Cyanogen bromide cleavage of bovine secretory component and its tryptic fragments

1. Five-domain bovine secretory component and its two-domain and three-domain tryptic fragments have been treated with cyanogen bromide. 2. N-terminal sequence analysis of the purified products showed that cleavage occurred within the disulphide bridged polypeptide loop of domain 2. The site lies within the region that binds IgM and IgA dimers. 3. The relative binding of the CNBr fragments to IgM has been measured and indicates that domains 1 and 3 are directly involved. 4. A possible role for domain 2 is less clear and domains 4 and 5 do not participate in binding.     

Physicochemical and immunochemical studies on bovine IgA and glycoprotein-a

1. Bovine secretory IgA (SIgA) from colostrum (mol. wt. about 410,000) is composed of four alpha-chains (mol. wt. 61,000), four light chains (mol. wt. 23,000) and one molecule of glycoprotein-a (mol. wt. 70,000-86,000). The alpha-chains are antigenically and physicochemically distinct from the heavy chains of IgM, IgG1 and IgG2 while the light chains are identical to those occurring on other bovine immunoglobulins. Glycoprotein-a and bovine free secretory component are identical and the former name should be abolished. Much of this protein is covalently bonded to IgA. 2. The gel filtration behavior of serum IgA suggests it is a dimer. 3. The elution behavior of IgA and SIgA from ion-exchange columns and the solubility characteristic of SIgA in the presence of Zn2+ are similar to those of human and rabbit IgA. 4. The disc electrophoretic behavior of IgA and SIgA are distinct from IgM, dimeric IgG1, 7-S IgG and glycoprotein-a. Dimeric IgG1 (s20,w = 9.5) is abundant in colostrum and is similar in size to SIgA. 5. Bovine IgA shows physicochemical and immunochemical heterogeneity when studied by gel filtration, disc electrophoresis, immunoelectrophoresis and ultracentrifugational analyses. Lacrimal and nasal SIgA possess antigenic determinants absent on colostral SIgA.     

Effect of a disulfide-interchange enzyme on the assembly of human secretory immunoglobulin A from immunoglobulin A and free secretory component.

A disulfide-interchange enzyme from rat liver microsomes was found to promote binding in vitro of human free secretory component (SC) to dimeric serum-type IgA containing J chain, as assessed by immune precipitation and gel filtration. This effect was greater withe native than with partially reduced SC. Most of the bound SC was covalently linked, as determined by electrophoresis in polyacrylamide gels in detergent. The enzyme did not promote binding of native or partially reduce SC to IgG, IgA monomer, IgA dimer without J chain, or IgM. In the case of IgM, the enzyme did, however, promote covalent bonding of previously non-covalently linked SC. The results overall suggest that a disulfide-interchange enzyme could play a role in vivo in the cell-associated assembly of secretory IgA by promoting the covalent attachment of SC to a dimer of serum-type IgA and that the J chain in the IgA dimer contributes to the enzyme effect.     

The sites of tryptic cleavage in bovine secretory component: structural and functional implications

Tryptic fragments from bovine secretory component and sIgA have been separated by HPLC and/or SDS polyacrylamide gel electrophoresis and electroblotting. Their N-terminal amino acid sequences have been determined and their positions in the secretory component molecule deduced by homology with the amino acid sequences of human secretory component and rabbit polyimmunoglobulin receptor. Taken in conjunction with the known binding affinities of the tryptic fragments, the results imply that the three most N-terminal domains of secretory component are directly involved in binding IgM and IgA dimers. The results also favour the concept of an extended 'zig-zag' structure for the secretory component molecule.     

Fragmentation and reduction of bovine secretory component. Preparation of a biologically active fragment and some evidence for a multiple-domain structure.

