Isotypic and allotypic analysis with monoclonal antibodies and jacalin of 309 serum monoclonal IgA from French and Japanese myeloma patients.

The subclass and allotype distribution of serum monoclonal IgA from myeloma patients was determined by ELISA with monoclonal antibodies in two French and one Japanese laboratory. In addition, the French sera were tested for their reactivity with the lectin jacalin. No significant difference in the isotypic distribution between French and Japanese series could be demonstrated: kappa/lambda ratios were 0.99 and 1.17, and the IgA1 subclass accounted for 93.9% and 91% of cases in the French and Japanese studies, respectively. Five out of 7 myeloma IgA2 from Japan and only one of the 12 IgA2 from France belonged to the A2m(2) allotype (P less than 0.01). All 219 IgA1 tested reacted with jacalin by immunoelectrophoresis (IEP), although with variable intensities. Among IgA2 proteins, only one (of the A2m(1) allotype) yielded a precipitating line with jacalin by IEP. Molecular analysis demonstrated that this protein was an IgA1-IgA2 hybrid bearing most of the A2m(1) epitopes.     

The heterogeneity of bovine IgG2--V. Differences in the primary structure of bovine IgG2 allotypes.

The partial amino acid sequences of the gamma chains of the bovine IgG2a(A1) and IgG2a(A2) allotypes were determined. Sequence differences were found in the CH1 domain, the hinge region, and the CH3 domain. The hinge regions displayed only 71.4% similarity and all of the differences were of a radical nature. The A2 hinge has isoleucine instead of serine at 229, histidine for asparagine at 235, proline for histidine at 238, and cysteine instead of proline in position 234; the latter has the potential for forming an additional interheavy chain disulphide bridge. The occurrence of such a bridge could explain the presence of a pepsin fragment consisting of the hinge region and the Fc. A corresponding fragment is not obtained with the A1 allotype. Both allotypes have a shortened hinge region and a truncated CH2 domain. This feature is characteristic of all reported sequences of IgG2 proteins but not IgG1 in cattle and the goat. This structural feature may be important in subclass-specific recognition by Fc gamma receptors in ruminants. A surprising discovery was the occurrence of five substitutions in the CH3 domain of the IgG2a(A2) in comparison with the A1, which are shared with the CH3 of IgG1. These permit the occurrence of isoallotypic determinants and can explain the difficulty encountered in preparing A2-specific antisera during which adsorption with IgG1 is a routine procedure. The primary sequence data we report confirm the presence of major structural differences between the A allotypes of cattle that was suggested by previous work. The sequence of the A1 allotype most closely agrees with the two IgG2 sequences deduced from their nucleotide sequences whereas the sequence differences in the hinge and C-terminal CH3 make IgG2a(A2) unique. The structural differences between allotypes could have major consequences for such biological activities as phagocytosis, transepithelial transport, lymphocyte and complement activation.     

Binding of human IgA1 and IgA1 fragments to jacalin

Interaction of jacalin, an N-terminal galactose specific lectin, with human IgA1 and IgA1 fragments was investigated. IgA1 and all galactose containing fragments bound to jacalin-Sepharose, including Fab fragments containing only the galNac linked to serine-224 and Fc fragments containing four gal-galNac sequences. These data indicate that both the galNac and gal-galNac sequences can interact with jacalin. Jacalin precipitated IgA1 and the fragments F(abc)2, F(ab')2 and Fc in agar gel and from solutions. It also precipitated Fab' fragments in agar gel. Jacalin did not precipitate Fab fragments significantly. This suggests that, except for the single binding site on the Fab fragments containing the galNac linked to serine-224, jacalin itself also has a limited number of sites to interact with N-terminal galactose residues. ELISA studies revealed that intact IgA1 had a lower jacalin binding capacity than F(abc)2 fragments which lack CH3 domains, than F(ab')2 which lack the CH2 and CH3 domains, and than Fc fragments containing four gal-galNac sequences. This led to the conclusion that part of the galNac or gal-galNac sequences in intact IgA1 molecules are inaccessible to interaction with jacalin. Cleaving the C-terminal domains off may have induced a reorientation of the hinge region structure, including the orientation of the carbohydrate units.     

