Clustered H chain somatic mutations shared by anti-p-azophenylarsonate antibodies confer enhanced affinity and ablate the cross-reactive idiotype

A cluster of four consecutive CDR2 somatic mutations are shared by the VH regions of two independently isolated hybridoma antibodies with specificity for p-azophenylarsonate (Ars). The mutations appear to be derived by a series of independent events. To assess the influence of these shared somatic mutations on antibody affinity for Ars and on idiotypy, we introduced them, via site-directed mutagenesis, into the V region of an anti-Ars antibody that was otherwise unmutated and we eliminated them from the mutated context of one of the two antibodies in which they were originally found. Results of affinity measurements by fluorescence quenching and of idiotypic binding assays performed on these engineered mutants demonstrated that the shared mutations increased affinity for Ars and eliminated the predominant Id associated with strain A anti-Ars antibodies and four of five idiotypes defined by anti-idiotypic mAb. These results support the interpretation that a strong affinity-based selection pressure has favored the clonal expansion of B cells with receptors containing these mutations despite the loss of a predominant Id. Thus, in producing antibodies containing V regions conferring high affinity for Ag, the combined processes of somatic mutation and clonal selection have generated a common structural solution through parallel repeats.     

The immune response toward beta-adrenergic ligands and their receptors. VIII. Extensive diversity of VH and VL genes encoding anti-alprenolol antibodies

The V region genes (VH and VL) used in the immune response of BALB/c mice to alprenolol, a synthetic beta-adrenergic ligand, were examined by Southern blot and nucleotide sequence analyses. Fourteen anti-alprenolol hybridomas utilize 10 different combinations of six Vk, one V lambda, eight VH, three JK, one J lambda, and three JH genes. In addition to the combinatorial association, somatic mutations and junctional variation of assembled genes further contribute to diversity of the anti-alprenolol response. Although differing both in length and structure, the five H-chain third complementarity-determining region analyzed contain several acidic residues. Neither V gene utilization, nor H-chain third complementarity-determining-region structure can be simply correlated with affinity of the antibodies for the ligand. The anti-alprenolol V genes were compared with the corresponding sequences of unrelated antibodies. Antibody 37A4 shares a VH gene with anti-(Glu60Ala30Tyr10)n random terpolymer and anti-nitrophenyl antibodies, and a Vk gene with two anti-oxazolone antibodies. Antibodies 14C3 and 17C1 use the same germ-line VH and Vk genes as do anti-anti-idiotypic antibodies of the (Glu60Ala30Tyr10) system. These data demonstrate the genetic diversity of the antibody response to alprenolol, and illustrate the extensive flexibility of the immune system.     

Clonal recruitment and somatic mutation in the generation of immunological memory to the hapten NP.

The nucleotide sequences of the variable regions of lambda 1 chain bearing anti-NP antibodies from the secondary response of C57BL/6 mice were determined. The data indicate that the V186.2 VH gene which dominates the primary anti-NP response is expressed in nine out of 10 secondary response antibodies and is extensively mutated. In the V lambda 1 regions somatic mutations are less frequent. While point mutations predominate, there is suggestive evidence for two conversion events, one involving a one-codon deletion. Most, but not all, secondary response antibodies have a higher affinity (up to 10-fold) for the hapten than is seen in the primary response. The increase in affinity correlates with 'parallel' mutations in CDRs of H and L chains, likely to play a role in hapten binding. The analysis of VDJH rearrangements demonstrates that the secondary response lambda 1 chain-bearing antibodies are produced by a diverse set of B cell clones, which are only rarely expressed in primary responses. These clones are characterized by N-sequence-mediated heterogeneity in the 3' half of CDR3, where the germ line sequence of the D element DFl16.1 predominates in primary response antibodies. The antibodies analyzed in this and in previous work were isolated from idiotypically suppressed mice in order to evaluate whether, intraclonally, idiotype suppression selects antibody mutants into the memory pool, through suppression of the wild-type. A selection of this type was not detectable. However, idiotype suppression may control the pattern of clonotypes expressed in the primary versus the secondary response.     

