Partial amino acid sequence and genetic control of latent a2 allotype induced in rabbits by immunization with anti-a2 antibody

We have shown that after immunization of homozygous a1 rabbits of the B immunoglobulin (Ig) heavy chain haplotype with anti-a2 antibody (Ab) a population of molecules appears that has all of the serologic characteristics of the a2 allotype. We have now isolated these putative latent a2 molecules, have separated the heavy chains, and after enzymatic deblocking, have determined the first 19 N-terminal amino acids. For all eight allotype-associated residues, these putative latent a2 molecules have the amino acid residues typical of a2 allotype. As expected, the preimmune IgG from this a1a1 rabbit has the amino acids typical of the a1 allotype. Thus by partial amino acid sequence analysis, we provide additional evidence that the latent a2 allotype can be induced in a1a1 rabbits of the B heavy chain haplotype by immunization with anti-a2 Ab. Rabbits of other heavy chain haplotypes were also immunized with anti-a2 Ab and were tested for their ability to synthesize latent a2 allotype. Thus far, a1a1 rabbits of the A, B, C, and I heavy chain haplotypes all synthesize latent a2 allotype. In contrast, a3a3 rabbits of the G and H heavy chain haplotypes did not synthesize latent a2 allotype.     

A reevaluation of rabbit anti-allotype antibody for the presence of cross-reactive idiotypes. I. A species-specific idiotype on rabbit anti-a1 antibody is recognized by guinea pig anti-IdX antibody

Rabbit reagents previously thought to display specificity for a cross-reactive idiotype on anti-VHa allotype antibody from all tested rabbits have recently been shown to be contaminated with an induced (latent) molecule similar or identical to the original antigen (rabbit a1 or a2 allotype). In an attempt to circumvent this problem, we have immunized guinea pigs with rabbit anti-a1 allotype antibody to produce heterologous anti-idiotype antibody. The resulting guinea pig antibody (GP anti-R IdX) recognizes anti-a1 antibody from each of 17 immunized rabbits, and in four tested samples reacts with 22 to 100% of the molecules. Neither goat nor guinea pig anti-a1 reacts with the guinea pig anti-R IdX antibody, even though the goat, guinea pig, and rabbit anti-a1 Ab all recognize a similar set of a1 determinants. The reaction between IdX-bearing rabbit anti-a1 and guinea pig anti-R IdX is inhibited by the original antigen (a1 IgG), demonstrating that the IdX is at or near the antigen combining site of anti-a1 antibody. Immunoelectron microscopy of immune complexes supports this conclusion and demonstrates that the reactive site on the GP anti-R IdX is at or near its antigen combining site.     

Preferential assignment of allotype a1 globulin for the production of early IgM anti-para-azobenzenearsonate antibodies in heterozygous a1a3 rabbits.

Rabbits of allotype a1a3 were injected on days 0, 2, and 4 with mixtures containing equal amounts of pigeon erythrocytes (Prbc) coupled to para-azobenzenearsonate (AA) and to para-azobenzene-N-trimethylammonium (TMA). On day 6, the allotypes of antibody from plaque-forming cells (PFC) of the blood were determined by observing the inhibition of plaque formation by anti-allotype sera. Anti-AA PFC appeared to consist for the most part of cells making antibody of allotype a1 since 65% of them were inhibited by anti-a1 serum and only 8% by anti-a3. Anti-TMA PFC, on the other hand, appeared to consist mostly of cells making antibody of allotype a3, since less than 1% of them were inhibited by anti-a1 but 47% by anti-a3. Antibody allotype for spleen PFC was also determined on day 6 and was similar to that found for blood PFC. Anti-AA PFC were inhibited 74% by anti-a1 serum and 15% by anti-a3 whereas anti-TMA PFC were inhibited 19% by anti-a1 and 43% by anti-a3. Serum hemolysin specific for AA hapten from a1a3 animals was also strongly inhibited by anti-a1 serum but not by anti-a3 whereas the converse was true for hemolysin against TMA hapten. The a1a3 rabbits, in whcih the anti-AA was restricted to allotype a1, were mated to produced homozygous a3a3 animals. When the PFC and serum antibodies of these a3a3 offspring were examined by specific inhibition, the anti-AA activity was found to be of allotype a3 rather than being a-negative. The number of anti-AA PFC in the blood of a3a3 rabbits was lower than that in blood of a1a3 or a1a1 animals. In addition, the TMA hapten appeared to inhibit the response to the AA hapten. Thus a1a3 rabbits immunized with AA-Prbc alone had 14-fold more anti-AA PFC or 18-fold higher anti-AA hemolysin titer than a3a3 animals immunized with both AA-Prbc and TMA-Prbc. Our results are discussed in relation to various explanations which have been offered for an imbalance of allotypes in a given antibody.     

