The immune adherence receptor CR1-like existed on porcine erythrocytes membrane.

In the present study, we obtain a mouse anti-porcine complement receptor type 1 (CR1)-like monoclonal antibody (McAb) and use this McAb to verify the existence of CR1-like protein on porcine erythrocytes. Our results confirm that CR1-like protein is localized on the surface of porcine erythrocytes. Mouse immunoglobulin G inhibited the binding of serum-opsonized green fluorescent protein-expressing Escherichia coli to porcine erythrocytes. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis indicates that CR1-like McAb reacts with biochemically-purified porcine erythrocyte membrane fractions, with a clear band at 135 kDa to 140 kDa. We postulate that the 135 kDa to 140 kDa membrane protein is the equivalent of the porcine erythrocyte CR1-like protein.

[Cloning, expression and identification of functional fragment rC3B of human complement C3 in E. Coli].

This study was purposed to verify the binding part of human complement C3 to complement receptor III (CRIII) in monocytes, the peptide rC3B, including the binding-site, was expressed, purified and identified. rC3B, the binding part of human complement C3 to CRIII, was selected by computer-aided modeling and summarizing researches published. Then, rC3B gene fragment was amplified by PCR, and cloned into prokaryotic vector pQE30a. The fusion protein rC3B was expressed in E.coli M15 and purified by Ni(2+)-chelating affinity chromatography. The activity of rC3B was identified by Western blot and adherence assay with monocytes. The results showed that rC3B fragment was obtained, and a prokaryotic expression vector pQE30-rC3B was constructed. rC3B was efficiently expressed and purified. In Western blot, the target protein showed the activity of binding with C3 antibody, while the purified protein showed the activity of adherence with monocytes. It is concluded that the recombinant C3B was obtained and identified, and this study lay the basis for the further functional analysis of C3.

Quantitative alleles of CR1: coding sequence analysis and comparison of haplotypes in two ethnic groups.

The quantitative expression of complement receptor type 1 (CR1) on erythrocytes is regulated by two CR1 alleles that differ in having genomic HindIII fragments of either 7.4 or 6.9 kb and that determine high (H allele) or low (L allele) CR1 expression, respectively, across a 10-fold range. To investigate whether the product of the L allele may contain amino acid substitutions that make it more susceptible to proteolysis, cDNA sequence spanning the CR1 coding region was analyzed in two donors who were homozygous for the H and L alleles and differed by 7-fold in their mean numbers of CR1 per erythrocyte. Sequence differences were detected at 10 nucleotide positions, including 6 that would cause amino acid substitutions. The HindIII RFLP and 3 of the latter 6 sites were analyzed in genomic DNA of 85 Caucasians and 75 African Americans; sites encoding the other amino acid substitutions were analyzed less extensively. Two major haplotypes defined prototypic H and L alleles in both ethnic groups, suggesting that these alleles existed before the African and European populations diverged. Decreased erythrocyte CR1 expression is associated with impaired clearance of immune complexes from blood. Persistence of the L allele in all populations that have been analyzed may suggest a compensatory survival advantage, perhaps related to malaria or another infectious disease.

Independently melting modules and highly structured intermodular junctions within complement receptor type 1.

A segment of complement receptor type 1 (CR1) corresponding to modules 15-17 was overexpressed as a functionally active recombinant protein with N-glycosylation sites ablated by mutagenesis (referred to as CR1 approximately 15-17(-)). A protein consisting of modules 15 and 16 and another corresponding to module 16 were also overexpressed. Comparison of heteronuclear nuclear magnetic resonance (NMR) spectra for the single, double, and triple module fragments indicated that module 16 makes more extensive contacts with module 15 than with module 17. A combination of NMR, differential scanning calorimetry, circular dichroism, and tryptophan-derived fluorescence indicated a complex unfolding pathway for CR1 approximately 15-17(-). As temperature or denaturant concentration was increased, the 16-17 junction appeared to melt first, followed by the 15-16 junction, and module 17 itself; finally, modules 15 and 16 became denatured. Modules 15 and 16 adopted an intermediate state prior to total denaturation. These results are compared with a previously published study [Clark, N. S., Dodd, I, Mossakowska, D. E., Smith, R. A. G., and Gore, M. G. (1996) Protein Eng. 9, 877-884] on a fragment consisting of the N-terminal three CR1 modules which appeared to melt as a single unit.

Antiinflammatory effects of soluble complement receptor type 1 promote rapid recovery of ischemia/reperfusion injury in rat small intestine.