Immunoglobulin idiotype and anti-anti-idiotype utilize the same variable region genes irrespective of antigen specificity

Idiotypic determinants characterizing certain antibody specificities have been proven valuable structural and genetic markers in studies of antibody diversity and regulation. The heritable predominant idiotype associated with the response to p-azophenylarsonate in A/J mice consists of a set of highly homologous (greater than 95%) heavy and light chain variable region amino acid sequences probably arising by somatic mutation from one or a few V region genes. We examined a peculiar set of monoclonal antibodies that have been defined as CRI by serologic analysis, but that have no affinity for the hapten Ars. These antibodies were elicited by immunization with anti-CRI rather than by the conventional immunization with antigen. The amino acid sequences of the amino terminal half of the V regions of these anti-(anti-CRI) antibodies are indistinguishable from those of conventional Ars-binding CRI antibodies. Thus, Ars-binding CRI and Ars-nonbinding anti-(anti-CRI) are derived from similar or identical VH and VL genes.     

Antibody engineering for the analysis of affinity maturation of an anti-hapten response.

The influence of structural variation, previously observed in a panel of V186.2 VH/V lambda 1-expressing anti-NP antibodies from the secondary response, on the affinity of these antibodies was examined by site-specific mutagenesis and recombinant antibody construction. A tryptophan----leucine exchange at position 33 in the VH segment of all but one of the high-affinity antibodies is the most frequently observed somatic mutation and by itself leads to a 10-fold higher affinity; all other somatic exchanges are irrelevant for affinity selection. In the single case of a high-affinity antibody without this common exchange, high affinity is mediated by a combination of mutations (including a one-codon deletion) in VH and the particular D-JH rearrangement carried by this antibody. The data indicate that the pattern of somatic diversification through hypermutation is shaped by affinity selection, but that only a single point mutation is available in the VH and the VL gene of lambda 1 chain-bearing anti-NP antibodies which by itself leads to an increase of hapten-binding affinity. Based on the analysis of two secondary response antibodies from which somatic mutations in VH and VL have been eliminated, it is also concluded that the recruitment of B cell clones into the pathway of hypermutation involves a mechanism which is not based upon affinity differences towards the antigen.     

Structural characterization of H chain-associated idiotopes of anti-p-azophenylarsonate monoclonal antibodies

The majority of antibodies directed against p-azophenylarsonate (Ars) protein conjugates elicited during secondary immune responses of A/J mice bear a heritable cross-reactive Id (CRIa or IdCR) which corresponds to the utilization of a unique combination of variable region gene segments that can differ by somatic mutations. One such monoclonal anti-Ars antibody, 44-10, bears IdCR as defined by rabbit antisera but does not react with two anti-idiotypic mAb, 5Ci and AD8, which react with all primary (unmutated) IdCR+ antibodies and some secondary response IdCR+ antibodies. We therefore determined the complete sequence of antibody 44-10, which differs from the germline encoded (unmutated) IdCR+ antibody 36-65 at four positions in the H chain V region (VH): position 55 in the second complementarity determining region, 100 and 107 (D-gene junctions) and 110 (in JH2). The 44-10 L chain is unmutated. Sequence analyses of five other secondary immune response anti-Ars IdCR+ antibodies chosen on the basis of sharing one or more of the amino acid substitutions found in 44-10, were correlated with idiotypic expression of this set of antibodies. The results suggest that the mutation at VH position 55 (Asn----Lys) is responsible for loss of the 5Ci idiotope. To substantiate this hypothesis, oligonucleotide-directed mutagenesis of the germline encoded (unmutated) IdCR+ antibody was used to produce two mutants, one with VH Lys 55 and the other containing residues at positions 100, 107 and 110 identical to those found in 44-10. Id binding studies on these mutants confirm that 5Ci idiotope loss is due to conformational changes resulting from a mutation at VH position 55. This mutation also results in loss of the AD8 idiotope in the structural context of antibody 44-10.     