Cross-reactive idiotypes on heterologous anti-allotype antibody

Specific anti-a1 Ab was isolated from rabbits, guinea pigs, mice, chickens, and a goat. Each of these preparations was able to inhibit the reaction between a1 IgG and rabbit anti-a1 Ab as well as the reaction between rabbit IdX (anti-a1 Ab) and rabbit anti-IdX (anti-anti-a1 Ab). Maximal levels of inhibition ranged from 75 to 100% in the latter assay. Although the relative binding efficiencies of each preparation varied widely, there was generally a positive correlation between the ability of an anti-allotype reagent to bind to a1 IgG and to anti-IdX Ab. Each of the heterologous anti-a1 Ab samples was able to form precipitin bands with rabbit anti-Id Ab. These bands fused with each other and with rabbit anti-a1 Ab. These results weaken the interpretation that the ubiquitous expression of IdX previously observed in the rabbit reflects shared conserved genes. We suggest that either 1) the anti-Id Ab represents high fidelity internal images of the a1 epitopes, or 2) latent a1 allotype Ig is present in the anti-IdX preparation. In either case, any anti-a1 Ab would be potentially reactive with the anti-IdX preparation.     

Auto-antibody to an Ig VH region allotype: induction of anti-a1 antibody in an a1-suppressed a1a2 heterozygous rabbit.

Two a1a2 heterozygous sibling rabbits were first suppressed for the paternally inherited a1 VH region allotype and then immunized with a1 IgG. Anti-a1 antibody was detected in the serum of one of the rabbits. The anti-a1 auto-antibody reacted with the same amount of a1 IgG as did a conventional anti-a1 allo-antibody. Most of the IgG and IgM of this rabbit was of the a2 allotype and no significant amount of the a1 allotype was detected as would be expected for an a1 suppressed a1a2 heterozygous rabbit. However, allotype suppression in this rabbit is maintained by endogenous anti-allotype antibody. Rabbits with anti-allotype auto-antibody may be exploited to produce litters of heterozygous and homozygous rabbits efficiently suppressed for selected allotypes.     

Heavy chain variable region allotypic subspecificities of rabbit immunoglobulins. II. Selective escape of the a1-AB Ig subpopulation after the induction of auto anti-a1 antibody.

An a1a2 rabbit (P286-3), neonatally suppressed for the expression of the a1 allotype, was immunized with autologous a1 IgG at 2 months of age. Both auto anti-a1 Ab and a1 IgG molecules were found in the serum of this rabbit after the auto-immunization. The auto anti-a1 Ab and the IgG from the auto anti-a1 Ab-depleted serum were isolated. Of the previously defined a1-AB, a1-AC, and a1-AD Ig subpopulations, the a1 IgG in the IgG preparation from the rabbit P286-3 were all of the a1-AB Ig subpopulation. The auto anti-a1 Ab from rabbit P286-3 did not react with the a1-A, a1-B, and a1-C allotypic subspecificities; thus, it was presumably specific for the a1-AC and a1-D allotypic subspecificity. Thus, the a1-AB Ig subpopulation escaped from allotype suppression in rabbit P286-3, whereas the a1-AD Ig subpopulation remained suppressed. The a1-AD Ig subpopulation will probably remain suppressed for a long time and perhaps permanently since rabbit P286-3 has produced circulating auto-Ab specific for the a1-D allotypic subspecificity. These results indicate that the a1 Ig subpopulations are synthesized by distinct clones of lymphocytes under separate control.     

Allotype suppression in rabbits: the requirement for CH3 domain of anti-allotype antibody.