Human IgD and IgAl Compete for D-Galactose-Related Binding Sites on the Lectin Jacalin

Lectin selectivity for human Ig classes is based on carbohydrate differences. Earlier reports that the lectin jacalin precipitated human IgA were confirmed and supplemented by the current study, which demonstrates that jacalin also binds human IgD as evaluated by micro-ELISA and SDS-PAGE. Experimental findings indicated that: (i) Monoclonal and polyclonal (sera) IgD, IgA1, but not IgA2, IgM, or IgG1-4 reacted with jacalin. (ii) Six tested monoclonal IgD proteins each bound approximately equally to jacalin when antigenicity rather than protein concentration was measured: the results weigh against the presence of jacalin-detectable IgD subclasses or genetic variants. (iii) IgD and IgA1 both associated maximally in 4-8 h at 4 degrees C. There was no dissociation at 4 degrees C but limited dissociation occurred at 37 degrees C after 24 h. (iv) Both IgD and IgA1 were eluted from jacalin by galactose-related sugars. (v) IgD and IgA1 bind competitively to jacalin. The results suggested that jacalin reacts with O-linked oligosaccharide N-acetyl-galactosamine (GalN) residues found on the hinge region of both IgD and IgA1. Jacalin also interacted with one major and several minor unidentified sera proteins. The findings offer an approach to the isolation of serum polyclonal IgD and to the characterization of the unusual carbohydrates of the human delta heavy chain with respect to their function.     

Allotypic and isotypic aspects of human immunoglobulin A

The location of isotypic, isoallotypic and allotypic determinants is reviewed in the light of data obtained when specific antisera are tested with proteolytic fragments of IgA molecules or mutants of IgA obtained from patients with alpha-heavy chain disease. Isotypic determinants are distributed throughout the alpha chain constant regions although when intact IgA proteins are used as immunogens the CH3 domain is immunodominant. Alpha 1 subclass specific isotypic determinants are present in both Fab and Fc fragments. Amino acid sequence analysis suggest that alpha 1 subclass isotypic determinants depend on substitution in the CH1, hinge and/or CH2 domain. The isoallotypic determinants nA2m(2) appears to be located on the CH1 domain and appears to require disulphide-linked alpha chains for its expression. The allotypic determinant A2m(2) appears to be located in the CH3 domain involving residues 428, 458 and/or 467. The latter residues are present in both A2m(1) and A1 proteins which indicates that for A2m(1) to be the antithetical determinant of A2m(2), the determinant formed by residues 428, 458 and/or 467 in these proteins must be influenced by subclass differences which allows its expression in A2m(1) proteins and not in A1 proteins.     

Three new alleles of IGHG2 and their prevalence in Danish Caucasians,Mozambican Blacks and Japanese

The human IGHG2 gene locus is polymorphic, encoding two known allotypes of IgG2: G2m(n-) and G2m(n+). The allele prevalence varies greatly between different ethnic groups and individual genotypes correlate with the level of plasma IgG2 and with antibody responses to certain polysaccharide antigens. In this study, we present three new alleles of IGHG2 (IGHG2*03, 04, and 05), and a complete sequence specific PCR typing system allowing discrimination between the different allotypes of IgG2. A hitherto unknown allotype, which we name G2m(ny), is encoded by IGHG2*04 and differs from G2m(n-) by asparagine rather than serine in CH1 residue 75 and by phenylalanine rather than leucine in CH1 residue 76 (EU numbering 192 and 193). The polymorphic residues are probably surface exposed near the hinge region. The same residues are also found in IgG1, IgG3, and IgG4, and G2m(ny) is therefore an isoallotype that probably arises by gene conversion within the heavy chain locus. The IGHG2*04 allele is present among Danish Caucasians with a low prevalence (2.5%), but was not found in Japanese or Mozambicans. The two other new alleles (IGHG2*03 and IGHG2*05) both encode the G2m(n-) allotype. The IGHG2*03 allele encodes most of the IgG2 of the G2m(n-) allotype in Danish Caucasians.     