Characteristics of two idiotypic subfamilies of murine anti-p-azobenzenearsonate antibodies

A family of antibodies bearing a common or cross-reactive idiotype, termed CRIC, predominates in the response of most BALB/c mice to the p-azobenzenearsonate (Ar) hapten, but represents a minor component of the anti-Ar response of most A/J mice. Previous results have suggested that the VH region of CRIC is encoded by two different germ-line genes in both strains. We have determined extensive mRNA sequences for VH and VL, developed specific idiotypic reagents and measured affinities for two subfamilies of CRIC, designated CRIC1 and CRIC2. Both were found to be minor components of A/J anti-Ar antibodies, and CRIC1, but not CRIC2, is a major component of the BALB/c response. The two subfamilies utilize different VH germ-line genes but the same, or nearly identical V kappa genes. The VH nucleotide sequences of CRIC1 and CRIC2 exhibit approximately 90% homology. The D regions of both families are short (one or two amino acid residues) and some can be accounted for on the basis of known JH sequences alone. Affinity differences may account for the dominance of CRIA over CRIC1 and CRIC2 in A/J mice, but results obtained with allotype-congenic mice indicate that background (non-V region) genes are also important in controlling levels of expression of the CRIC1 idiotype. Our data suggest that the A/J germline VH gene that gives rise to the CRIC2 family of antibodies may be identical with a previously sequenced BALB/c germ-line VH gene. On the basis of these and earlier data it is suggested that extensive differences between inbred strains of mice in their complements of VH genes do not result from the accumulation of many mutations in these genes. An alternative possibility is that the differences arise from deletions and/or duplications of VH genes.     

Sequence and fine specificity analysis of primary 511 anti-phosphorylcholine antibodies

The primary antibody response of mice to phosphorylcholine (PC) is dominated by antibodies using the T15 L chain. Anti-PC antibodies using the 511 L chain are prominent only in secondary responses to PC coupled to proteins, are somatically mutated, and all have an extra amino acid at the Vh-D junction, compared with T15 antibodies. The aim of the experiments reported here was to determine if the extra junctional amino acid alone was sufficient to generate a 511 PC-binding antibody, or if somatic mutation or other junctional changes were also necessary. We also wished to determine if unmutated 511 antibodies had sufficient affinity for PC to appear in the primary response. To increase the frequency of primary 511 antibodies, we generated a series of hybridomas from M167 L chain transgenic mice immunized 4 days earlier with either Streptococcus pneumonia R36a or PC-keyhole limpet hemocyanin (KLH). We determined the relative affinity of the antibodies, and sequenced their H chain V regions. The results showed that: 1) somatic mutations are not required for 511 antibodies to bind PC; 2) primary 511 antibodies all had lower relative affinities for PC than T15 while having similar affinities to T15 for TNP-aminophenyl PC, and higher affinities for the PC analogs nitrophenyl PC and choline; 3) all antibodies had the 511-specific insertion of an extra amino acid, usually Ala, at the VhD junction, compared with T15; 4) immunization with R36a, but not PC-hemocyanin, elicited antibodies with a specific Tyr----Asp substitution in the D region, indicating Ag selection based on fine specificity differences; 5) the total length of CDR3 was conserved in most anti-PC-hemocyanin antibodies, whereas the anti-R36a antibodies predominantly had longer CDR3 sequences; and 6) there were unique substitutions in most antibodies, including significant sequence heterogeneity in the D-Jh junction. We conclude that Ag selection on the basis of affinity for PC biases the primary anti-PC response in favor of T15, and that 511 precursors with their alternative fine specificities contribute the precursors that are expanded in the secondary anti-PC-KLH responses.     

Clonal characterization of the human IgG antibody repertoire to Haemophilus influenzae type b polysaccharide. III. A single VKII gene and one of several JK genes are joined by an invariant arginine to form the most common L chain V region

To characterize the L chain V region repertoire of IgG anti-Haemophilus influenzae type b capsular polysaccharide (Hib-PS) antibodies, clonal antibodies were purified from immune serum and internal amino acid sequences of VKII anti-Hib-PS L chains obtained. We examined VKII L chains because it is the most common VL family expressed in the anti-Hib-PS response. Comparison of VKII amino acid sequences, including the entire CDR2 and CDR3 regions, of five anti-Hib-PS clonal antibodies from four unrelated individuals revealed complete identity with the exception of a single CDR3 residue from one antibody. When the sequence of these antibodies was compared with known VKII genes and myeloma proteins, it was found to be identical to the human VKII gene, A2, whose genomic sequence is presented here. In addition, all five of the VKII anti-Hib-PS antibodies examined contain an arginine inserted at the V-J junction. Finally, in contrast to the extraordinary homology of the VKII-encoded residues, there is variability in the JK gene utilization by these antibodies. These results demonstrate that the most common L chain V region in IgG anti-Hib-PS antibodies is the product of a single germ-line gene. The invariant arginine insertion suggests that this residue has an important role in Ag binding.     