We examined the effect of soluble complement receptor type 1 (sCR1) on mucosal injury and inflammation in a rat model of ischemia/reperfusion. Groups of vehicle- and sCR1-treated rats underwent 30 min of mesenteric ischemia followed by 60 or 120 min of reperfusion. When compared to vehicle-treated rats, treatment with sCR1 (12 mg/kg) prior to 120 min of reperfusion significantly reduced mucosal injury, neutrophil infiltration, leukotriene B4 production, and restored villus height to control levels. The protective effect of sCR1 evident at 120 min of reperfusion was not observed at 60 min of reperfusion despite rapid inactivation of complement. These data suggest that complement inhibition minimized mucosal disruption by facilitating mucosal restitution or interrupting the inflammatory process. Delayed administration of sCR1 for 30 or 60 min into the reperfusion period progressively reduced the protection. sCR1-mediated rapid recovery of rat intestine after ischemia/reperfusion underscores the fundamental role of complement activation in neutrophil-mediated tissue injury.

Characterization of C3-binding proteins on mouse neutrophils and platelets.

In the mouse, MCR1 and MCR2 on B lymphocytes are encoded by alternatively spliced Cr2 gene transcripts. Immune adherence receptors that bind C3 are present on mouse platelets and unstimulated neutrophils, yet they are not MCR1 or MCR2. To examine C3b- and C3d-binding proteins on mouse platelets and neutrophils, we performed C3b and C3d affinity chromatography as well as immunoprecipitation studies using previously described Ab to MCR1/MCR2 (mAb clones 8C12, 7G6, and 7E9 and polyclonal Ab BRN-1). Mouse neutrophils contained a 190-kDa membrane protein that specifically bound to C3b-Sepharose. Preabsorption of neutrophil proteins with anti-MCR1/MCR2 Ab did not affect the recovery of the 190-kDa C3b-binding protein by subsequent C3b affinity chromatography. Thus, this protein is immunologically distinct from the previously described MCR1 and MCR2 proteins. By virtue of its size and C3b-binding capacity, the 190-kDa protein was named C3bR-190. C3bR-190 was also apparent on platelets, but in reduced amounts. BRN-1 anti-MCR1/MCR2 Ab immunoprecipitated proteins of 125 and 150 kDa from surface-radiolabeled mouse platelets, which specifically bound to C3d-Sepharose. However, these proteins were not identified by mAb to MCR2, thus distinguishing them from previously described MCR2. These proteins were named C3dR-125 and C3dR-150. Therefore, we have identified a 190-kDa C3b-binding protein on mouse neutrophils and 125- and 150-kDa C3d-binding proteins on mouse platelets. These appear to be distinct from the heretofore identified mouse B lymphocyte MCR1 and MCR2. The identity of these C3b- and C3d-binding proteins on mouse neutrophils and platelets awaits further study.

Isolation and characterization of complement receptor type 1 (CR1) storage vesicles from human neutrophils using antibodies to the cytoplasmic tail of CR1.

Neutrophil (PMN) activation is associated with increased surface expression of several membrane proteins that are translocated from intracellular pools. Indirect evidence suggests that the intracellular storage pools of complement receptor type 1 (CR1) in resting PMN are distinct from traditional granules and may be the secretory vesicles in which albumin is also stored, but it is not known if this compartment is homogeneous or heterogeneous. To isolate and characterize the CR1-containing vesicles, we used antibodies against unique sequences in the cytoplasmic tail of CR1. Affinity-purified IgG was used to adsorb CR1 storage vesicles from the light membrane fraction (gamma-band) of nitrogen cavitates of resting PMN. The immunoadsorbent could quantitatively remove the CR1-containing vesicles, whereas control adsorbents with nonimmune IgG showed no specific binding of CR1. Immunoblots of specifically isolated vesicles also showed enrichment of albumin, decay-accelerating factor, Fc gammaRIII, and CR3; whereas HLA class I was not detectable in these vesicles. Enzyme assay of specifically isolated vesicles after treatment with Triton X-100 showed that these vesicles contained most of the cells' latent alkaline phosphatase. An additional population of vesicles containing albumin, but not CR1, and that did not bind to anti-CR1 adsorbent was also identified. Immunoelectron microscopy showed that the specifically isolated vesicles had mean diameters of 0.086 to 0.1 microm and stained positive for CR1 and albumin. These results indicate that CR1 storage vesicles can be isolated with antibodies against the cytoplasmic tail of CR1 and show that these vesicles also contain albumin as well as glycosylphosphatidyl inositol-anchored proteins. These results are most compatible with the hypothesis that CR1-containing vesicles have arisen by endocytic retrieval of proteins that had been on the plasma membrane.

