The CD19 complex of B lymphocytes. Activation of phospholipase C by a protein tyrosine kinase-dependent pathway that can be enhanced by the membrane IgM complex

We have investigated the mechanism by which the membrane protein complex of the B lymphocyte that contains CD19 and CR2 activates phospholipase C (PLC) to induce a rise in [CA2+]i. The CD19 complex resembled the membrane IgM complex in that three protein tyrosine kinase inhibitors suppressed increases in [Ca2+]i and inositol bisphosphate and inositol triphosphate generation. However, the activation of PLC by the CD19 complex could be distinguished from that by the membrane IgM complex by slower kinetics of generation of inositol phosphates, resistance to inhibition by activators of protein kinase C, and different pattern of tyrosine-phosphorylated cellular substrates. Western blot analysis of lysates from cells stimulated by the CD19 complex demonstrated a single new phosphotyrosine-containing protein of 85 kDa, whereas multiple other phosphotyrosine-containing proteins were present in cells activated by the mIgM complex. In particular, PLC-gamma 1, which is a substrate for the protein tyrosine kinase activated by the mIgM complex, was not tyrosine-phosphorylated in cells stimulated by the CD19 complex. Cross-linking the two complexes together caused a synergistic increase in [CA2+]i which was neither suppressed by activation of protein kinase C nor associated with increased tyrosine-phosphorylation of PLC, characteristic of the CD19 pathway. Therefore, the B cell has two signal transduction complexes, associated with membrane IgM and CD19, that activate PLC by different mechanisms and that can synergistically interact to enhance this function by the CD19 pathway.

The CD19 complex of B lymphocytes. Activation of phospholipase C by a protein tyrosine kinase-dependent pathway that can be enhanced by the membrane IgM complex

We have investigated the mechanism by which the membrane protein complex of the B lymphocyte that contains CD19 and CR2 activates phospholipase C (PLC) to induce a rise in [CA2+]i. The CD19 complex resembled the membrane IgM complex in that three protein tyrosine kinase inhibitors suppressed increases in [Ca2+]i and inositol bisphosphate and inositol triphosphate generation. However, the activation of PLC by the CD19 complex could be distinguished from that by the membrane IgM complex by slower kinetics of generation of inositol phosphates, resistance to inhibition by activators of protein kinase C, and different pattern of tyrosine-phosphorylated cellular substrates. Western blot analysis of lysates from cells stimulated by the CD19 complex demonstrated a single new phosphotyrosine-containing protein of 85 kDa, whereas multiple other phosphotyrosine-containing proteins were present in cells activated by the mIgM complex. In particular, PLC-gamma 1, which is a substrate for the protein tyrosine kinase activated by the mIgM complex, was not tyrosine-phosphorylated in cells stimulated by the CD19 complex. Cross-linking the two complexes together caused a synergistic increase in [CA2+]i which was neither suppressed by activation of protein kinase C nor associated with increased tyrosine-phosphorylation of PLC, characteristic of the CD19 pathway. Therefore, the B cell has two signal transduction complexes, associated with membrane IgM and CD19, that activate PLC by different mechanisms and that can synergistically interact to enhance this function by the CD19 pathway.

Determination of the structural basis for selective binding of Epstein-Barr virus to human complement receptor type 2

Epstein-Barr virus (EBV) is an oncogenic herpesvirus that selectively infects and immortalizes human B lymphocytes. One determinant of this narrow tropism is human CR2, the only viral receptor within the superfamily of proteins that contain short consensus repeats (SCRs). Human CR2 serves as a receptor for both C3dg and the gp350/220 glycoprotein of EBV, and binds the monoclonal antibody (mAb) OKB7, which blocks binding of both ligands to the receptor. In contrast, although murine CR2 is capable of binding human C3dg and this interaction can be blocked with the mAb 7G6, it does not bind OKB7 or EBV. We have determined the structural basis for absolute specificity of EBV for human CR2 through characterization of a panel of 24 human-murine chimeric receptors, all of which bind human C3dg. The results indicate that preferential binding of EBV to human CR2 is not due to unique amino acids that are capable of binding the virus, but reflects a distinct receptor conformation that can be achieved in murine CR2 with single amino acid substitutions in two discontinuous regions of the primary structure: replacement of proline at position 15 with the corresponding serine from human CR2, and elimination of a potential N-linked glycosylation site between SCR-1 and SCR-2. Furthermore, species-specific binding of EBV, OKB7, and 7G6 can all be manipulated through substitutions among residues 8-15, suggesting that this octapeptide is part of a structural determinant that is critical for binding of both viral and natural ligands to CR2.

