Anne Nicholson-Weller

Complement Receptor Type 1 (CR1, CD35) Is a Receptor for C1q

Molecular definition of the cellular receptor for the collagen domain of C1q has been elusive. We now report that C1q binds specifically to human CR1 (CD35), the leukocyte C3b/C4b receptor, and the receptor on erythrocytes for opsonized immune complexes. Biotinylated or radioiodinated C1q (*C1q) bound specifically to transfected K562 cells expressing cell surface CR1 and to immobilized recombinant soluble CR1 (rsCR1). *C1q binding to rsCR1 was completely inhibited by unlabeled C1q and the collagen domain of C1q and was partially inhibited by C3b dimers. Kinetic analysis in physiologic saline of the interaction of unlabeled C1q with immobilized rsCR1 using surface plasmon resonance yielded an apparent equilibrium dissociation constant (K[eq2]) of 3.9 nM. Thus, CR1 is a cellular C1q receptor that recognizes all three complement opsonins, namely, C1q, C3b, and C4b.

Membrane signaling by complement C5b-9, the membrane attack complex

The terminal complement complexes C5b-7, C5b-8 and C5b-9 are able to generate nonlethal cell signals. One universal consequence of a cell being targeted by C5b-8 or C5b-9 is an influx of Ca2+. In addition, other second messengers, including cAMP, inositol phosphate intermediates and arachidonate metabolites, are generated by the terminal complement complexes in specific cell types. In vivo, terminal complement complexes have been found in a wide variety of inflammatory processes in humans and in experimental animal models. Some of these models of inflammation putatively induced by terminal complement complexes have been tested in complement-deficient animals, and indeed no inflammation results, which supports the critical role of the terminal complement complexes in the pathogenesis of the lesion.

Deficiency of the complement regulatory protein, "decay-accelerating factor," on membranes of granulocytes, monocytes, and platelets in paroxysmal nocturnal hemoglobinuria.

Erythrocytes from patients with paroxysmal nocturnal hemoglobinuria are deficient in decay-accelerating factor, a membrane protein that inhibits the complement C3 convertases. We studied the expression of this protein on leukocytes and platelets from four patients with paroxysmal nocturnal hemoglobinuria, using cytofluorographic analysis and antibody to decay-accelerating factor. The granulocytes and monocytes had a bimodal distribution of fluorescence, indicating antigen-deficient and antigen-positive subpopulations of cells. In contrast, granulocytes and monocytes from normal donors and patients with other diseases had no antigen-deficient cells. Platelets from the four patients with paroxysmal nocturnal hemoglobinuria had less fluorescence than normal platelets. Furthermore, surface-radiolabeled granulocytes and platelets from one of the four patients, which were maximally deficient in decay-accelerating factor, also lacked antigen that was immunoprecipitable by specific antibody to this protein. Thus, paroxysmal nocturnal hemoglobinuria is a clonal disorder characterized by deficient membrane expression of decay-accelerating factor on granulocytes, monocytes, and platelets, as well as on erythrocytes.

Terminal complement complex C5b-9 stimulates mitogenesis in 3T3 cells.

The membrane attack complex of complement (MAC) can induce reversible changes in cell membrane permeability resulting in significant but transient intracellular ionic changes in the absence of cell lysis. Because ion fluxes and cytosolic ionic changes are integral steps in the signaling cascade initiated when growth factors bind to their receptors, we hypothesized that the MAC-induced reversible changes in membrane permeability could stimulate cell proliferation. Using purified terminal complement components we have documented a mitogenic effect of the MAC for quiescent murine 3T3 cells. The MAC enhances the mitogenic effects of serum and PDGF, and also stimulates cell proliferation in the absence of other exogenous growth factors. MAC-induced mitogenesis represents a novel effect of the terminal complement complex that could contribute to focal tissue repair or pathological cell proliferation locally at sites of complement activation.

Staphylococcus aureus Strains That Express Serotype 5 or Serotype 8 Capsular Polysaccharides Differ in Virulence

ABSTRACT Most isolates of Staphylococcus aureus produce a serotype 5 (CP5) or 8 (CP8) capsular polysaccharide. To investigate whether CP5 and CP8 differ in their biological properties, we created isogenic mutants of S. aureus Reynolds that expressed CP5, CP8, or no capsule. Biochemical analyses of CP5 and CP8 purified from the isogenic S. aureus strains were consistent with published structures. The degree of O acetylation of each polysaccharide was similar, but CP5 showed a greater degree of N acetylation. Mice challenged with the CP5+ strain showed a significantly higher bacteremia level than mice challenged with the CP8+ strain. Similarly, the CP5+ strain survived preferentially in the bloodstream and kidneys of infected mice challenged with a mixed inoculum containing both strains. The enhanced virulence of the CP5+ strain in vivo correlated with its greater resistance to in vitro killing in whole mouse blood. Likewise, in vitro opsonophagocytic killing assays with human neutrophils and sera revealed greater survival of the Reynolds (CP5) strain, even though the kinetics of opsonization by C3b and iC3b was similar for both the CP5+ and CP8+ strains. Electron micrographs demonstrated C3 molecules on the cell wall beneath the capsule layer for both serotype 5 and 8 strains. Purified CP5 and CP8 stimulated a modest oxidative burst in human neutrophils but failed to activate the alternative complement pathway. These results indicate that CP5 and CP8 differ in a number of biological properties, and these differences likely contribute to the relative virulence of serotype 5 and 8 S. aureus in vivo.