Rapid purification of human complement receptor type 1 (CD35, CR1).

We established a rapid purification procedure for complement receptor type 1 (CR1, CD35). Human erythrocyte stromata were solubilized, and the extract was directly applied to a Red-Sepharose column. The eluate was diluted 2-fold, then subjected to an immunoaffinity column, anti-CR1 (named 31R)-conjugated to Sepharose. More than 50% of CR1 was recovered with purity of > 90%. The CR1 preparation showed sufficient cofactor activity for factor I as compared to that prepared by the conventional method. Since 31R recognizes a single epitope in CR1 including its rare variants and soluble forms, this method will allow us to recover with high efficiency these forms of CR1 which have been detected especially in some disease states.

Overexpression in Escherichia coli, folding, purification, and characterization of the first three short consensus repeat modules of human complement receptor type 1.

We have developed a simple expression, isolation, and folding protocol for an SCR oligomer comprising the first three SCRs of complement receptor Type 1 (C3b/C4b receptor, CD35). A T7 RNA polymerase expression system in Escherichia coli was used to express the oligomer as inclusion bodies. The oligomer was recovered from solubilized inclusion bodies using batch adsorption on SP-Sepharose. The oligomer was folded by one-step dilution in 20 mM ethanolamine/1 mM EDTA supplemented with 1 mM GSH/0.5 mM GSSG. The folded material was processed to a concentrated (> 20 mg/ml), usable product of greater than 98% purity using a combination of ultrafiltration, ammonium sulfate treatment, hydrophobic interaction, and size-exclusion chromatography. The yield of folded material varied between 6 and 15 mg/liter culture. The oxidation states of the 12 cysteine residues in SCR(1-3) were identified by HPLC of peptide fragments from a tryptic digest using dual UV/fluorescence detection, collection of selected peaks, and N-terminal sequencing. This methodology confirmed the expected location of disulfide bridges. Equilibrium and velocity sedimentation studies are interpreted in terms of a single sedimenting species with molecular weights of 21,629 and 21,063 by these respective techniques. These values compare to the predicted molecular weight, from amino acid composition, of 21,817. The hydrodynamic properties of the molecule indicate that it is asymmetric with an axial ratio of 1:5.2 or equivalent dimensions of 21 x 110 A. SCR(1-3) has an unusual CD spectrum exhibiting a broad maximum at 220-230 nm and a minimum at 190 nm. There was little evidence of classical secondary structure. The product exhibited concentration-dependent inhibition of complement-mediated lysis of sensitized sheep red blood cells.

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.

Primary sequence of an alternatively spliced form of CR1. Candidate for the 75,000 M(r) complement receptor expressed on chimpanzee erythrocytes.

Chimpanzee erythrocytes express a 75,000 M(r) complement receptor (E-CR) that binds C3b bearing immune complexes and is recognized by an anti-CR1 mAb (E11). Human erythrocytes express the type 1 CR (CR1), the most common form being 220,000 M(r) and consisting of 30 short consensus repeats (SCRs) for its entire extracellular region. The purpose of this investigation was to determine the structure of the 75,000 M(r) chimpanzee E-CR. A chimpanzee cell line was identified that expressed a 220,000 M(r) CR1, and a 75,000 M(r) molecule that was recognized by E11 and could bind human C3i. Utilizing this cell line, chimpanzee CR1 cDNA was amplified in overlapping segments by the PCR, using primer pairs specific for various regions of human CR1 cDNA. Direct sequencing of the PCR-amplified products revealed 6044 nucleotides encoding the entire 220,000 M(r) chimpanzee CR1. This nucleotide sequence was 98.8% homologous to that of the human 220,000 M(r) CR1. Amplification using a CR1 primer from the signal peptide and from the cytoplasmic region yielded a 1985-bp PCR product, termed CR1a. The CR1a sequence was identical with the sequence encoding SCRs 1 to 6, SCRs 28 to 30, and the transmembrane and cytoplasmic regions of chimpanzee CR1. This alternatively spliced product of chimpanzee CR1 would encode a protein of 71,000 peptide m.w. with six potential N-glycosylation sites. Amplification employing a CR1 primer from SCR 1 and from the 3' untranslated region yielded a second PCR product of 1731 bp. This sequence, termed CR1b, encoded eight SCRs, followed by a hydrophobic region that ended in a stop codon. The first six SCRs of CR1b were closer in homology to the first six SCRs of a human CR1-like genomic sequence (97.4%) than to those of the chimpanzee CR1 (94.8%). Taken together, these sequence data suggest that the 75,000 M(r) chimpanzee E-CR is encoded by CR1a, an alternative splice variant of chimpanzee CR1. The CR1b is presumably derived from an RNA species related to the CR1-like genomic sequence previously described only in humans.