Facb fragments of rabbit anti-allotype antibody were prepared by plasmin digestion and isolated by gel chromatography. The antibody preparation was used in an attempt to induce allotype suppression in newborn rabbits. The Facb fragments were found to be ineffective in inducing the allotype suppression. Administration of Facb fragments caused a "burst" of immunoglobulin synthesis almost immediately after the administration of the antibody. It was concluded that the CH3 domain, which is responsible for the cytophilic activity of the antibody, is essential in induction of allotype suppression.     

Possible existence of autoantibodies against immunoglobulin allotypes in normal rabbits, and their relation to the expression of these allotypes

The concentration of a3 allotype was increased in the serum of heterozygous a1 a3 rabbits which received antiidiotypic antibodies against anti-a3 antibodies in the perinatal period. This is explained by the normal presence of anti-a3 autoantibodies which control the expression of a3 allotype in heterozygous a1 a3 rabbits under physiological conditions.     

VDJ genes in VHa2 allotype-suppressed rabbits. Limited germline VH gene usage and accumulation of somatic mutations in D regions

In this study we investigate the molecular genetic basis for VHa- Ig. Knowing that the expression of VHa allotype Ig is suppressed by neonatal injection of rabbits with anti-VHa allotype antibody, and that the decreased level of VHa allotype Ig, VHa+, in the suppressed rabbits is compensated for by an increase in VHa- Ig, we determined the nucleotide sequences of 41 VDJ genes from a2/a2 rabbits neonatally suppressed for the expression of a2 Ig. We compared these nucleotide sequences to each other and identified two groups of VH sequences. We predict that the molecules of each group are encoded by one germline VH gene. Inasmuch as VHa+ Ig is encoded predominantly by one germline VH gene, VH1, it appears that more than 95% of the VDJ repertoire of rabbits may be encoded by as few as three germline VH genes. A genomic VDJ gene whose VH sequence was similar to those of group I molecules was expressed in vitro and was shown by ELISA to encode molecules of the VHa- allotype, y33. Analysis of the D regions in the VDJ gene indicated that germline D2b and D3 gene segments were preferentially used in the VDJ gene rearrangement. A comparison of sequences of D regions of the 41 VDJ gene rearrangements in 3-, 6-, and 9-wk-old rabbits to sequences of germline D gene segments showed an accumulation of mutations in the D region. Inasmuch as we have previously shown that V regions of rabbit VDJ genes are diversified, in part, by somatic gene conversion, it appears now that rabbit VDJ genes diversify by a combination of somatic mutation and somatic gene conversion.     

Rabbit Ig kappa 1b6 gene structure

Previous studies employing Southern blot analyses have detected multiple kappa-homologous sequences within EcoRI-digested DNA isolated from kappa 1b6 homozygous rabbits and kappa 1b6 L chain secreting RMH H158 cell line. These results are very unexpected because the published partial protein sequence for the kappa 1b6 C region is incompatible with an EcoRI restriction endonuclease recognition sequence at the nucleotide level for this allotype. To determine their identity, the kappa-homologous sequences were isolated from DNA extracted from a kappa 1b6 L chain secreting RMH H158 cell line by molecular cloning. Structural analyses demonstrated these sequences to contain genetic information encoding the majority of the kappa 1b6 L chain gene locus. The protein sequence deduced from the kappa 1b6 C region gene was shown to differ from the published partial kappa 1b6 C region protein sequence at five amino acid positions. One of these differences results in a glycine to serine interchange that introduces an EcoRI restriction endonuclease recognition site within the kappa 1b6 C region gene. Subsequent genomic Southern blot analyses confirmed this structural assignment. Based on these data, the EcoRI-sensitive kappa-homologous fragments present within the genomes of the RMH H158 cell line and kappa 1b6 homozygous rabbits represent the nominal kappa 1 gene and not an alternative kappa isotype or kappa pseudogene. Rabbit Ig kappa 1 allelic nucleotide sequence homology comparisons have shown the isolated kappa 1b6 J-C gene locus to display common structural features previously identified in other kappa 1 alleles.     