A tryptic fragment (A) of Mr 25000 was prepared from bovine secretory component. The fragment binds polymeric immunoglobulin, although 9 times less effectively than secretory component on a molar basis. The fragment has four buried half-cystine residues and two exposed half-cystine residues. It gives rise to two fragments of Mr 11000-13000 on prolonged digestion with trypsin, and these do not bind polymeric immunoglobulin. It is proposed that fragment A consists of two immunoglobulin-like domains. Bovine secretory component was found to have 9-11 buried half-cystine residues and four exposed half-cystine residues. Reduction and alkylation of the exposed residues decreases the binding of polymeric immunoglobulin by 3-fold. Initial tryptic cleavage of bovine secretory component gives a fragment (Q) disulphide-bridged to a further fragment (T). Fragment Q is similar in size to a three-domain immunoglobulin fragment, and fragment T is similar in size to a two-domain immunoglobulin fragment. The two-domain fragment A is derived from fragment Q by further tryptic cleavage. The results are compatible with the proposal by Mostov, Friedlander & Blobel [(1984) Nature (London) 308, 37-43] that secretory component consists of multiple immunoglobulin-like domains. The results also indicate that optimal binding of polymeric immunoglobulin involves several domains stabilized by an exposed disulphide bridge.     

Oligosaccharide side chains on human secretory IgA serve as receptors for ricin

Secretory IgA (sIgA) Abs are polymeric Igs comprised of two or more IgA monomers joined together at their C termini and covalently associated with a 70-kDa glycoprotein called secretory component. As the predominant Ig type in gastrointestinal sections, sIgA Abs are centrally important in adaptive immunity to enteropathogenic bacteria, viruses, and toxins. In this study, we demonstrate that sIgA Abs may also function in innate defense against ricin, a naturally occurring, galactose-specific plant lectin with extremely potent shiga toxin-like enzymatic activity. In lectin blot overlay assays, we found that ricin bound to secretory component and the H chain of human IgA, and this binding was inhibited by the addition of excess galactose. The toxin also recognized IgM (albeit with less affinity than to IgA), but not IgG. Ricin bound to both human IgA1 and IgA2, primarily via N-linked oligosaccharide side chains. At 100-fold molar excess concentration, sIgA (but not IgG) Abs inhibited ricin attachment to the apical surfaces of polarized intestinal epithelial cells grown in culture. sIgA Abs also visibly reduced toxin binding to the luminal surfaces of human duodenum in tissue section overlay assays. We conclude that sIgA Abs in mucosal secretions may serve as receptor analogues for ricin, thereby reducing the effective dose of toxin capable of gaining access to glycolipid and glycoprotein receptors on epithelial cell surfaces.     

Characterization of autoantibodies to ferritin in canine serum

Ferritin-binding proteins circulating in mammalian blood are thought to be involved in the clearance of ferritin. The present study characterizes canine serum autoantibodies (IgM and IgA) that react with ferritin. Canine IgM and IgA bound to bovine spleen ferritin as well as canine liver ferritin. To examine the specificity of canine IgM and IgA to ferritin H and L subunits, we used canine heart ferritin and canine liver ferritin with H/L subunit ratios of 3.69 and 0.43, respectively. Canine IgM and IgA recognized both of the H- and L-subunit-rich isoferritins, showing that their binding activities to ferritin depend on the H-subunit content. Recombinant bovine H-chain ferritin homopolymer expressed in a baculovirus expression system bound more with IgM and IgA than the recombinant L-chain homopolymer expressed under the same conditions. These results suggest that canine IgM and IgA recognize H-subunit-rich isoferritins, and that H-subunit-rich isoferritins are cleared from the circulation more rapidly than L-subunit-rich isoferritins.     

A novel receptor for secretory component on porcine mononuclear cells

Porcine mononuclear cells from peripheral blood separated by Ficoll-Hypaque gradient technique bound secretory IgA preferentially but not serum IgA or IgG after capping with anti-Ig. When the cells were incubated with free secretory component and washed, serum IgA binding was facilitated. Thus, the results indicate that a subpopulation of porcine circulating mononuclear cells bear surface receptors for secretory component (SC-receptor).     