Mapping of the C3b-binding site of CR1 and construction of a (CR1)2-F(ab')2 chimeric complement inhibitor

CR1/CR2 chimeric receptors in which various short consensus repeats (SCRs) of CR1 were attached to CR2 were transiently expressed on COS cells, and assessed for the binding of polymerized C3b (pC3b) and anti-CR2 by immunofluorescence. Of COS cells expressing chimeras containing SCR 1-4, 1-3, 2-4, 1-2, and 2-3 of the long homologous repeats (LHRs) -B or -C, 96%, 66%, 23%, 0%, and 0%, respectively, bound pC3b. K562 cells were stably transfected with wild-type CR1, deletion mutants of CR1, and the CR1/CR2 chimeras, respectively, and assayed for binding of 125I-pC3b. The dissociation constants (Kd) for pC3b of wild-type CR1 and the LHR-BD and -CD constructs were in the range of 1.0-2.7 nM, and of the CR1/CR2 chimeras containing SCRs 1-4, 1-3, and 2-4 of LHR-B or -C were 1.8-2.4, 6-9, and 22-36 nM, respectively. The factor I-cofactor function of the CR1/CR2 chimeras paralleled the C3b-binding function of the constructs. A CR1/immunoglobulin (Ig) chimeric protein was prepared by fusing SCRs 1-4 of LHR-B to the heavy chains of a murine F(ab')2 anti-nitrophenacetyl (NP) monoclonal antibody. The (CR1)2-F(ab')2 chimera, which retained its specificity for NP, was as effective as soluble, full-length CR1 in binding pC3b, serving as a cofactor for factor I-mediated cleavage of C3b, and inhibiting activation of the alternative pathway, indicating that the bivalent expression of these SCRs reconstitutes the alternative pathway inhibitory function of CR1. The feasibility of creating CR1/Ig chimeras makes possible a new strategy of targeting complement inhibition by the use of Ig fusion partners having particular antigenic specificities.

Suppression of the immune response by a soluble complement receptor of B lymphocytes

The CD19-CR2 complex of B lymphocytes contains proteins that participate in two host-defense systems, the immune and complement systems. The ligand for the subunit of the immune system, CD19, is not known, but the complement receptor subunit, CR2 (CD21), binds activation fragments of the C3 component of the complement system and may mediate immunopotentiating effects of complement. A recombinant, soluble CR2 was prepared by fusing the C3-binding region of the receptor to immunoglobulin G1 (IgG1). The (CR2)2-IgG1 chimera competed with cellular CR2 for C3 binding and suppressed the antibody response to a T cell-dependent antigen when administered to mice at the time of immunization. This inhibitory effect of (CR2)2-IgG1 demonstrates the B cell-activating function of the CD19-CR2 complex and suggests a new method for humoral immunosuppression.

Anti-inflammatory and immunosuppressive effects of recombinant soluble complement receptors

CR1 and CR2 have served as unusual probes for the analysis of the two major functions of the immune system involving inflammation and the immune response, respectively. CR1, or some construct containing its active site SCRs, may find a role in the therapy of complement-dependent tissue injury, and may be used to define which diseases are caused by the inappropriate or excessive activation of this system. Although soluble forms of CR2 may be shown to have potential clinical utility when foreign antigen is given prospectively, as in monoclonal antibody therapy, perhaps the most important finding emanating from the analysis of this receptor is the recognition of a previously unrecognized membrane protein complex whose role in B cell development is yet to be determined. It is reasonable to predict that the function of the CD19 complex will be significant as it serves as the link between two evolutionarily distinct systems that share a common purpose of anti-microbial host defense.