Immunoelectron microscopic localization of idiotypes and allotypes on immunoglobulin molecules

We have developed a novel approach to the analysis of antigenic (allotypic and idiotypic) determinants on intact immunoglobulin molecules. Immune complexes composed of IgG in combination with anti-idiotype or anti-allotype antibody were "visualized" by transmission electron microscopy. Individual Fab fragments of anti-idiotype or anti-allotype antibody, when bound to the IgG, altered the "Y" configuration in a reproducible and interpretable manner. Anti-idiotype antibody (either as Fab or IgG) bound to the terminus of the presumed V region of the IgG molecule, thus extending the apparent length of the Fab arms. Analysis of a rabbit VH framework allotype (a1) revealed that the determinant(s) is (are) located on the lateral portion of the V region of IgG. Binding of the anti-a1 Fab fragments was always at approximately right angles to the axis of the Fab arms of IgG. Fab antibody to the rabbit kappa light chain (b4) allotype bound to the lateral portion of the terminal half of the IgG Fab arms. This technique should be of value in localizing less well defined immunoglobulin determinants.     

The structural basis of rabbit VH allotypes: serologic studies on a1 H chains with defined amino acid sequence.

The amino acid sequences for the VH regions of three homogeneous antibodies elicited by type III pneumococcal vaccine were determined. All three antibodies had the group a allotype a1. Two of the antibody H chains (3372, 3381) had identical amino acid sequences in all framework positions that are considered correlates of the VH allotype, whereas the third H chain (3T72) differed from these at positions 15 and 16. The a1 allotypic specificities of the three homogeneous antibodies were compared by quantitative radiobinding and inhibition assays by using both insolubilized anti-a1 antisera and allotypic antiserum fractions rendered specific for the homogeneous antibody 3374. It was found that antibodies 3374 and 3381 are allotypically indistinguishable and have in common an a1 allotypic specificity that predominates in pooled a1 IgG. The allotypic specificity of the 3T72 antibody, on the other hand, was markedly deficient to those of 3374, 3381, and the a1 IgG pool. This correlation of allotypic difference with amino acid sequence variation at position 15 and 16 of the H chain indicates the involvement of these two residues in a major a1 allotypic determinant.     

Identification of rabbit genomic Ig-VH pseudogenes that could serve as donor sequences for latent allotype expression

Synthetic DNA oligomers specific for the VHa allotypes of rabbit Ig genes have been used to identify latent allotypic sequences in homozygous a1 and a2 rabbits. Two Ig VH pseudogenes containing latent a3 regions have been cloned from the genome of a homozygous a2 rabbit. Analysis of the regions associated with allotype expression indicates that these two pseudogenes contain VHa- sequences in framework region 1 (FR1) and VHa3 sequences in FR3. One gene has undergone an unusual rearrangement with a third VH gene, deleting their intervening sequences and recombining in FR3 with sequences 5' to the leader exon. Our results demonstrate the presence of latent VH sequences in the genomic DNA of normal rabbits and suggest that a mechanism such as gene conversion is responsible for expression of genetically-unexpected Ig VH genes.     

Enhanced antigen-antibody binding affinity mediated by an anti-idiotypic antibody

We previously described the production of four monoclonal antibodies to the beta-adrenergic receptor antagonist alprenolol. One of these antibodies, 5B7 (IgG2a, kappa), was used to raise anti-idiotypic antisera in rabbits. In contrast to the expected results, one of the anti-idiotypic antisera (R9) promotes [125I]iodocyanopindolol (ICYP) binding to antibody 5B7. In the presence of R9, the dissociation constant decreases 100-fold from 20 to 0.3 nM. This increase in binding affinity of antibody 5B7 for ICYP is not observed in the presence of preimmune, rabbit anti-mouse or anti-idiotypic antisera generated to a monoclonal antibody of a different specificity. Furthermore, R9 in the absence of 5B7 does not bind ICYP. The F(ab) fragments of 5B7 and R9 behaved in a similar manner, and the soluble complex responsible for the high-affinity interaction with ICYP can be identified by gel filtration chromatography. The elution position of the complex is consistent with a 5B7 F(ab)-R9 F(ab) dimer, indicating that polyvalency is not responsible for the enhanced ligand binding. Kinetic analysis of ICYP-5B7 binding revealed that the rate of ICYP dissociation from 5B7 in the presence of R9 is approximately 100 times slower than in the absence of R9 [k-1(+R9) = 0.025 min-1 vs. k-1(-R9) = 2.04 min-1], consistent with the 100-fold change in binding affinity of 5B7 for ICYP. The available data best fit a model in which an anti-idiotypic antibody binds at or near the binding site of the idiotype participating in the formation of a hybrid ligand binding site.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vitro immunoglobulin allotype synthesis by spleen cells of heterozygous rabbits. Specific suppression by anti-allotype antibody