Monoclonal antibodies against isotypic and isoallotypic determinants of human IgA1 and IgA2: fine specificities and binding properties

We have analysed and compared the fine specificity and behavior in various immunoassays of 10 mouse monoclonal antibodies, from three independent laboratories, directed against IgA1, IgA2 or non-IgA2m(2). The following observations were made. (1) Although all of the monoclonal antibodies were specific for a particular IgA subclass or isoallotype in a radioimmunoassay, three of them were not specific when tested in indirect immunofluorescence on plasma cells derived from pokeweed-activated peripheral blood lymphocytes. In this highly sensitive system, contrary to direct immunofluorescence previously performed using formalin-fixed lymphoid tissue, the anti-IgA1 69.114 reacted with some of the IgA2 plasma cells, the anti-IgA2 DLDB7 reacted with some of the IgA1 plasma cells and the anti-IgA2 16.512 dimly reacted with all IgM plasma cells. (2) Among the eight anti-IgA subclass antibodies, seven were directed against the CH2 domain of IgA whereas the anti-IgA1 1-155-1 recognised an epitope destroyed by Streptococcus sanguis IgA1 protease and localised in the hinge region of IgA1. The two anti-isoallotype antibodies were directed against epitope(s) probably localised in the 65 C-terminal amino acid residues of the alpha-CH3 domain. All of the 10 antibodies were able to react with endogeneously produced surface IgA on B-cells. (3) Using monoclonal anti-IgA subclass antibodies in radioimmunoassay may be hazardous in the absence of knowledge of their affinity constants and of careful control experiments: some of the antibodies were not sensitive in radioimmunoassays designed to measure the serum titer of specific IgA1 and IgA2 antibodies. Moreover, major differences were observed between the different monoclonal reagents with respect to the influence of the size of IgA on a solid-phase sandwich radioimmunoassay. While three of the anti-IgA1 underestimated dimeric IgA relative to monomeric IgA, the fourth anti-IgA1 and all the anti-IgA2 overestimated dimeric IgA relative to monomeric IgA, by a factor sometimes close to 7.     

IgA1 half molecules in human multiple myeloma and the in vitro production of similar fragments from intact IgA1 molecules.

This paper describes an IgA related protein Vla which occurred in the serum and urine of a patient with multiple myeloma. The protein was isolated from urine; it had a molecular mass of 70,000 daltons. It was shown to be a two chain IgA half molecule, consisting of a deleted alpha heavy chain, with a molecular mass of 42,000 daltons, which was disulphide linked to a normal kappa type light chain. Fabc fragments were produced from an unrelated myeloma IgA. These had the same biochemical properties as protein V1a, except for the absence of the disulphide linkage between the deleted heavy chains and the light chains. Protein Vla and the Fabc fragments could both be cleaved by IgA1 protease from Streptococcus sanguis, which indicates the presence of the alpha 1 hinge region. An inventory of its antigenic determinants and their similarity to those of previously characterized F(abc)2 fragments, indicates that protein Vla, like the Fabc fragments, contains the CH1 and CH2 domains, but lacks most of the CH3 domain. The fact that cleavage by IgA1 protease from S. sanguis yields a Fab fragment but fails to yield a CH2 domain demonstrates that cleavage by the enzyme is not only restricted to the Pro227-Thr228 bond in the IgA1 hinge region.     

Cleavage of the human immunoglobulin A1 (IgA1) hinge region by IgA1 proteases requires structures in the Fc region of IgA

Secretory immunoglobulin A (IgA) protects the mucosal surfaces against inhaled and ingested pathogens. Many pathogenic bacteria produce IgA1 proteases that cleave in the hinge of IgA1, thus separating the Fab region from the Fc region and making IgA ineffective. Here, we show that Haemophilus influenzae type 1 and Neisseria gonorrhoeae type 2 IgA1 proteases cleave the IgA1 hinge in the context of the constant region of IgA1 or IgA2m(1) but not in the context of IgG2. Both C(alpha)2 and C(alpha)3 but not C(alpha)1 are required for the cleavage of the IgA1 hinge by H. influenzae and N. gonorrhoeae proteases. While there was no difference in the cleavage kinetics between wild-type IgA1 and IgA1 containing only the first GalNAc residue of the O-linked glycans, the absence of N-linked glycans in the Fc increased the ability of the N. gonorrhoeae protease to cleave the IgA1 hinge. Taken together, these results suggest that, in addition to the IgA1 hinge, structures in the Fc region of IgA are required for the recognition and cleavage of IgA1 by the H. influenzae and N. gonorrhoeae proteases.     