Interaction of iC3b with recombinant isotypic and chimeric forms of CR2

CR2 is a component of a signal transduction complex on B lymphocytes that augments B cell responses to Ag. We have quantitatively assessed binding by the two isotypic forms of CR2 for two of its ligands, the polymerized iC3b (p(iC3b)) fragment of C3, and gp350/220, the EBV membrane protein. The recombinant 15-SCR or 16-SCR forms of CR2 bound p(iC3b) with identical affinities. Full binding activity of CR2 for p(iC3b) was observed with a chimera comprised of SCR-1 and -2 of CR2 fused to SCR-17 through -30 of CR1. Therefore, the alternatively spliced SCR-10a has no role in binding p(iC3b), and the binding activity of wild type receptor for iC3b can be reconstituted with SCR-1 and -2 of CR2. The binding affinities of the two isoforms of CR2 for soluble gp350/220 were also similar. Additional sites in the C3c region of C3 have been postulated also to interact with CR2. However, monomeric iC3b and C3d were equally effective in inhibiting the binding of p(iC3b) to CR2, indicating that the C3c region of iC3b does not contribute to the interaction of iC3b with CR2. Finally, the relative abilities of C3b and iC3b to bind to CR1 and CR2 were compared. The conversion of C3b to iC3b generated a ligand with an approximate 100-fold decrease in affinity for CR1 and a 10-fold increased affinity for CR2, resulting in a 1000-fold greater likelihood for binding to the latter receptor that may then promote B cell activation.

Interaction of iC3b with recombinant isotypic and chimeric forms of CR2

CR2 is a component of a signal transduction complex on B lymphocytes that augments B cell responses to Ag. We have quantitatively assessed binding by the two isotypic forms of CR2 for two of its ligands, the polymerized iC3b (p(iC3b)) fragment of C3, and gp350/220, the EBV membrane protein. The recombinant 15-SCR or 16-SCR forms of CR2 bound p(iC3b) with identical affinities. Full binding activity of CR2 for p(iC3b) was observed with a chimera comprised of SCR-1 and -2 of CR2 fused to SCR-17 through -30 of CR1. Therefore, the alternatively spliced SCR-10a has no role in binding p(iC3b), and the binding activity of wild type receptor for iC3b can be reconstituted with SCR-1 and -2 of CR2. The binding affinities of the two isoforms of CR2 for soluble gp350/220 were also similar. Additional sites in the C3c region of C3 have been postulated also to interact with CR2. However, monomeric iC3b and C3d were equally effective in inhibiting the binding of p(iC3b) to CR2, indicating that the C3c region of iC3b does not contribute to the interaction of iC3b with CR2. Finally, the relative abilities of C3b and iC3b to bind to CR1 and CR2 were compared. The conversion of C3b to iC3b generated a ligand with an approximate 100-fold decrease in affinity for CR1 and a 10-fold increased affinity for CR2, resulting in a 1000-fold greater likelihood for binding to the latter receptor that may then promote B cell activation.

Molecular interactions of complement receptors on B lymphocytes: a CR1/CR2 complex distinct from the CR2/CD19 complex

The complement system augments the humoral immune response to low concentrations of antigen. This effect may be partly mediated by complement receptors on the surface of B lymphocytes that bind immunogenic complexes bearing fragments of C3 and C4. We have shown by immunoprecipitation analysis that the two complement receptors expressed by B lymphocytes, complement receptor 1 (CR1) and CR2, form a detergent-sensitive complex on the surface of tonsillar B lymphocytes and on K562 erythroleukemia cells that were co-transfected with cDNAs encoding CR1 and CR2. The CR1/CR2 complex is distinct from the CR2/CD19 complex and may assist B cell activation by efficiently capturing C3b-containing immunogens and maintaining such immunogens on the B cell after CR1 and factor I-mediated cleavage to iC3b and C3dg. The complement activating immunogen may then trigger signal transduction by the CR1/CR2 complex, the CR2/CD19 complex, or membrane immunoglobulin.