Specific H chain junctional diversity may be required for non-T15 antibodies to bind phosphorylcholine

The secondary antibody response of mice to phosphorylcholine (PC) shows a markedly different clonal profile than the primary response. In particular, the T15 antibodies that dominate the primary response are a minor part of secondary IgG antibodies, whereas 511 and 603 antibodies become a more prominent part of the PC-specific secondary response. These three anti-PC families differ only in L chain usage. We partially sequenced the IgH chain mRNA of a series of secondary T15 and 511 hybridomas to determine the role of somatic mutation and affinity maturation in these changes in clonal profile. None of the sequenced T15 antibodies showed somatic mutations or affinity increases. In contrast, all of the 511 antibodies had extensive somatic mutation and most had significantly increased affinity for nitrophenyl-PC. The failure of T15-expressing B cells to contribute to the secondary IgG response thus is likely to be explained by their inability to undergo (or tolerate) substantial somatic mutation and affinity maturation. We also noted that all 511 antibodies sequenced by us or others had an extra amino acid encoded at the VH-D junction by either N region addition or diversity of VH-D joining. Published sequences also show a 603 family-specific change at the VH-D junction. The frequency with which these changes, which appear obligate for PC binding, occur may determine the under-representation of these clonotypes in the primary anti-PC response. The affinity maturation in 511 antibodies after somatic mutation appears to account for their expansion in the secondary response.     

Somatic evolution of diversity among anti-phosphocholine antibodies induced with Proteus morganii

The variable region sequences of light and heavy chains (VL and VH) were determined for 11 hybridoma antibodies produced in response to the PC moiety on Proteus morganii. These hybridomas were derived from two separate fusions, one obtained from mice early in a secondary response and the other from late in a secondary response. All of these antibodies possessed a cross-reactive idiotype found on anti-PC antibodies in the M603 family, and exhibited preferential specificity for PC in the context of P. morganii. We found that all of the antibodies were derived from a single VH/VL pair. VH was encoded by V1, DFL16.1 and JH1, and VL was encoded by a consensus VK8 gene and JK5. Antibodies differed from each other by somatic point mutations that occurred at a high rate. The mutations in VL were approximately one-third as abundant as those in VH and were randomly distributed throughout the molecule. Mutations in VH were concentrated in CDR 2 and 3 and had a replacement to silent ratio that was three to six times greater than predicted from random accumulation. Based on the sequence data, a single genealogic tree with multiple branches could accommodate all the hybrids from a fusion. We concluded that in both examples the anti-PC response arose by somatic mutation and stepwise selection from a single precursor. Antigen binding studies with these 11 hybridomas and a 12th that had no mutations revealed that the acquisition of preferential specificity for antigen was dependent on somatic mutation of germline genes. Additional binding studies demonstrated that continued selection during clonal expansion was probably antigen driven. An unexpected finding was five independently selected antibodies from one fusion that had identically mutated VH and VL sequences. We suggest that the hypermutation mechanism is not a continuously active process during clonal expansion and that it is regulated, probably during the mid to late phase of the primary response.     

Complete variable region sequences of five homologous high affinity anti-digoxin antibodies

High affinity murine A/J anti-digoxin monoclonal antibodies exhibit diversity in binding specificity for structurally related cardiac glycosides. They utilize several VH and VL genes. Among this diverse set, however, five antibodies share V region amino-terminal sequences that are remarkably homologous. The five antibodies were divided into three subsets based on different fine specificity-binding patterns. Therefore, complete V region sequences were determined by Edman degradation and by nucleotide sequence analysis. The VH region homology among the five antibodies was 84 to 100% and the VL region homology was 89 to 99%. The sequence data are consistent with the use of single (or closely related) VH and VL genes encoding the five antibodies. Four antibodies, derived from the same fusion (40-40, 40-120, 40-140, and 40-160), use identical D, JH2, and JK5 gene segments and identical junctions suggesting that they are clonally related. The fifth antibody (35-20) uses different D and JH1 gene segments but the same JK5 gene segment. All five antibodies share a cross-reactive idiotype. The three antibodies that exhibit the greatest degree of homology (40-40, 40-120, and 40-140) also share indistinguishable antigen-binding patterns as well as private idiotopes not present on the other two antibodies. Antibody 40-160, which has the next most homologous sequence, shares idiotopes with the first set but binds preferentially to different sites on the hapten, whereas antibody 35-20 has the most divergent sequence. In general, the degree of sequence homology among the five antibodies correlates with their hierarchical order based on hapten and idiotype fine specificity patterns.     