Selective adherence of IgA to murine Peyer's patch M cells: evidence for a novel IgA receptor

M cells represent the primary route by which mucosal Ags are transported across the intestinal epithelium and delivered to underlying gut-associated lymphoid tissues. In rodents and rabbits, Peyer's patch M cells selectively bind and endocytose secretory IgA (SIgA) Abs. Neither the nature of the M cell IgR nor the domains of SIgA involved in this interaction are known. Using a mouse ligated ileal loop assay, we found that monoclonal IgA Abs with or without secretory component, but not IgG or IgM Abs, bound to the apical surfaces of Peyer's patch M cells, indicating that the receptor is specific for the IgA isotype. Human serum IgA and colostral SIgA also bound to mouse M cells. The asialoglycoprotein receptor or other lectin-like receptors were not detected on the apical surfaces of M cells. We used recombinant human IgA1 and human IgA2 Abs and domain swapped IgA/IgG chimeras to determine that both domains Calpha1 and Calpha2 are required for IgA adherence to mouse Peyer's patch M cells. This distinguishes the M cell IgA receptor from CD89 (FcalphaI), which binds domains Calpha2-Calpha3. Finally, we observed by immunofluorescence microscopy that some M cells in the human ileum are coated with IgA. Together these data suggest that mouse, and possibly human, M cells express an IgA-specific receptor on their apical surfaces that mediates the transepithelial transport of SIgA from the intestinal lumen to underlying gut-associated organized lymphoid tissues.     

Reconstituted Human Polyclonal Plasma-derived Secretory-like IgM and IgA Maintain the Barrier Function of Epithelial Cells Infected with an Enteropathogen

Intravenous administration of polyclonal and monoclonal antibodies has proven to be a clinically valid approach in the treatment, or at least relief, of many acute and chronic pathologies, such as infection, immunodeficiency, and a broad range of autoimmune conditions. Plasma-derived IgG or recombinant IgG are most frequently used for intravenous or subcutaneous administration, whereas a few IgM-based products are available as well. We have established recently that secretory-like IgA and IgM can be produced upon association of plasma-derived polymeric IgA and IgM with a recombinant secretory component. As a next step toward potential future mucosal administration, we sought to unravel the mechanisms by which these secretory Igs protect epithelial cells located at the interface between the environment and the inside of the body. By using polarized epithelial Caco-2 cell monolayers and Shigella flexneri as a model enteropathogen, we found that polyspecific plasma-derived SIgA and SIgM fulfill many protective functions, including dose-dependent recognition of the antigen via formation of aggregated immune complexes, reduction of bacterial infectivity, maintenance of epithelial cell integrity, and inhibition of proinflammatory cytokine/chemokine production by epithelial cells. In this in vitro model devoid of other cellular or molecular interfering partners, IgM and secretory IgM showed stronger bacterial neutralization than secretory IgA. Together, these data suggest that mucosally delivered antibody preparations may be most effective when combining both secretory-like IgA and IgM, which, together, play a crucial role in preserving several levels of epithelial cell integrity.     

Rat secretory component binds poorly to rodent IgM.

Our previous studies and those of others indicated that human secretory component (SC), the five domain extracellular portion of the poly Ig receptor, binds avidly to both pIgA and IgM. In this study we report that in rodents, SC binds primarily to pIgA. Rat secretory component was isolated from bile and radiolabeled to known specific activity with 125I. Radiolabeled rat SC was incubated with rat and mouse monoclonal proteins for 1 h at room temperature and overnight at 4 degrees D. Binding of 125I-rat SC to Ig was determined in two ways: 1) immunoprecipitation of putative 125I-rat SC-Ig complexes with anti-L chain antibodies; 2) HPLC gel filtration on an analytical TSK 4000 column that separated free 125I-rat SC from 125I-rat SC bound to Ig. Both methods of analysis yielded similar results. Rat and mouse polymeric (p) IgA bound rat SC with high avidity, although the binding activity of the IgM from either species was virtually nil. The number of SC-binding sites on rat polymeric Ig was determined by immunoprecipitation of mixtures of rat pIg with saturating concentrations of 125I-rat SC and yielded values of 1.0 and 0.05 for rat pIgA and IgM, respectively. The significance of these findings with respect to the biologic function of the pIg R in rodents and the nature of the pIg R-binding site on pIg is discussed.     