Tyrosine phosphorylation of phospholipase C induced by membrane immunoglobulin in B lymphocytes

Ligation of membrane IgM on B lymphocytes causes activation of a protein-tyrosine kinase(s) (PTK) and of phospholipase C (PLC). To determine whether these are elements of a common signal-transduction pathway, the effect of three PTK inhibitors on the rise in intracellular free Ca2+ concentration [( Ca2+]i) in human B-lymphoblastoid cell lines was assessed. Tyrphostin completely suppressed the increase in [Ca2+]i and the generation of inositol phosphates induced by ligation of membrane immunoglobulin (mIg) M. Herbimycin and genistein reduced by 30% and 50%, respectively, the rise in [Ca2+]i caused by optimal ligation of mIgM, and they abolished it in cells activated by suboptimal ligation of mIgM. Tyrphostin had no effect on the capacity of aluminum fluoride to increase [Ca2+]i. To determine whether a function of PTK is the phosphorylation of PLC, immunoprecipitates obtained with anti-phosphotyrosine from detergent lysates of B-lymphoblastoid cells were assayed for PLC activity. Ligation of mIgM increased immunoprecipitable PLC activity 2-fold by 90 sec and 4-fold by 30 min. Specific immunoprecipitation and Western blot analysis identified tyrosine phosphorylation of the gamma 1 isoform of PLC after 60 sec of stimulation. Activation of PLC in B cells by mIgM requires PTK function and is associated with tyrosine phosphorylation of PLC-gamma 1, suggesting a mechanism of PLC activation similar to that described for certain receptor PTKs.

Intersection of the complement and immune systems: a signal transduction complex of the B lymphocyte-containing complement receptor type 2 and CD19

The complement system augments the humoral immune response, possibly by a mechanism that involves the B lymphocyte membrane receptor, CR2, which binds the C3dg fragment of C3 and triggers several B cell responses in vitro. The present study demonstrates that CR2 associates with a complex of membrane proteins that may mediate signal transduction by ligated CR2. Monoclonal antibodies to CR2 immunoprecipitated from digitonin lysates of Raji B lymphoblastoid cells a membrane complex containing CR2, approximately equimolar amounts of CD19, which is a member of the immunoglobulin superfamily, and three unidentified components: p130, p50, and p20. The complex, which was immunoprecipitated also with anti-CD19, could be dissociated by Nonidet P-40, accounting for its absence in previous studies of CR2. Expression of recombinant CR2 and CD19 in K562 erythroleukemia cells led to formation of a complex that contained not only these two proteins but also p130, p50, and p20, and another component, p14. These unidentified components of the CR2/CD19 complex coimmunoprecipitated with CD19 and not with CR2 from singly transfected cells, indicating primary association with the former. CD19 replicated the capacity of CR2 to interact synergistically with mIgM for increasing free intracellular Ca2+, suggesting that the complex mediates this function of CR2. Therefore, CR2 associates directly with CD19 to become a ligand-binding subunit of a pre-existing signal transduction complex of the B cell that may be representative of a family of membrane protein complexes. This interaction between the complement and immune systems differs from that between immunoglobulin and Clq by involving membrane rather than plasma proteins, and by having complement involved in the afferent phase of the immune response.