Complete amino acid sequences of the heavy and light chain variable regions from two A/J mouse antigen nonbinding monoclonal antibodies bearing the predominant p-azophenyl arsonate idiotype

The immune response to p-azophenyl arsonate (Ars) in A/J mice is dominated by a cross-reactive idiotype (CRI or IdCR). IdCR+ hybridoma proteins 1F6 and 3D10 produced in a single mouse by immunization with a monoclonal anti-IdCR antibody did not bind Ars [Wysocki, L., & Sato, V. (1981) Eur. J. Immunol. 11, 832-839]. The preservation of idiotype coupled with lack of antigen binding in the same molecules provoked an examination of their primary structures in order to localize sites involved in binding to antigen and to anti-idiotypes. The VH sequence of antibody 3D10 was determined by Edman degradation of intact chains and fragments generated by CNBr, hydroxylamine, and o-iodosobenzoic acid cleavage, by trypsin and V8 protease digestion, and by sequence analysis of mRNA. The 1F6 VH sequence was reported previously [Smith, J. A., & Margolies, M. N. (1984) Biochemistry 23, 4726-4732]. The VL sequences of 1F6 and 3D10 were determined by Edman degradation of intact chains and peptides generated by cleavage with o-iodosobenzoic acid and digestion with trypsin and chymotrypsin. Both 1F6 and 3D10 are encoded by the same VH, VK, D, and JK gene segments as are IdCR+ Ars-binding antibodies. However, 1F6 and 3D10 employ the JH4 gene segment rather than JH2. Antibodies 1F6 and 3D10 share several somatic mutations, suggesting a common clonal origin, but manifest individual mutations as well. By comparison with Ars-binding IdCR+ molecules, the substitutions in 1F6 and 3D10 likely responsible for the lack of Ars binding are localized to the heavy chain D-JH junction and/or to a substitution in light chain CDR 3.     

Germ-line affinity and germ-line variable-region genes in the B cell response

The predominance of germ-line genes in IgM expression was evaluated from the nucleotide sequences of mRNA, derived from 10 hybridoma cell lines, coding for the VH and VL regions of anti-5-dimethylaminonaphthalene-1-sulfonyl (anti-Dns) IgM antibody. At least six germ-line VH gene segments distributed among four families are used in this response. Seven of the 10 independently rear-ranged VH genes were identified as germ line, with the other three possibly germ line. In all of them the D and JH portions retained the germ-line sequences of the D and JH segments from which they were derived. Maximum diversity was found in the D segments and the use of noncoded nucleotides at the VH-D and D-JH junctions. Of the eight cell lines expressing the lambda light chains, all were germ line and involved the three subtypes. Maximum affinity for the homologous ligand was found among the seven cell lines identified as expressing germ-line gene segments. Thus any somatic mutation among the remaining 3 cell lines did not provide enhanced affinity and the observed affinity of each cell line can be described as germ-line affinity. It is further suggested that the anti-Dns selectivity of the IgM antibodies is associated primarily with the CDR3 regions.     