The production of immunoglobulin (Ig) bearing the b4 and b5 allotypic markers by b⁴b⁵ heterozygous spleen cells cultured in vitro was assessed by means of a sensitive and reproducible radioimmunoassay. Ig synthesis was demonstrated by the increasing amounts of the b4 and b5 allotypes appearing with time in the supernatant fluids. To determine the effect of anti-b4 or anti-b5 antibody on the synthesis of the b4 and b5 allotypes, spleen cells from b⁴b⁵ heterozygous rabbits were incubated for 24 hr in the presence of anti-b4 or anti-b5 and then washed and cultured for an additional 4 days. Anti-b4 suppressed the production of the b4 allotype with no effect on b5 production, whereas anti-b5 suppressed the production of b5 allotype with no effect on b4 production. This suppression of allotype synthesis in vitro presumably results from an antigen-antibody reaction occurring on the surface of lymphoid cells by a mechanism which may be similar to that which brings about allotype suppression in vivo for fetal and newborn rabbits.     

Comparison of latent and nominal rabbit Ig VHa1 allotype cDNA sequences

The genetic basis for the expression of a latent VH allotype in the rabbit was investigated. VH region cDNA libraries were produced from spleen mRNA derived from a homozygous a2a2 rabbit expressing an induced latent VHa1 allotype and, for comparison, from a normal homozygus a1a1 rabbit expressing nominal VHa1 allotype. The deduced amino acid sequences of the nominal VHa1 cDNA were concordant with previously published VHa1 protein sequences. A comparison of two complete VH-DH-JH and six partial VHa1 sequences reveals highly conserved sequence within VH framework regions (FR) and considerable diversity in complementarity-determining regions and D region sequences. Two functional JH genes or alleles are evident. Amino acid sequencing of the N-terminal 15 residues of pooled affinity-purified latent VHa1 H chain showed complete sequence identity with the nominal VHa1 sequences. Possible latent VHa1-encoding cDNA clones, derived from the a2a2 rabbit, were selected by hybridization with oligonucleotide probes corresponding to the VHa1 allotype-associated segments of the first and third framework regions (FR1 and FR3). cDNA sequence analysis reveals that the 5' untranslated regions of nominal and latent VHa1 cDNA were virtually identical to each other and to previously reported sequences associated with VHa2 and VHa-negative genes. Moreover, some latent VHa1 genes encode FR1 segments that are essentially homologous to the corresponding segment of a nominal VHa1 allotype. In contrast, other putative latent genes display blocks of VHa1 sequence in either FR1 or FR3 that are flanked by blocks of sequence identical to other rabbit VH genes (i.e., VHa2 or VHa-negative). These composite sequences may be directly encoded by composite germ-line VH genes or may be the products of somatically generated recombination or gene conversion between genes encoding latent and nominal allotypes. The data do not support the hypothesis that latent genes are the result of extensive modification by somatic point mutation.     

Inhibition of DNA replication and DNA polymerase alpha activity by monoclonal anti-(DNA polymerase alpha) immunoglobulin G and F(ab) fragments

The effect of monoclonal anti-(DNA polymerase alpha) immunoglobulin G (IgG) and F(ab) fragments on DNA replication in lysolecithin-permeabilized human cells and on DNA polymerase alpha activity was determined. DNA polymerase alpha activity in vitro was inhibited equally by the same concentrations of monoclonal IgGs and F(ab) fragments. However, the IgGs and F(ab) fragments were not equally potent in inhibiting DNA replication in permeable cells. In general, the F(ab) fragments were approximately equal to 10-fold more potent than IgGs in inhibiting DNA replication, suggesting the F(ab) fragments cross the nuclear membrane more readily than IgGs. Immunocytochemical studies demonstrated that at least a fraction of anti-(DNA polymerase alpha) IgGs entered the nucleus of permeable cells. For most antibodies tested, the IgG or F(ab) concentration needed to inhibit replication was several orders of magnitude higher than that needed to neutralize polymerase alpha activity extracted from the same number of cells. Anti-(DNA polymerase alpha) F(ab) fragments were shown to inhibit the discontinuous synthesis of Okazaki DNA, as well as the maturation of Okazaki DNA to larger DNA, thereby implicating DNA polymerase alpha in both of these processes.     