Soluble human complement receptor type 1: in vivo inhibitor of complement suppressing post-ischemic myocardial inflammation and necrosis

The complement system is an important mediator of the acute inflammatory response, and an effective inhibitor would suppress tissue damage in many autoimmune and inflammatory diseases. Such an inhibitor might be found among the endogenous regulatory proteins of complement that block the enzymes that activate C3 and C5. Of these proteins, complement receptor type 1 (CR1; CD35) has the most inhibitory potential, but its restriction to a few cell types limits its function in vivo. This limitation was overcome by the recombinant, soluble human CR1, sCR1, which lacks the transmembrane and cytoplasmic domains. The sCR1 bivalently bound dimeric forms of its ligands, C3b and methylamine-treated C4 (C4-ma), and promoted their inactivation by factor I. In nanomolar concentrations, sCR1 blocked complement activation in human serum by the two pathways. The sCR1 had complement inhibitory and anti-inflammatory activities in a rat model of reperfusion injury of ischemic myocardium, reducing myocardial infarction size by 44 percent. These findings identify sCR1 as a potential agent for the suppression of complement-dependent tissue injury in autoimmune and inflammatory diseases.

Mapping of the Epstein-Barr virus and C3dg binding sites to a common domain on complement receptor type 2

Complement receptor type 2 (CR2;CD21), a member of the superfamily of proteins containing short consensus repeats (SCRs), is the B cell receptor for both the gp350/220 envelope protein of Epstein-Barr virus (EBV), and for the C3dg protein of complement. By analysis of CR2 deletion mutants and chimeras formed with CR1 (CD35) we determined that of the 15 SCRs in CR2, the NH2-terminal two SCRs are necessary and sufficient to bind both gp350/220 and C3dg with affinities equivalent to those of the wild-type receptor. The epitope for OKB-7, a mAb that blocks binding of both EBV and C3dg and shares with these ligands B cell-activating capabilities, also requires both SCR-1 and SCR-2, whereas mAbs lacking these functions bind to other SCRs. Thus, EBV, a polyclonal activator of B cells, has selected a site that is proximate or identical to the natural ligand binding site in CR2, perhaps reflecting the relative immutability of that site as well as its signal transducing function.

Polymeric C3dg primes human B lymphocytes for proliferation induced by anti-IgM

Polymeric C3dg (pC3dg), having an average m.w. of approximately 400,000 and saturating complement receptor type 2 (CR2) on B lymphoblastoid cells at 1 micrograms/ml, was preincubated with tonsillar B cells for 24 h, after which anti-IgM was added and proliferation assessed by thymidine incorporation. Preculture of B cells with 0.01 to 1.0 micrograms/ml of polymerized C3dg (pC3dg) caused a dose-dependent enhancement of proliferation and accelerated entry into S phase after addition of anti-IgM. The continued presence of pC3dg during stimulation by anti-IgM was not required. pC3dg alone did not induce proliferation and preculture of B cells with C3dg monomer had no effect on the subsequent response to anti-IgM. The priming effect of pC3dg required at least 6 h and was greatest after 24 h of preculture. Preincubation with pC3dg did not lower the concentration of anti-IgM necessary for induction of proliferation, but did enhance proliferation at all concentrations above this threshold. Augmented proliferation occurred only in B cells of higher density in Percoll gradients, and neither T cells nor monocytes were required. Thus, independent interaction of CR2 with its natural ligand primes the B cell for subsequent stimulation through the Ag receptor, an effect that might synergize with the previously described CR2 function of lowering the threshold for B cell activation when crosslinked to membrane IgM.

Polymeric C3dg primes human B lymphocytes for proliferation induced by anti-IgM

Polymeric C3dg (pC3dg), having an average m.w. of approximately 400,000 and saturating complement receptor type 2 (CR2) on B lymphoblastoid cells at 1 micrograms/ml, was preincubated with tonsillar B cells for 24 h, after which anti-IgM was added and proliferation assessed by thymidine incorporation. Preculture of B cells with 0.01 to 1.0 micrograms/ml of polymerized C3dg (pC3dg) caused a dose-dependent enhancement of proliferation and accelerated entry into S phase after addition of anti-IgM. The continued presence of pC3dg during stimulation by anti-IgM was not required. pC3dg alone did not induce proliferation and preculture of B cells with C3dg monomer had no effect on the subsequent response to anti-IgM. The priming effect of pC3dg required at least 6 h and was greatest after 24 h of preculture. Preincubation with pC3dg did not lower the concentration of anti-IgM necessary for induction of proliferation, but did enhance proliferation at all concentrations above this threshold. Augmented proliferation occurred only in B cells of higher density in Percoll gradients, and neither T cells nor monocytes were required. Thus, independent interaction of CR2 with its natural ligand primes the B cell for subsequent stimulation through the Ag receptor, an effect that might synergize with the previously described CR2 function of lowering the threshold for B cell activation when crosslinked to membrane IgM.