Immunologic memory to PC-KLH: participation of the Q52 VH gene family

BALB/c mice immunized with phosphocholine-conjugated keyhole limpet hemocyanin respond with two major groups of antibodies that differ with respect to fine specificity and idiotype. Group I antibodies predominantly bear the T15 idiotype, and show appreciable affinity for the haptens PC and nitrophenyl PC (NPPC), whereas group II antibodies have appreciable affinity for NPPC only and are T15 idiotype negative. Previous studies indicated that group II binding characteristics may derive from the use of novel V gene segments not observed in group I antibodies. To determine the nature of VH gene usage in the group II antibody response, we examined the VH region of a prototype group II hybridoma, PCG1-1. The nucleotide sequence obtained from the VDJ region indicates that PCG1-1 utilizes a VH gene not observed in the group I response, one that belongs to the Q52 VH family. The PCG1-1 VH nucleotide sequence shares 97% identity with the myeloma M141 VH gene. In addition, PCG1-1 utilizes a D segment most closely related to DSP2.6 rearranged to JH-3. These data indicate that M141, a VH gene not seen in group I anti-PC antibodies is utilized by PCG1-1 to generate a PC-protein-binding group II antibody. PCG1-1 was previously shown to express the V kappa 1-3 light chain, a characteristic shared by several group II hybridomas. Furthermore, here we examined the VH gene rearrangements in four lambda 1-bearing group II hybridomas that share a common JH rearrangement with PCG1-1 by Southern blot analysis. A VH-specific probe that detects M141 VH rearrangements revealed that all four lambda 1 hybridomas as well as PCG1-1 share an identical VH gene rearrangement to JH-3. Thus the M141 VH gene product is able to utilize two distinct light chains to generate group II-like combining sites.     

Complete heavy and light chain variable region sequence of anti-arsonate monoclonal antibodies from BALB/c and A/J mice sharing the 36-60 idiotype are highly homologous

Structural and serologic studies on murine A/J monoclonal anti-arsonate antibodies resulted in the identification of a second idiotype family (Id36-60) in addition to the predominant idiotype family (IdCR). Id36-60, unlike IdCR, is a dominant idiotype in the BALB/c strain but is a "minor" idiotype in the A/J strain. The complete heavy and light chain variable region (VH and VL) amino acid sequences of a representative Id36-60 hybridoma protein from both the A/J and BALB/c strains have been determined. There are only four amino acid sequence differences between the VH of antibody 36-60 (A/J) and antibody 1210.7 (BALB/c). Two of these differences arise from single nucleotide changes in which the A/J and BALB/c Id36-60 VH germline gene sequences differ. The two other differences are the result of somatic mutation in hybridoma protein 36-60. In addition, Id36-60 heavy chains employ the same D and JH3 segments in both strains. The entire Vk2 VL of 36-60 and 1210.7 differ by only two amino acids, suggesting that like the heavy chains, they are derived from highly homologous VL genes. The same Jk segment is used in both antibodies. A comparison of the amino acid sequence data from Id36-60-bearing hybridomas suggests that a heavy chain amino acid difference accounts for the diminished arsonate binding by the 1210.7 hybridoma protein. Because the 1210.7 heavy chain is the unmutated product of the BALB/c VH gene, somatic mutation in VH may be required to enhance Ars affinity in this system.     

Three-dimensional structure of murine anti-p-azophenylarsonate Fab 36-71. 2. Structural basis of hapten binding and idiotypy

Comparison between the structures and solvent-accessible surfaces of the antigen-binding fragments of two murine anti-p-azophenylarsonate monoclonal antibodies, one bearing a major cross-reactive idiotype of A/J strain mice (36-71) and one lacking the idiotype (R19.9; Lascombe et al., 1989), highlight the structural basis for the determination of hapten affinity and idiotypy. Since the sequence of R 19.9 is identical with the germline-encoded sequence at 16 positions in both heavy-chain and light-chain variable regions where somatic mutations and junctional differences have occurred to produce the 36-71 sequence, the structure of R 19.9 can be used to model the structure of the germline-encoded antibody (36-65) in the regions around these sites. These 16 sequence differences exclude the third heavy-chain complementarity-determining region because R 19.9 utilizes a D gene segment not associated with the predominant idiotype, which is 4 residues longer than the canonical D gene segment utilized in the sequences of 36-71 and 36-65. This difference between the structures of R 19.9 and 36-71 does not affect the validity of using the structure of R 19.9 to model the structure of 36-65 since the third heavy-chain complementarity-determining region is highly solvent-exposed in both 36-71 and R 19.9, and does not interact with any of these 16 sites. Comparing the structures of 36-71 and R 19.9 suggests that only three of the differences in the heavy-chain sequences, and three of the differences in the light-chain sequences of 36-71 and 36-65, increase the affinity for hapten.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cloning and sequence analysis of the VH and VL regions of an anti-myelin/DNA antibody from a patient with peripheral neuropathy and chronic lymphocytic leukemia

