the rodent immune adherence receptor.

Characterization of a complement receptor 2 (CR2, CD21) ligand binding site for C3. An initial model of ligand interaction with two linked short consensus repeat modules

Human CR2 (CD21, EBV receptor) is an approximately 145-kDa receptor and a member of the regulators of complement activation gene family. Regulators of complement activation proteins are characterized by the presence of repeating motifs of 60 to 70 amino acids that are designated short consensus repeats (SCR). CR2 serves as a receptor for four distinct ligands. Three of these ligands (complement C3, gp350/220 of EBV, and CD23) interact with the amino terminal 2 of 16 SCR (SCR 1 and 2). Previous studies have determined that at least four sites are important in allowing CR2 to efficiently bind EBV. Two of these sites are also important for binding mAb OKB7, a reagent that blocks both EBV and iC3b/C3dg binding to CR2. We have identified and characterized important sites of iC3b ligand binding by utilizing human-mouse CR2 chimeras, a rat anti-mouse CR2 mAb designated 4E3 that blocks receptor binding to C3, and human CR2-derived peptides. In addition to demonstrating an important role for the same sequence in SCR 1 that is part of the mAb OKB7 and EBV binding site, we have identified a new region within SCR 2 that interacts with C3. These results, when compared with a model of a dual SCR solution structure derived from human factor H SCR, predict that two distinct largely surface-exposed sites on CR2 interact with iC3b. A relative twist of 130 degrees about the long axis of the second SCR in this model would be necessary for these sites to form a single patch for iC3b binding on CR2.

Analysis of C3b/C3d binding sites and factor I cofactor regions within mouse complement receptors 1 and 2

Human and murine CR1 and CR2 are defined as evolutionary homologues on the basis of their in vitro activities and a shared structural motif known as a short consensus repeat (SCR). To identify additional similarities between the two species, we analyzed the functional domains within the mouse receptors by constructing mouse-human chimeric cDNAs in which the C3 binding site of human CR2 has been replaced by different regions within the first eight SCRs of mouse CR1. Rosette analysis of cells expressing chimeric proteins, with erythrocytes bearing different mouse C3 fragments, coupled with rosette inhibition studies using specific anti-mouse CR1/CR2 mAbs reveal a weak C3b binding site within SCRs 1 and 2 of mouse CR1. There is no independent C3b interacting domain within SCRs 3 to 6, but their presence enhances C3 binding. A molecule that contains only the first six SCRs of mouse CR1 also binds C3b, but with less efficiency. There is no C3d binding area within the first six SCRs, but our data confirms previous studies indicating an additional C3b/C3d binding region within SCRs 7 and 8 of mouse CR1 (SCRs 1-2 of mouse CR2). The presence of SCRs 1 to 4 is required for C3 cofactor activity. 8C12, a mAb which blocks C3b erythrocyte rosette binding and the C3 cofactor activity of mouse CR1, binds only to chimeras containing SCRs 3 to 4.(ABSTRACT TRUNCATED AT 250 WORDS)

CD23 interacts with a new functional extracytoplasmic domain involving N-linked oligosaccharides on CD21

Human CD21 has been described as a receptor for the C3d,g and iC3b proteins of complement, for the Epstein-Barr virus, and also for IFN-alpha. We reported recently that CD23, a low affinity receptor for IgE (Fc epsilon R2), is a new functional ligand for CD21. To determine the site of interaction of CD23 on CD21, we analyzed the ability of purified recombinant CD23 incorporated into fluorescent liposomes to bind CD21 mutants bearing various deletions of extracytoplasmic short consensus repeats (SCRs). We found that the site of interaction of CD23 on CD21 is on SCRs 5 to 8, with contribution of SCRs 1 and 2. Tunicamycin treatment of CD21-transfected K562 cells strongly inhibited the binding of CD23-liposomes, suggesting that an N-linked sugar, present on SCRs 5 to 8, is involved in the CD23/CD21 interaction. By mutating together or individually, the three asparagines present on SCRs 5 to 8, asparagines (Asn) 370 and 295, but not Asn 492, were shown to be involved critically in the binding of CD23. Furthermore, we mapped the binding sites of a panel of anti-CD21 mAbs and found that at least six epitopes can be detected on CD21. The mAbs that inhibit the most CD23 binding to CD21 map in SCRs 5 to 8. This study indicates that SCRs 5 to 8 represent a novel functional domain on the CD21 molecule, and is the first demonstration of an activity of an extracytoplasmic region of the CD21 outside of SCRs 1 to 4.

The human IgE network

IgE and its receptors are believed to have evolved as a mechanism to protect mammals against parasites. But other and intrinsically innocuous antigens can subvert this system to provoke an allergic response. For human populations in industrialized countries, allergy and asthma now represent a far greater threat than parasitic infection, and the main impetus for current studies of the IgE system is the hope of understanding and intervening in the aetiology of allergic diseases.

Properties of soluble CR2 in human serum

A soluble form of complement receptor number 2 (sCR2) found in human serum closely resembles that produced in culture by B lymphoblastoid cells. Epitope analysis with a panel of CD21 monoclonal antibodies revealed only minor differences between antigen from the two sources. Purified sCR2 from both sources bound to C3dg prepared from human or mouse serum and to u.v.-inactivated Epstein-Barr virus. SDS-PAGE analysis of culture supernates of B-lymphoid cells labelled by growth in medium containing 35S-methionine revealed a major component of molecular weight approximately 130 kDa and another band at 30 kDa. Incubation with endoglycosidase F reduced the size of the high molecular weight component. Gel filtration of untreated serum or culture supernate revealed that, in its native state, sCR2 behaved as a molecule or complex of apparent molecular weight 320 kDa. Possible explanations are discussed.