Structure of the human CR1 gene. Molecular basis of the structural and quantitative polymorphisms and identification of a new CR1-like allele

Structural and quantitative polymorphisms have been described in human CR1. In the former, the S allotype is larger than the F allotype by 40-50 kD, the size of a long homologous repeat (LHR). In the latter, homozygotes for a 7.4-kb Hind III fragment express fourfold more CR1 per erythrocyte than do homozygotes for the allelic 6.9-kb restriction fragment. The basis for these genomic polymorphisms has been determined by restriction mapping the entire S allele and part of the F allele. The S allele is 158 kb and contains 5 LHRs of 20-30 kb, designated -A, -B/A, -B, -C, and -D, respectively, 5' to 3'. Extensive homology was found among the LHRs in their restriction maps, exon organization, and the coding and noncoding sequences. The presence of LHR-B/A in the S allele but not in the F allele accounts for the longer transcripts and polypeptide associated with the former allotype. At least 42 exons are present in the S allele, with distinct exons for the leader sequence, the transmembrane and cytoplasmic regions and most of the SCRs comprising the extracellular portion of CR1. Consistent with the mapping of the ligand binding site to the first two SCRs in each LHR, the second SCRs in LHR-A, -B/A, -B, and -C are encoded by two exons, reflecting a specialized function for this unit. The allelic 7.4/6.9-kb Hind III fragments extend from the 3' region of LHR-C to LHR-D. The 6.9-kb restriction fragment is the result of a new Hind III site generated by a single base change in the intron between the exons encoding the second SCR of LHR-D. A second cluster of genomic clones has been identified by hybridization to CR1 probes. Although they contain regions of hybridization to the cDNA and genomic probes derived from CR1, these cannot be overlapped with the structural gene owing to their distinct restriction maps. Three genomic polymorphisms previously identified by CR1 cDNA probes map to this region. These additional clones may represent part of a duplicated allele located nearby within the CR1 locus.

Epstein-Barr virus (EBV) infection of murine L cells expressing recombinant human EBV/C3d receptor

The normal host range of Epstein-Barr virus (EBV) is limited to primate B lymphocytes and certain epithelial cells that express the C3d/EBV receptor [complement receptor 2 (CR2, CD21)]. In the present study, expansion of the tissue tropism of EBV has been accomplished by stably transfecting the murine fibroblast L cell line with pMT.CR2. neo.1, a eukaryotic expression vector promoting the transcription of a complementary DNA insert encoding human CR2. High CR2-expressing transfected L cells were selected by fluorescence-activated cell sorting. The recombinant CR2 was shown to have the same molecular weight as wild-type CR2 from Raji cells and to mediate the binding by the transfectants of particles bearing the iC3b and C3d fragments of the third component of complement. All CR2-expressing L cells, but not nontransfected controls, also bound EBV, as assessed by indirect immunofluorescence. After a 60-hr culture, approximately 0.5% of the CR2-expressing cells preincubated with EBV demonstrated immunofluorescent staining of EBV nuclear antigen with serum from a patient with nasopharyngeal carcinoma. No fluorescent staining of cells was seen with monoclonal antibodies to the early antigen complex or to gp350/220, indicating that the infection was predominantly latent. Infected cells cultured for up to 4 weeks remained EBV nuclear antigen-positive. The capacity of recombinant human CR2 to confer on murine L cells susceptibility to stable latent infection by EBV indicates that this receptor is a primary determinant of the tissue tropism of EBV and may facilitate studies of cell-specific factors that regulate the viral growth cycle.