We have cloned and determined the nucleotide sequence of the Ig VH and VL region genes of an IgM kappa mAb that binds to denatured DNA and myelin from a patient (POP) with chronic lymphocytic leukemia and peripheral neuropathy. Sequence analysis indicates that the V region of the kappa L chain gene (PopVK) has 99% homology to a V kappa IIIa germ-line gene and the V region of the mu H chain gene (PopVH) has 96% homology to the VH26 germ-line gene that is a member of the VH3 gene family. It is likely the V kappa and VH genes arose from these respective germ-line genes via somatic mutation or from closely related genes. V kappa III genes have frequently been used by other IgMk mAb especially those with rheumatoid factor activity, and the VH26 gene with no somatic mutation has been used by several anti-DNA antibodies, suggesting the possibility of preferential association of these or related germ-line genes with autoantibodies. The minor differences between the sequences of POP's VH and V kappa genes and sequences used by other autoantibodies, may be responsible for this antibody's crossreactivity with myelin and, as a result, the autoimmune neuropathy.     

Complete amino acid sequence of the heavy-chain variable region from an A/J mouse antigen-nonbinding monoclonal antibody bearing the predominant arsonate idiotype

The 1F6 hybridoma protein, exhibiting the predominant cross-reactive idiotype (CRI) associated with the immune response to p-azophenylarsonate in A/J mice but failing to bind the hapten arsonate, was elicited following immunization with rat anti-CRI [Wysocki, L.J., & Sato, V. (1981) Eur. J. Immunol. 11, 832-839]. The dissociation of idiotype and antigen binding in this hybridoma provides an opportunity to determine structural features involved in antigen binding and idiotypic sites. The complete heavy-chain variable region (VH) amino acid sequence was obtained by automated Edman degradation of the intact chain and fragments due to CNBr cleavage, trypsin digestion, mild acid hydrolysis, and carboxypeptidase A digestion of a CNBr fragment. Comparison of the CRI+ arsonate-nonbinding 1F6 sequence with the CRI+ germ-line VH gene sequence reveals that the 1F6 heavy chain differs from the germ-line-encoded amino acid sequence at seven positions within VH [Siekevitz, M., Gefter, M. L., Brodeur, P., Riblet, R., & Marshak-Rothstein, A. (1982) Eur. J. Immunol. 12, 1023-1032]. The 1F6 VH appears to arise from the CRI+ germ-line VH by somatic mutation at at least seven amino acid residues, each of which could be due to a single nucleotide base change. The diversity (D) gene-encoded segment of 1F6 is similar to that of the CRI+ antigen-binding hybridoma 36-65 except for two amino acid substitutions. Further, the idiotype (CRI) is preserved despite use of a JH4 gene segment in 1F6 as compared to JH2 in all CRI+ arsonate-binding hybridomas examined to date.(ABSTRACT TRUNCATED AT 250 WORDS)     

Analysis of antibodies of known structure suggests a lack of correspondence between the residues in contact with the antigen and those modified by somatic hypermutation

Forty unique murine antibody-antigen complexes determined at 2.5 A or less resolution are analyzed to determine whether the residues in direct contact with the antigen are modified by somatic hypermutation. This was done by taking advantage of the recent characterization of the pool of Vkappa germline genes of the mouse. The average number of residues in contact with the antigen in the V(L) gene, which contains the CDRL-1, CDRL-2, and all but one residue of CDRL-3, was six. The average number of somatic mutations was similar (around five). However, as many as 53% of the antibodies did not show somatic replacements of residues in contact with the antigen. Another 28% had only one. Overall, the frequency of antibodies with increasing number of somatic replacements in residues in contact with the antigen decreased exponentially. A possible explanation of this finding is that mutations in the contacting residues have an adverse effect on the antigen-antibody interaction. This implies that most of the observed mutations are those remaining after negative (purifying) selection. Therefore, efficient strategies of site-directed mutagenesis to improve the affinity of antibodies should be focused on residues other than those directly interacting with the antigen.