Identification of membrane-bound CR1 (CD35) in human urine: evidence for its release by glomerular podocytes.

Complement receptor 1 (CR1) is present on erythrocytes (E-CR1), various leucocytes, and renal glomerular epithelial cells (podocytes). In addition, plasma contains a soluble form of CR1 (sCR1). By using a specific ELISA, CR1 was detected in the urine (uCR1) of normal individuals (excretion rate in 12 subjects, 3.12 +/- 1.15 micrograms/24 h). Contrary to sCR1, uCR1 was pelleted by centrifugation at 200,000 g for 60 min. Analysis by sucrose density gradient ultracentrifugation showed that uCR1 was sedimenting in fractions larger than 19 S, whereas sCR1 was found as expected in fractions smaller than 19 S. The addition of detergents reduced the apparent size of uCR1 to that of sCR1. After gel filtration on Sephacryl-300 of normal urine, the fractions containing uCR1 were found to be enriched in cholesterol and phospholipids. The membrane-association of uCR1 was demonstrated by analyzing immunoaffinity purified uCR1 by electron microscopy which revealed membrane-bound vesicles. The apparent molecular mass of uCR1 was 15 kD larger than E-CR1 and sCR1 when assessed by SDS-PAGE and immunoblotting. This difference in size could not be explained on the basis of glycosylation only, since pretreatment with N-glycosidase F reduced the size of all forms of CR1; however, the difference in regular molecular mass was not abrogated. The structural alleles described for E-CR1 were also found for uCR1. The urine of patients who had undergone renal transplantation contained alleles of uCR1 which were discordant with E-CR1 in 7 of 11 individuals, indicating that uCR1 originated from the kidney. uCR1 was shown to bind C3b-coated immune complexes, suggesting that the function of CR1 was not destroyed in urine. A decrease in uCR1 excretion was observed in 3 of 10 patients with systemic lupus erythematosus, corresponding to the three who had severe proliferative nephritis, and in three of three patients with focal sclerosis, but not in six other patients with proteinuria. Taken together, these data suggest that glomerular podocytes release CR1-coated vesicles into the urine. The function of this release remains to be defined, but it may be used as a marker for podocyte injury.

Inherited structural and quantitative polymorphisms of C3b receptor (CR1) in normals and patients with glomerular diseases.

The erythrocyte C3b receptor (CR1) has been studied for its structural and quantitative polymorphisms in normal Indian individuals and in patients with glomerular diseases. In the normal Indian population, purification of CR1 by immunoprecipitation or C3b-Sepharose affinity column and subjecting it to electrophoresis showed the existence of two types of structural polymorphic patterns with M(r) of 190 kDa and 220 kDa, and with gene frequencies of 0.975 and 0.025, respectively. The gene frequencies of these alleles remain unaltered in the patient population. Evaluation of CR1 levels in the normal Indian population revealed a trimodal distribution of CR1 number suggesting a co-dominant allelic pattern (L and H alleles) for the quantitative expression of CR1 with gene frequencies of 0.523 and 0.477, respectively. In our earlier study we have shown that there is a decreased expression of CR1 on the erythrocytes of patients with acute glomerulonephritis. Since this decrease in the CR1 level in patients is an acquired characteristic, it may not be the level controlled by the LL homozygous alleles. The discrepancy in the gene frequencies of the structural and quantitative polymorphic alleles in normal individuals show that they are not linked to each other. In our earlier study, we showed that the affinity constant of C3b-CR1 binding in different individuals remains the same irrespective of the number of CR1 on the erythrocyte surface. Comparison of this result with the present investigation shows that there is no functional difference among various structural polymorphic forms of CR1 and the susceptibility to glomerular diseases is not associated with any of the CR1 polymorphic patterns.

Isolation and biochemical characterization of the iC3b receptor of Candida albicans.