Identification of distinct C3b and C4b recognition sites in the human C3b/C4b receptor (CR1, CD35) by deletion mutagenesis

Complementary DNA clones encoding the NH2-terminal region of human CR1 have been isolated and sequenced. The deduced complete amino acid sequence of the F allotype of human CR1 contains 2,039 residues, including a 41-residue signal peptide, an extracellular domain of 1,930 residues, a 25-amino acid transmembrane domain, and a 43-amino acid cytoplasmic region. The extracellular domain is composed exclusively of 30 short consensus repeats (SCRs), characteristic of the family of C3/C4-binding proteins. The 28 NH2-terminal SCRs are organized as four long homologous repeats (LHRs) of seven SCRs each. The newly sequenced LHR, LHR-A, is 61% identical to LHR-B in the NH2-terminal two SCRs and greater than 99% identical in the COOH-terminal five SCRs. Eight cDNA clones were spliced to form a single construct, piABCD, that contained the entire CR1 coding sequence downstream of a cytomegalovirus promoter. COS cells transfected with piABCD transiently expressed recombinant CR1 that comigrated with the F allotype of erythrocyte CR1 on SDS-PAGE and that mediated rosette formation with sheep erythrocytes bearing C4b and C3b. Recombinant CR1 also had factor I-cofactor activity for cleavage of C3(ma). Analyses of six deletion mutants expressed in COS cells indicated that the NH2-terminal two SCRs of LHR-A contained a site determining C4 specificity and the NH2-terminal two SCRs of LHR-B and -C each had a site determining C3 specificity. The presence of these three distinct sites in CR1 may enable the receptor to interact multivalently with C4b/C3b and C3b/C3b complexes generated during activation of the classical and alternative pathways.

Synergistic interaction between complement receptor type 2 and membrane IgM on B lymphocytes

We sought biochemical evidence for a role of C receptors types 1 (CR1) and 2 (CR2) in B cell activation. A flow cytometer was used to measure the fluorescence of tonsillar cells that had been loaded with the calcium-dependent indicator indo-1, and cells were stimulated by cross-linking cell-bound DA4.4 anti-IgM, Yz-1 anti-CR1 or HB5 anti-CR2 with goat anti-mouse IgG. There was a direct dose-response relationship between the proportion of cells having increased cytoplasmic free calcium concentration (Cai) after addition of second antibody and the amount of cell-bound Fab' DA4.4. In contrast, no rise in Cai was observed after cross-linking bound Yz-1 or HB5. To determine whether CR1 or CR2 could modify the increase in Cai induced by cross-linking membrane IgM, Cai was monitored after addition of second antibody to cells bearing combinations of either Yz-1 or HB5 with a limited amount of DA4.4. The combination of Yz-1 with DA4.4 yielded little or no further increase in the percentage of cells responding to cross-linking with elevated Cai compared with DA4.4 alone. However, the combination of HB5 with limited DA4.4 synergistically enhanced this response, resulting in stimulation that was equivalent to that obtained with optimal concentrations of DA4.4. The synergistic effect of CR2 was also observed with avidin as the cross-linking reagent for bound biotinylated HB5 and DA4.4, occurred in the presence of EGTA, and did not require T cells. Studies of the proliferation of B cell-enriched PBMC demonstrated that, whereas HB5 coupled to Sepharose alone induced little or no DNA synthesis, the combination of HB5 with limited DA4.4 on Sepharose induced a dose-related synergistic increase in the incorporation of [3H]thymidine.