IgG antibodies to secretory component in normal human serum

While isolating free secretory component (FSC) by monoclonal antibody affinity chromatography, we demonstrated FSC-IgG complexes in human milk. We hypothesized that IgG antibody to secretory component (SC) might be transported into the milk from the serum. We therefore examined sera from 10 normal adults and 10 infants for IgG capable of binding to FSC in an enzyme-linked immunosorbent assay. Eight of 10 normal adult sera and nine of 10 infant sera demonstrated IgG binding to FSC with titers ranging from 1:54 to 1:4096. Quantitation of the IgG bound to FSC was hampered in adult sera by the binding of IgM and polymeric IgA to the FSC. Quantitation in five infant sera ranged from 0.5 to 6.4 micrograms/ml. A pepsin digest of an IgG fraction of serum demonstrated binding of the F(ab')2 fragments to the FSC. The specificity of the antibodies in human serum was evaluated by examining the binding to secretory IgA (sIgA) and FSC isolated from pooled human milk and polymeric IgA isolated from the ascitic fluid of a patient with an IgA myeloma. Eight of the 10 adults had antibody specific for FSC. Three of the eight, all female, also had antibody specific for sIgA. Two of the eight had antibody either to FSC and sIgA or to FSC plus an antibody that could bind to an epitope shared by sIgA and FSC. Competition experiments with monoclonal antibodies to human secretory component and sIgA were used to confirm and further define these specificities. The results of this study indicate that antibody to SC is common in normal adult and infant sera. The majority of antibodies seem to be directed against epitopes present on FSC but not on sIgA, which suggests sensitization to circulating or membrane-bound SC. The significance of these antibodies in normal human sera remains to be elucidated.     

Peculiar secretory IgA system identified in chickens. II. Identification and distribution of free secretory component and immunoglobulins of IgA, IgM, and IgG in chicken external secretions.

A homologue of a free secretory component (SC) was identified in chicken intestinal secretion by criteria based on its antigenic relationship with intestinal secretory IgA (SIgA), molecular size, sugar content, and electrophoretic mobility, as well as its elution characteristic from ion-exchange chromatography. SC was obtained in a form free from IgA from the intestinal secretion by salting out and DEAE chromatography, followed by density ultracentrifuguation or Sephadex G-200 gel-filtration. However, the free SC revealed some antigenic deficiency when compared to bound SC of intestinal SIgA and showed a failure of binding to serum-type-polymeric IgA of biliary IgA in vitro. Several kinds of chicken external secretions were examined for detection of SC and immunoglobulin classes of IgG, IgA, and IgM. In spite of the wide distribution of immunoglobulins in the external secretions, SC antigen could be detected only in intestinal secretion. Most IgA in the secretions had a molecular structure of a tetramer of serum-type IgA, lacking in SC and having 17S to 18.5S and 600,000 to 700,000 daltons. On the other hand, IgA in the intestinal secretion showed close similarity to the mammalian SIgA, associated with SC and having 11.2S and 350,000 daltons. Presence of antibody activity in the intestinal IgA to avian reovirus was confirmed by plaque reduction tests.     

A novel IgA receptor expressed on a murine B cell lymphoma.

The specificity and properties of a novel IgA receptor expressed on the surface of a tissue culture-adapted B cell lymphoma, T560, that originated in murine gut-associated lymphoid tissue, have been explored. Like the IgA receptors of murine T and splenic B cells studied by others, the T560 IgA receptor is trypsin sensitive and neuraminidase resistant and is up-regulated on T560 cells by exposing them overnight to high concentrations of polymeric IgA. Unlike them, the T560 IgA receptor is inhibited by low concentrations of IgM and high concentrations of IgG2a and IgG2b, binds at pH 4.0 but not at pH 8.0, is down-regulated by activation of protein kinase C and is sensitive to phosphatidylinositol-specific phospholipase C, indicating that it is glycosyl phosphatidylinositol-linked to the cell membrane. It is not a cell-bound form of galactosyl transferase, does not appear to bind to Ig through carbohydrate residues and does not react specifically with antibody to secretory component. It may be a completely new, cross-reactive receptor, perhaps related in some way to the polymeric Ig receptor or to the receptor for IgA expressed on the apical surface of Peyer's patch M cells, which is known to cross-react with IgG. Alternatively, it may be homologous to the highly IgA-specific Fc alpha R of T cells but, perhaps because of its glycosyl phosphatidylinositol linker, may have an ability to move and interact with other Ig receptors on the cell surface such that Ig bound to them are cross-inhibitory.     