Decay Accelerating Factor (CD55)

Complement is a mediator system comprised of 12 activation proteins and at least 11 inhibitors. The activation proteins interact sequentially to generate cleavage fragments and condensation products with specific and potent biologic activity. Activated complement proteins can function as anaphylatoxins, adherence factors, chemotaxins, opsonins, and a transmembrane pore, which can be lytic (reviewed in Fries and Frank 1987). Regulated complement activation is essential for the survival of the host, while unregulated complement activation contributes to inflammation and is detrimental to the host. Complement is regulated by the specificity of its activation, by the lability of its activation products, and by the potent inhibitors found in the fluid phase and within the membranes of host cells. The structure, function, and expression of one important membrane regulator of complement, namely, the decay accelerating factor (DAF), will be reviewed here.

C1q-binding proteins and C1q receptors

Aggregated or immobilized complement C1q induces cellular responses in many different cell types. C1q-induced cellular responses may be involved in host defense and in protection against autoimmunity because C1q-deficient humans have infectious complications and a very high incidence of autoimmune disease. The search for the C1q receptor(s), which has been ongoing for 25 years, has led recently to the recognition that proteins identified as binding to C1q may be divided into two groups: C1q-binding molecules that are normally intracellular; and cell surface C1q receptors.

Complement C3a Enhances CXCL12 (SDF-1)-Mediated Chemotaxis of Bone Marrow Hematopoietic Cells Independently of C3a Receptor

Complement C3a promotes CXCL12-induced migration and engraftment of human and murine hemopoietic progenitor cells, suggesting a cross-influence between anaphylatoxin and chemokine axes. Here we have explored the underlying mechanism(s) of complement anaphylatoxin and chemokine cooperation. In addition to C3a, C3a-desArg and C4a but not C5a, are potent enhancers of CXCL12-induced chemotaxis of human and murine bone marrow (BM) stem/progenitor cells and B lineage cells. C3a enhancement of chemotaxis is chemokine specific because it is also observed for chemotaxis to CCL19 but not to CXCL13. The potentiating effect of C3a on CXCL12 is independent of the classical C3a receptor (C3aR). First, human BM CD34+ and B lineage cells do not express C3aR by flow cytometry. Second, the competitive C3aR inhibitor SB290157 does not affect C3a-mediated enhancement of CXCL12-induced chemotaxis. Third, enhancement of chemotaxis of hemopoietic cells is also mediated by C3a-desArg, which does not bind to C3aR. Finally, C3a enhances CXCL12-induced chemotaxis of BM cells from C3aR knockout mice similar to BM cells from wild-type mice. Subsequent studies revealed that C3a increased the binding affinity of CXCL12 to human CXCR4+/C3aR−, REH pro-B cells, which is compatible with a direct interaction between C3a and CXCL12. BM stromal cells were able to generate C3a, C3a-desArg, C4a, as well as CXCL12, suggesting that this pathway could function in vivo. Taken together, we demonstrate a C3a-CXCL12 interaction independent of the C3aR, which may provide a mechanism to modulate the function of CXCL12 in the BM microenvironment.

Human Complement Receptor Type 1/CD35 Is an Epstein-Barr Virus Receptor

Epstein-Barr virus (EBV) attachment to primary B cells initiates virus entry. Although CD21 is the only known receptor for EBVgp350/220, a recent report documents EBV-infected B cells from a patient genetically deficient in CD21. On normal resting B cells, CD21 forms two membrane complexes: one with CD19 and another with CD35. Whereas the CD21/CD19 complex is widely retained on immortalized and B cell tumor lines, the related complement-regulatory protein CD35 is lost. To determine the role(s) of CD35 in initial infection, we transduced a CD21-negative pre-B cell and myeloid leukemia line with CD35, CD21, or both. Cells expressing CD35 alone bound gp350/220 and became latently infected when the fusion receptor HLA II was coexpressed. Temporal, biophysical, and structural characteristics of CD35-mediated infection were distinct from CD21. Identification of CD35 as an EBV receptor uncovers a salient role in primary infection, addresses unsettled questions of virus tropism, and underscores the importance of EBVgp350/220 for vaccine development.

Critical Role of the Complement System in Group B Streptococcus-Induced Tumor Necrosis Factor Alpha Release

ABSTRACT Group B Streptococcus (GBS) is a major cause of newborn sepsis and meningitis and induces systemic release of tumor necrosis factor alpha (TNF-α), believed to play a role in morbidity and mortality. While previous studies have shown that GBS can induce TNF-α release from monocytes and macrophages, little is known about the potential modulating effect of plasma or serum on GBS-induced TNF-α release, and there are conflicting reports as to the host receptors involved. In a human whole-blood assay system, GBS type III COH-1 potently induced substantial monocyte TNF-α release in adult peripheral blood and, due to a higher concentration of monocytes, 10-fold-greater TNF-α release in newborn cord blood. Remarkably, GBS-induced TNF-α release from human monocytes was enhanced ∼1,000-fold by heat-labile serum components. Experiments employing C2-, C3-, or C7-depleted serum demonstrated that C3 activation via the alternative pathway is crucial for potent GBS-induced TNF-α release. Accordingly, whole blood from C3-deficient mice demonstrated significantly reduced GBS-induced TNF-α release. Preincubation with human serum enhanced the TNF-α-inducing activity of GBS in a C3- and factor B-dependent manner, implying deposition of complement components via the alternative pathway. GBS-induced TNF-α release was inhibited by monoclonal antibodies directed against each of the components of CR3 and CR4: the common integrin β subunit CD18 and the α subunits CD11b (of CR3) and CD11c (of CR4). Blood derived from CR3 (CD11b/CD18)-deficient mice demonstrated a markedly diminished TNF-α response to GBS. We conclude that the ability of plasma and serum to greatly amplify GBS-induced TNF-α release reflects the activity of the alternative complement pathway that deposits fragments on GBS and thereby enhances CR3- and CR4-mediated monocyte activation.