Synergistic interaction between complement receptor type 2 and membrane IgM on B lymphocytes

We sought biochemical evidence for a role of C receptors types 1 (CR1) and 2 (CR2) in B cell activation. A flow cytometer was used to measure the fluorescence of tonsillar cells that had been loaded with the calcium-dependent indicator indo-1, and cells were stimulated by cross-linking cell-bound DA4.4 anti-IgM, Yz-1 anti-CR1 or HB5 anti-CR2 with goat anti-mouse IgG. There was a direct dose-response relationship between the proportion of cells having increased cytoplasmic free calcium concentration (Cai) after addition of second antibody and the amount of cell-bound Fab' DA4.4. In contrast, no rise in Cai was observed after cross-linking bound Yz-1 or HB5. To determine whether CR1 or CR2 could modify the increase in Cai induced by cross-linking membrane IgM, Cai was monitored after addition of second antibody to cells bearing combinations of either Yz-1 or HB5 with a limited amount of DA4.4. The combination of Yz-1 with DA4.4 yielded little or no further increase in the percentage of cells responding to cross-linking with elevated Cai compared with DA4.4 alone. However, the combination of HB5 with limited DA4.4 synergistically enhanced this response, resulting in stimulation that was equivalent to that obtained with optimal concentrations of DA4.4. The synergistic effect of CR2 was also observed with avidin as the cross-linking reagent for bound biotinylated HB5 and DA4.4, occurred in the presence of EGTA, and did not require T cells. Studies of the proliferation of B cell-enriched PBMC demonstrated that, whereas HB5 coupled to Sepharose alone induced little or no DNA synthesis, the combination of HB5 with limited DA4.4 on Sepharose induced a dose-related synergistic increase in the incorporation of [3H]thymidine.

Selective synthesis of mRNA and proteins by human peripheral blood neutrophils

Human peripheral blood polymorphonuclear neutrophils (PMN) have been considered to be capable of little if any protein biosynthesis. We evaluated the ability of PMN to synthesize both mRNA and proteins. Using in vitro [35S]methionine pulse-chase labeling of purified PMN, followed by immunoprecipitation of cell lysates with immobilized mAb and analysis by gel electrophoresis, PMN were shown to synthesize CR1, FcR, CR3 alpha-chain, MHC class I, and actin. In contrast, incorporation of [35S]methionine into either CR3 beta-chain or the secondary granule protein lactoferrin was not detected. Purification of mRNA from PMN and analysis by Northern blots demonstrated the presence in PMN of CR1, actin, and MHC class I transcripts. However, despite the apparent lack of CR3 beta-chain biosynthesis, specific beta-chain message was detectable in PMN RNA. Inhibition of mRNA synthesis in PMN with actinomycin D resulted in decreased synthesis of nascent CR1, FcR, MHC class I, and actin compared with control cells. Thus, PMN continue to transcribe and translate the genes for certain membrane and cytoskeletal proteins. In contrast, the lack of detectable synthesis of either lactoferrin or CR3 beta-chain suggested that biosynthesis in circulating PMN is selective.

Selective synthesis of mRNA and proteins by human peripheral blood neutrophils

Human peripheral blood polymorphonuclear neutrophils (PMN) have been considered to be capable of little if any protein biosynthesis. We evaluated the ability of PMN to synthesize both mRNA and proteins. Using in vitro [35S]methionine pulse-chase labeling of purified PMN, followed by immunoprecipitation of cell lysates with immobilized mAb and analysis by gel electrophoresis, PMN were shown to synthesize CR1, FcR, CR3 alpha-chain, MHC class I, and actin. In contrast, incorporation of [35S]methionine into either CR3 beta-chain or the secondary granule protein lactoferrin was not detected. Purification of mRNA from PMN and analysis by Northern blots demonstrated the presence in PMN of CR1, actin, and MHC class I transcripts. However, despite the apparent lack of CR3 beta-chain biosynthesis, specific beta-chain message was detectable in PMN RNA. Inhibition of mRNA synthesis in PMN with actinomycin D resulted in decreased synthesis of nascent CR1, FcR, MHC class I, and actin compared with control cells. Thus, PMN continue to transcribe and translate the genes for certain membrane and cytoskeletal proteins. In contrast, the lack of detectable synthesis of either lactoferrin or CR3 beta-chain suggested that biosynthesis in circulating PMN is selective.