Effect of mutations in the human immunoglobulin A1 (IgA1) hinge on its susceptibility to cleavage by diverse bacterial IgA1 proteases

Components of the human immunoglobulin A1 (IgA1) hinge governing sensitivity to cleavage by bacterial IgA1 proteases were investigated. Recombinant antibodies with distinct hinge mutations were constructed from a hybrid comprised of human IgA2 bearing half of the human IgA1 hinge region. This hybrid antibody and all the mutant antibodies derived from it were resistant to cleavage by the IgA1 proteases from Streptococcus oralis and Streptococcus mitis biovar 1 strains but were cleaved to various degrees by those of Streptococcus pneumoniae, some Streptococcus sanguis strains, and the type 1 and 2 IgA1 proteases of Haemophilus influenzae, Neisseria meningitidis, and Neisseria gonorrhoeae. Remarkably, those proteases that cleave a Pro-Ser peptide bond in the wild-type IgA1 hinge were able to cleave mutant antibodies lacking a Pro-Ser peptide bond in the hinge, and those that cleave a Pro-Thr peptide bond in the wild-type IgA1 hinge were able to cleave mutant antibodies devoid of a Pro-Thr peptide bond in the hinge. Thus, the enzymes can cleave alternatives to their preferred postproline peptide bond when such a bond is unavailable. Peptide sequence analysis of a representative antibody digestion product confirmed this conclusion. The presence of a cleavable peptide bond near the CH2 end of the hinge appeared to result in greater cleavage than if the scissile bond was at the CH1 end of the hinge. Proline-to-serine substitution at residue 230 in a hinge containing potentially cleavable Pro-Ser and Pro-Thr peptide bonds increased the resistance of the antibody to cleavage by many IgA1 proteases.     

Purification and characterization of human immunoglobulin IgA1 and IgA2 isotypes from serum

A method is described for the simultaneous purification of IgA1 and IgA2 from human serum. Ammonium sulphate precipitation, gel filtration and ion-exchange chromatography on DEAE-Sephacel yielded a partially purified IgA preparation which was separated quantitatively into IgA1 and IgA2 by affinity chromatography on jacalin-Sepharose. The IgA1 which bound to the jacalin was eluted with 0.8 M D-galactose. The IgA1 preparation was apparently homogeneous by SDS-PAGE but contained a trace of C1-inhibitor and a second protein detected by immunoelectrophoresis. The IgA2 which did not bind to the jacalin was purified to apparent homogeneity by chromatography on columns of Protein G-Sepharose, Fastflow-S Sepharose and Superose 6. Typical yields were 95% and 58% for IgA1 and IgA2 respectively or 253 mg and 24 mg per 100 ml serum. The IgA1 and IgA2 were characterised by their reactivity with isotype specific monoclonal antibodies and sensitivity to bacterial proteinases. The IgA2 preparation apparently contained both allotypes, IgA2m(1) and IgA2m(2).     

The site of cleavage in human alpha chains of IgA1 and IgA2:A2m(1) allotype paraproteins by the clostridial IGA protease

Fc fragments of human immunoglobulin A(IgA) of IgA1 subclass and IgA2 subclass of A2m(1) allotype were prepared from IgA paraproteins by digestion with a protease from Clostridium sp. (M.O.-6). The N-terminal tetrapeptide of Val-Pro-Ser-Thr- for the Fc of IgA1 subclass, and that of Val-Pro-Pro-Pro- for the Fc of IgA2:A2m(1) allotype, were identified by sequence analysis. The site of cleavage by the protease was defined to be at the Pro-Val peptide bond, which is a common peptide bond present at 221-222 in both alpha chains. IgA of IgA2 subclass of A2m(2) allotype is resistant to the protease due to the different, Arg-Val, peptide bond at the same position.     