A monoclonal antibody against hinge-cleaved IgG restores effector function to proteolytically-inactivated IgGs in vitro and in vivo

We report a chimeric monoclonal antibody (mAb) directed to a neo-epitope that is exposed in the IgG lower hinge following proteolytic cleavage. The mAb, designated 2095–2, displays specificity for IdeS-generated F(ab’)₂ fragments, but not for full-length IgG or for closely-related F(ab’)₂ fragments generated with other proteases. A critical component of the specificity is provided by the C-terminal amino acid of the epitope corresponding to gly-236 in the IgG1 (also IgG4) hinge. By its ability to bind to IdeS-cleaved anti-CD20 mAb, mAb 2095–2 fully restored antibody-dependent cell-mediated cytotoxicity (ADCC) and complement-dependent cytotoxicity (CDC) against WIL2-S cells to the otherwise inactive anti-CD20 IgG1 F(ab’)₂ fragment. Similarly, 2095–2 reinstated ADCC against MDA-MB-231 cells to an anti-CD142 IgG1 F(ab’)₂ fragment. mAb 2095–2 was also capable of eliciting both CDC and ADCC to IgG4 F(ab’)₂ fragments, an IgG subclass that has weaker ADCC and CDC when intact relative to intact IgG1. The in vitro cell-based efficacy of 2095–2 was extended to the in vivo setting using platelets as a cell clearance surrogate. In a canine model, the co-administration of 2095–2 together with IdeS-generated, platelet-targeting anti-CD41/61 F(ab’)₂ fragment not only restored platelet clearance, but did so at a rate and extent of clearance that exceeded that of intact anti-CD41/61 IgG at comparable concentrations. To further explore this unexpected amplification effect, we conducted a rat study in which 2095–2 was administered at a series of doses in combination with a fixed dose of anti-CD41/61 F(ab’)₂ fragments. Again, the combination, at ratios as low as 1:10 (w/w) 2095–2 to F(ab’)₂, proved more effective than the anti-CD41/61 IgG1 alone. These findings suggest a novel mechanism for enhancing antibody-mediated cell-killing effector functions with potential applications in pathologic settings such as tumors and acute infections where protease activity is abundant.     

Regulation of idiotope expression. IV. Genetic linkage of two D region-dependent T15 idiotopes to the IgH allotype

The idiotopic (Id) repertoire of antibody response to phosphocholine was studied in mouse strains with different IgH allotypes. The T15 idiotype-bearing (T15+) serum antibody and antibody plaque-forming cells (PFC) were characterized with four monoclonal anti-Id that recognize distinct Id determinants on T15+ antibody encoded by VH-1 (of the S107 gene family), DH FL16.1, JH-1 and Vk22 germ-line genes. We have previously shown that expression of the Id designated AB1-2 and B36-82 depends on the third hypervariable loop (D region), whereas the other Id, MaId5-4 and B24-44, are influenced by VH structures outside of the D region. All four Id were expressed in the PC-response of all mouse strains tested, except the Ighj strains (C3H/HeJ, CBA/H-T6, PL/j), where the D region-dependent Id, AB1-2 and B36-82, were absent. The other Id, however, were normally expressed on individual PFC as well as the serum antibody of the Ighj strains. Expression of AB1-2 and B36-82 on 50% of PFC occurred in (BALB/c-Igha x C3H/HeJ-Ighj)F1 mice. The absence of Id correlated with a unique RFLP of the S107 gene family in Ighj strains. Finally, Id expression segregated with the appropriate RFLP pattern in individual (BALB/c x C3H/HeJ)F2 mice. These data demonstrate a selective genetic linkage of discrete T15 Id determinants, AB1-2 and B36-82 with the Igh allotype. By comparing these results with the available Ig sequences, we suggest that the Ighj allotype may be associated with an allelic form of the DH-FL16.1 segment which with VH-1, JH-1, and the Vk 22 code for the phosphocholine-specific antibody in the mouse.