Inhibition of acrosin by oviductal secretory immunoglobulin A

A major inhibitor of acrosin in rhesus monkey and rabbit oviduct fluid, isolated by isoelectrofocusing in sucrose gradients, displayed a broad peak in the acidic region of the column and was demonstrated to contain secretory IgA specific for acrosin. Its identity was established by immunodiffusion, by the removal of acrosin inhibition with antisera to IgA (α-chain), and by its correct molecular weight during ultracentrifugation. Purified human serum IgA also inhibited rabbit, rhesus monkey, and human acrosins, but neither purified human IgG nor IgM had any inhibitory effect on these acrosins. Neither oviduct fluid secretory IgA nor purified human serum IgA inhibited the activity of bovine pancreatic trypsin. The high specificity of secretory IgA for acrosin and its presence in every rabbit and rhesus monkey oviduct fluid specimen examined suggests a possible regulatory role for this antibody in reproduction.     

A study of the association of human secretory component with IgA and IgM proteins.

Human secretory component (SC) was isolated from colostral whey, and the binding of 125I-SC to purified IgA and IgM monoclonal proteins was studied using two methods to separate free from immunoglobulin-bound 125I-SC: a) gel filtration on Sephadex G-200, and b) precipitation of 125I-SC-Ig complexes with anti-Ig antibody. Both IgA dimeric proteins and IgM pentamers bound 125I-SC with approximately one SC-binding site per mole of polymer and similar affinity. Assuming a reversible equilibrium, an apparent association constant congruent to 10-8 M-1 was calculated to govern the binding of 125I-SC to immunoglobulin polymers. The assignment of a single association constant may be an oversimplication, particularly for the case of IgA polymers, since evidence was obtained that disulfide bonds were formed in the 125I-SC-IgA complex. Despite the complexity of the reaction, binding of 125I-SC to both IgA and IgM polymers could be analyzed by standard methods of saturation analysis, and both were shown to have a similar affinity for 125I-SC. No differences were noted in the affinity of 125I-SC binding to the IgA1 and IgA2 subclasses. Binding of monomeric IgA and IgM proteins could not be measured and was at least 100-fold lower than that found for IgA and IgM polymers. Complexes of 125I-SC with IgA dimers were presumed to involve covalent bond formation, since these complexes did not dissociate in guanidine-HCl. One IgA2 trimer did not form a covalent bond since it was completely dissociated in guanidine. In contrast, 125I-SC-IgM complexes were dissociated in denaturing solvent, indicating that such complexes were held together primarily by non-covalent bonds. Experiments with (Fc)5 mu isolated by high temperature tryptic digestion of IgM showed that binding of 125I-SC was to the Fc region of IgM proteins. It was suggested that the binding of SC with similar affinity to both IgA and IgM polymers may be important in the biologic function of both these immunoglobulin classes.     

Translocation of dimeric IgA through neoplastic colon cells in vitro.

We studied the translocation of dimeric IgA across epithelium, using neoplastic human colon cells in culture as a source of epithelial cells, and immunoelectronmicroscopy with peroxidase-labeled antigens and antibodies. The cells had some of the ultrastructural characteristics of normal, mature epithelial cells, i.e., polarity, desmosomal junctions, and secretory component on their basal and lateral plasma membranes. Horseradish peroxidase-labeled dimeric IgA, exposed to the cells at 0 degrees C, bound selectively to secretory component on the cell surfaces. At 37 degrees C, the bound dimeric IgA was taken into the cells by endocytosis and transported apically through the cytoplasm in vesicles. After 30 min, IgA was discharged across the apical surface. Neither colchicine (10(-4) M) nor cytochalasin B (10(-5) M) interfered with binding or endocytosis of dimeric IgA, but colchicine inhibited intracellular transport of the IgA-containing vesicles. These experiments demonstrated that dimeric IgA can be transported through living intestinal epithelial cells in vitro. The transport includes 1) specific binding of IgA dimers to secretory component on plasma membranes, 2) endocytosis of IgA in vesicles, 3) transcytoplasmic transport of the IgA-containing vesicles by a process involving microtubules, and 4) discharge of IgA at the apical surfaces.     