An enzyme-linked immunosorbent assay for the determination of the IgA subclass distribution of antigen-specific antibodies

An ELISA for the determination of the IgA subclass distribution of antigen-specific antibodies was developed using commercially available monoclonal anti-IgA1 anti-IgA2 subclass antibodies. Furthermore an anti-A2m allotype-specific antibody was included in the study. The specificity and sensitivity of the monoclonal anti-immunoglobulin antibodies used was analyzed using sera from normal and IgA class- or subclass-deficient individuals (with or without homozygous C alpha 1 subclass gene deletions). Human IgA1 and IgA2 hybridoma antibodies were also used. In this particular assay, only two out of four tested anti-IgA1 and two out of three tested anti-IgA2 antibodies proved to be specific for their corresponding IgA subclass. The anti-A2m(2) monoclonal antibody was shown to be specific for the corresponding allotype. These ELISA methods may facilitate further work on the regulation of IgA subclass production in man.     

Nucleotide sequence of chimpanzee Fc and hinge regions

The nucleotide sequence of the Fc and hinge regions of a chimpanzee monoclonal antibody has been determined. Most of the sequence is similar to the human IgG1 sequence. However, the chimpanzee hinge regions differs from the human hinge region in six of 48 nucleotides, which leads to three amino acid substitutions. Two of the amino acid changes are not conservative and may lead to differences in flexibility of the hinge. The chimp hinge sequence seems to be a combination of the human IgG1 hinge and the hinge sequence of a human IgG pseudogene. The implications of this difference for the evolution of human IgG subgroup is discussed. Despite differences in the hinge regions, the chimpanzee monoclonal antibody differs from the most closely related human IgG1 allotype only slightly more than the two most distantly related human allotypes differ from each other.     

Effect of serum albumin on the recovery of human IgA1 from immobilized jacalin

Published methods for affinity purification of human IgA1 on immobilized jacalin are based on binding through galNac residues in the IgA1 hinge region. The present study shows that in addition to this galNac-dependent binding an 'alternative' binding mechanism, involving protein-protein interactions, is operative. Moreover, human (HSA) and bovine (BSA) serum albumins were also observed to interact with jacalin through the 'alternative' mechanism, though much more weakly than IgA1. HSA and BSA did not interfere with the galNac-dependent binding of IgA1, but inhibited the 'alternative' binding of IgA1 to jacalin-Sepharose, probably by competition. Thus, IgA1 from serum samples was almost completely bound through the galNac-dependent mechanism, but part of the IgA1 from samples containing little or no HSA or BSA was bound by the 'alternative' mechanism. Washing of jacalin-Sepharose columns with excess BSA could disrupt the 'alternative' binding and subsequent washing with 0.8 M D-galactose in 0.5 M NaCl/PBS was sufficient to elute all IgA1. The 'alternative' binding to jacalin is probably not restricted to the above-mentioned proteins. Purification of IgA1 by precipitation with jacalin and subsequent gel filtration of the D-galactose-dissolved precipitate was not practical, since jacalin-IgA1 precipitates did not dissolve completely and new complexes were formed during the gel filtration procedure.     

The human G1m1 allotype associates with CD4+ T-cell responsiveness to a highly conserved IgG1 constant region peptide and confers an asparaginyl endopeptidase cleavage site

The human G1m1 allotype comprises two amino acids, D12 and L14, in the CH3 domain of IGHG1. Although the G1m1 allotype is prevalent in human populations, ~40% of Caucasiods are homozygous for the nG1m1 allotype corresponding to E12 and M14. Peptides derived from the G1m1 region were tested for their ability to induce CD4+ T-cell proliferative responses in vitro. A peptide immediately downstream from the G1m1 sequence was recognized by CD4+ T cells in a large percentage of donors (peptide CH3??-??). CD4+ T-cell proliferative responses to CH3??-?? were found at an increased frequency in nG1m1 homozygous donors. Homozygous nG1m1 donors possessing the HLA-DRB1*07 allele displayed the highest magnitudes of proliferation. CD4+ T cells from donors homozygous for nG1m1 proliferated to G1m1-carrying Fc-fragment proteins, whereas CD4+ T cells from G1m1 homozygous donors did not. The G1m1 sequence creates an enzymatic cleavage site for asparaginyl endopeptidase in vitro. Proteolytic activity at D12 may allow the presentation of the CH3??-?? peptide, which in turn may result in the establishment of tolerance to this peptide in G1m1-positive donors. Homozygous nG1m1 patients may be more likely to develop CD4+ T-cell-mediated immune responses to therapeutic antibodies carrying the G1m1 allotype.     

Loss of splice consensus signal is responsible for the removal of the entire C(H)1 domain of the functional camel IGG2A heavy-chain antibodies.