In an effort to identify the protein structure on Candida albicans, pseudohyphal forms which had been shown earlier to bind human iC3b, a protein of about 42 kDa (p42), were obtained from lysates of pseudohyphal forms by absorption with C3(H2O)-Sepharose. An antiserum raised in rabbits against this protein effectively inhibited adherence of sheep erythrocytes carrying iC3b (EAC3bi) to pseudohyphal forms. p42 cross-reacted with OKM-1, a monoclonal antibody directed against the human complement receptor type 3 (CR3, CD11b). This protein, p42, was designated p42-CR3. The antiserum against p42-CR3 was used for further purification of lysates by affinity chromatography. Three proteins of 66, 55, and 42 kDa were isolated. All were recognized by OKM-1 in immunoblots (p66-, p55-, and p42-CR3). The different proteins were separated and treated with neuraminidase and endoglycosidase F. Almost complete deglycosylation of the p66-CR3 protein was obtained after treatment with neuraminidase, indicating a high degree of glycosylation. Neuraminidase also had an effect on p55-CR3, but not on p42-CR3. Endoglycosidase F did not alter any of the three proteins. In ligand blots, p42-CR3 bound C3(H2O), C3b, and iC3b but not C3d; p55-CR3 clearly reacted with C3(H2O) and weakly reacted with C3b and iC3b. p66-CR3 never showed reactivity. It is suggested that p55 and p66 represent glycosylated forms of p42-CR3. Although C. albicans CR3 and human CR3 cross-react and bind identical ligands, the two receptors differ in structure.

Ligand specificities of mouse complement receptor types 1 (CR1) and 2 (CR2) purified from spleen cells.

Murine complement receptor type 2 (MCR2) is homologous to human CR2, whereas murine CR1 (MCR1) is structurally and evolutionary different from human CR1. Since ligand specificities of MCR1 and MCR2 are not completely clarified, we analyzed their functional characteristics to correlate them with structural information obtained in molecular biological studies. MCR1 and MCR2 purified from spleen cells were incubated with thiol-Sepharose bearing murine C3b, iC3b, or C3d in the presence or absence of various anti-MCR1 or -MCR1/MCR2 mAbs. Bound and free MCR1 and MCR2 were quantitated by Western blotting or two-site immunoradiometric assay. MCR2 bound to C3d and iC3b similarly efficiently, and 5-fold less efficiently to C3b. These bindings were completely inhibited by MCR1/MCR2-crossreactive antibodies 7G6 and 4E3. MCR1 bound to C3b efficiently and this was partially inhibited by MCR1-monospecific antibody 8C12, but not by 7G6 and 4E3. Combinations of 8C12 and 7G6 or 4E3 completely inhibited MCR1 binding to C3b. Therefore, two binding sites, one unique to MCR1 and the other shared with MCR2, are involved in MCR1 binding to C3b. MCR1 bound also to C3d and this was completely inhibited by 7G6 and 4E3. The binding of this solubilized MCR1 to C3d was as efficient as that of MCR2 to C3d. It seems, therefore, that the site shared by MCR1 and MCR2 that is recognized by both 7G6 and 4E3 binds to C3d and less efficiently to C3b. These results clarify the ligand specificities of MCR1 and MCR2.

Isolation and characterization of complement receptor type 1 from rat glomerular epithelial cells.

Complement receptor type 1 (C3b/C4b receptor, CR1) is known to be present in human glomerular epithelial cells (GEC) in vivo. The presence of CR1 has not been documented in rat glomeruli, although cultured rat GEC appear to express CR1 based upon their ability to rosette with complement-coated erythrocytes. In this study, we establish that CR1 is present in cultured rat GEC: (1) by isolating a 200 kDa protein from detergent-solubilized cultured rat GEC through the use of C3b affinity chromatography; (2) by Western blotting studies demonstrating reactivity of anti-human CR1 antibodies with this protein from cultured GEC; and (3) by demonstrating that C3b binding to GEC monolayers exhibits low affinity and that an estimate of the number of binding sites is 6700 per cell, both of which are comparable to that seen for CR1 in human blood cells. Furthermore, we show that CR1 is also present in rat glomeruli by Western blotting studies with anti-human CR1. Anti-human CR1 also identifies a 70 kDa protein from cultured GEC and isolated glomeruli. This 70 kDa protein is likely to be the CR1-like protein, designated Crry, which was initially identified in the mouse and has significant homology to human CR1. Crry may be present in rat GEC instead of decay accelerating factor, which is present in human GEC.