Tryptic digestion of bovine secretory IgA at elevated temperature and in urea. Isolation of SC domain 1 which is covalently bound to IgA dimer and binds non-covalently to IgM

1. Tryptic cleavage sites in bovine secretory component (SC) which become inaccessible when SC is bound to IgA dimer remained inaccessible at 60 degrees C and in 4 M urea at 37 degrees C. 2. This suggests the presence of strong interactions compatible with published affinity constants of ca 10(8) M-1. 3. In 5 M urea at 37 degrees C further cleavage of bound SC did occur to produce a fragment consisting of domain 1 which was disulphide bridged to the IgA dimer. 4. Binding studies on the isolated fragment showed that domain 1 did not account for all the binding by SC. 5. Cleavage of the isolated fragment with iodosobenzoic produced a smaller fragment consisting of the n-terminal third of domain 1 (residues 1-35). This N-terminal fragment showed significant binding.     

Degradation of human secretory IgA1 and IgA2 by Entamoeba histolytica surface-associated proteolytic activity

The protozoan Entamoeba histolytica is the etiological agent of amebiasis, an infection with high prevalence worldwide. The host-ameba relationship outcome depends on parasite and host factors, and among these is secretory IgA. These antibodies reduce mucosal colonization by pathogens and neutralize a variety of toxins and enzymes. The functionality of secretory IgA depends on its integrity. Some bacteria produce IgA proteases that cleave mainly the IgA1 subclass; live E. histolytica trophozoites, and other ameba fractions are also able to degrade human IgA. The aim of this study was to determine if serum and secretory IgA, its subclasses and secretory component, are degraded by cysteine proteases, which are present and active on the surface of glutaraldehyde-fixed amebas. It was observed that secretory IgA1, IgA2, free and IgA-bound secretory component were degraded by E. histolytica surface-associated cysteine proteinases. Secretory IgA2, although it was degraded, conserved its ability to agglutinate live amebas better than IgA1. Therefore, while specificity of known ameba cysteine proteases is cathepsin B-like and is different from bacterial IgA proteases, IgA2 was functionally more resistant than IgA1 to ameba surface-associated cysteine protease degradation, similar to the greater resistance of IgA2 to bacterial IgA-specific proteases.     

Purification and Characterization of Canine Serum Ferritin-binding Proteins

Ferritin-binding protein (FBP) is known to interact with circulating ferritins in mammals. Canine FBPs were purified from canine serum by affinity chromatography and were identified as IgM, IgG, and IgA by immunoblotting with alkaline phosphatase-labeled antibodies to canine IgM, IgG, and IgA heavy chains. Following further purification by application to a Sephacryl S-300 column, canine FBPs were separated into 81.3- and 27.7-kDa bands by sodium dodecyl sulfate-polyacryamide gel electrophoresis, and the 81.3-kDa band reacted with the anti-canine IgM heavy chain antibody. Purified canine FBP bound to canine liver ferritin, but not to canine albumin and transferrin. FBP showed greater binding to the expressed bovine ferritin H-chain homopolymer than to the expressed bovine ferritin L-chain homopolymer. The binding of FBP with canine liver ferritin was dose-dependently inhibited by anti-rat liver ferritin antibody, and the anti-ferritin antibody dissociated the bound FBP in a dose-dependent manner, even after binding FBP with liver ferritin. The canine ferritin H subunit peptide fragment with amino acid residues 148–155 (NH₂-GDHVTNLR-COOH) in its C-terminal region was recognized by FBP. These results indicate that canine serum FBPs are autoantibodies to ferritin (IgM, IgG, and IgA) and that anti-ferritin autoantibody (IgM) recognizes the C-terminal region of ferritin H subunit.