The molecular basis for the absence of the C(H)1 domain in naturally occurring heavy-chain antibodies of the camelids was assessed by determining the entire Camelus dromedarius gamma2a heavy-chain constant gene. The organization of the camel gamma2a constant heavy-chain gene obtained from a liver genomic library appears to be typical of all other mammalian gamma genes sequenced to date. It contains the switch, CH1, hinge, CH2, CH3, M1 and M2 exons. In contrast to the case in mouse and human heavy chain diseases, the camel gamma2a gene shows no major structural defect, and its equivalent CHI exon is intact. However, sequence analysis has revealed that the splicing site, immediately after the CH1 exon, is defective due to point mutations, especially the G(+1) to A(+1) transversion seems to be detrimental. It is concluded that the loss of the splice consensus signal is responsible for the removal of the entire CH1 domain in camel gamma2a heavy-chain immunoglobulins. Additionally, a closer analysis of the hinge exon suggests the possible involvement of transposons in the genetic variation of mammalian Cgamma hinges.     

The first monoclonal anti-G1m(x) antibody: production and usefulness in haemagglutination-inhibition assay.

Murine monoclonal anti-human Ig allotype antibodies have been described for a limited number of specificities. Now the first monoclonal anti-G1m(x) antibody has been produced by fusion of lymph gland cells of a mouse injected with G1m(zax)-positive myeloma proteins with cells of the myeloma cell line SP2/0. Several limiting dilutions resulted in one antibody-producing hybridoma, clone 3A12. The specificity of monoclonal antibody (mAb) 3A12 in the direct haemagglutination assay, as well as in the haemagglutination-inhibition (HAI) assay, is described. Neither cross-reactivity nor nonspecific inhibition with G1m(x)-negative Ig was seen. Typing for the G1m(x) allotype with mAb 3A12 gave results which are identical to those obtained with the conventional human antisera. With the production of this mAb, it now is possible to discriminate between the four main G1m alleles not only by HAI assay but also by other assay systems, of which the preliminary results are promising.     

Localization of the cleavage site specificity determinant of Haemophilus influenzae immunoglobulin A1 protease genes.

Immunoglobulin A1 (IgA1) proteases are produced by a number of different species of bacteria which cause infection at human mucosal surfaces. The sole substrate of these proteases is human IgA1. Cleavage is within the hinge region of IgA1, although there is variability in the exact peptide bond within the hinge region that is cut by a particular protease. The cleavage site of the Haemophilus influenzae type 1 protease is located four amino acids from the cleavage site of the type 2 enzyme. In this study, the region of the H. influenzae IgA1 protease gene (iga) that determines the cleavage site specificity was localized through the comparison of the type 1 and type 2 genes and the construction and analysis of type 1-type 2 hybrid genes. The hybrid genes were generated by in vivo and in vitro techniques which facilitated the selection and screening of randomly generated hybrids. The cleavage site determinant was found to be within a 370-base-pair region near the amino-terminal coding region, in one of two large areas of nonhomology between the two types of H. influenzae iga genes. DNA sequence analysis of the cleavage site determinant and surrounding regions did not reveal a simple mechanism whereby one enzyme type could be converted to the other type. Comparison of the type 2 gonococcal IgA1 protease gene to the two Haemophilus genes revealed a significant amount of homology around the cleavage site determinant, with the two type 2 genes showing greater homology.     

Cleavage of protein A-binding IgA1 with IgA1 protease from Streptococcus sanguis

Protein A-binding fractions of two IgA1 myeloma proteins failed to produce Fc fragments on digestion with IgA1 protease from Streptococcus sanguis. A polymeric protein A-binding IgA1 fraction yielded a protein A-non-binding monomer, which was further cleaved into Fab fragments but it did not yield Fc fragments. The protein A-binding fraction of a monomeric IgA1 yielded an IgA molecule lacking one Fab fragment. Subsequently, the remaining part of its cleaved alpha chain was degraded. Further digestion yielded Fab but not Fc fragments. Similarly, F(abc)2 and Fabc fragments, which lack the CH3 domain (8), yielded Fab fragments but not CH2 domains. Thus, the enzyme in addition to cleaving IgA in the hinge region, under certain conditions, also degrades its Fc fragments.