Inheritance of idiotype expression unlinked to the H chain allotype locus. Novel features of genetic control in the Ia.7 system

We have observed a pattern of inherited idiotype expression in three mouse strains that is unexpected from the genetics of the strains: a dominant idiotype that was expressed at high levels in two parental strains was expressed only at low levels in a heavy chain allotype congenic strain derived from them. In the C3H.SW strain, the antibody response to the class II MHC Ag I-E is of limited diversity, with dominant expression of an idiotype and the V kappa 21 L chain. The C57BL/10 strain expresses the same idiotype at high levels, whereas the CWB/12 strain, which was derived by replacing the Ig H chain Igh-Cj allele of C3H.SW with the Igh-Cb allele derived from C57B1/10, has been found to express little of this dominant idiotype. CWB/12 responds, with titers equal to those of the parental strains, to the I-E epitope responsible for dominant idiotype expression, and it expresses normal V kappa 21 levels; thus deficiencies in epitope-specific responsiveness or in V kappa 21 expression cannot explain the low Id expression in CWB/12. Furthermore, Southern blot analysis of three VH families gave no evidence of recombination within the the VH locus of CWB/12, which was Igh-Vb throughout. Black-cross analysis demonstrated that expression of the dominant idiotype segregated independently of Ig allotype, and was therefore due to genes unlinked to the H chain gene locus. To our knowledge, this pattern of Id expression is unprecedented, and indicates the need for caution in the interpretation of studies using allotype congenic strains. It also demonstrates a role for genes outside the Igh locus in the control of Id expression.     

Molecular characterization of a supratypic cross-reactive idiotype associated with IgM autoantibodies

Neoplastic B cells from patients with chronic lymphocytic leukemia (CLL) or small lymphocytic lymphomas (SLL) frequently express surface Ig reactive with the mouse mAb, Lc1. Raised against a human monoclonal IgM with rheumatoid factor activity, Lc1 detects a major cross-reactive Id (CRI) present on the H chain of many monoclonal IgM autoantibodies. In contrast to other major autoantibody-CRI investigated to date, we note that the Lc1-CRI is expressed by subpopulation of cells in the germinal centers, as well as in the mantle zones, of secondary human B cell follicles. To examine the molecular basis for Lc1 expression, we used the polymerase chain reaction to isolate the functionally rearranged Ig VH genes of monoclonal Lc1-reactive B cell populations from six unrelated patients with CLL or SLL. Although the neoplastic B cells from most patients with CLL or SLL express the CD5 surface differentiation Ag, the lymphoma cells from one patient with SLL were CD5-negative. We find that the Lc1-reactive cells from each cell population have Ig rearrangements involving a VH gene of the VH4 subgroup. However, the VH4 genes rearranged in different Lc1-reactive tumor populations may originate from at least two disparate germ-line VH4 genes. Also, in contrast to the CD5-positive tumor populations, we find evidence for intraclonal diversity in the functionally rearranged VH4 genes of the CD5-negative SLL. Collectively, this study discerns a degeneracy in the VH4 genes that can encode the Lc1 CRI, indicating the term "supratypic cross-reactive idiotype" may best describe the specificity of the Lc1 mAb. Also, this study suggests that expression of CD5 may delineate categories of B cell SLL that differ in their relative rates of constitutive Ig V gene somatic mutation.     

The developmental patterns of B cell precursors distinguishing between environmental and nonenvironmental forms of phosphocholine.

We have analyzed the developmental patterns of two groups of B cell precursors in nonimmunized BALB/c mice with respect to their relative proportions, absolute frequencies, V gene usage, fine specificity, and avidity for antigen. One group of B cells (group I) secretes antibodies specific for PC and PC-containing bacteria, whereas the other group (group II) produces antibodies recognizing only nonenvironmental PC-protein conjugates. A marked shift in the proportions of group I and group II occurs during ontogeny: while the group I B cells dominate (greater than 85%) the adult antibody repertoire, the group II B cells have equal representation in neonatal mice from Days 1 to 7, and remain as a significant portion until 2 weeks of age. Examination of the absolute frequencies of group I and group II B cells revealed that the frequency of group II B cells remained relatively stable throughout ontogeny, whereas group I B cells expanded rapidly after 7 days of age to predominate in the adult. Genetic analysis indicated that early group I antibodies were encoded by VH and VL genes different from adult group I antibodies which are mostly encoded by a single VH (S107) and VL (V kappa 22) gene combination (the T15 idiotype). On the other hand, early group II antibodies used VH genes comparable to their adult counterparts. The majority of early group I antibodies have lower avidity for PC than adult T15+ antibodies, whereas the avidity of neonatal group II antibodies varies considerably and is comparable with that of the adult group II antibodies. Our results suggest that the ontogeny of phosphocholine-specific B cells may be regulated according to their fine specificity rather than to their avidity or V gene usage.     

Analysis of variable region genes encoding a human anti-DNA antibody of normal origin. Implications for the molecular basis of human autoimmune responses

In order to investigate the genetic basis for natural anti-DNA immune responses, we isolated and sequenced the variable gene elements (VH and VL) encoding an anti-DNA antibody expressed by a human hybridoma of normal origin (Kim4.6) and compared these sequences with those reported for four other human anti-DNA antibodies. The Kim4.6 antibody leader and VH segments were identical in nucleotide sequence with the VH1.9III germ-line VH3 gene, and the Kim4.6VL segment showed 98% nucleotide sequence identity with a V lambda I subgroup gene expressed in a Burkitt's lymphoma. Comparative analysis of Kim4.6 and other human hybridoma anti-DNA antibodies indicated that anti-DNA immune responses are diverse in terms of VH and VL gene utilization but may exhibit a bias toward rearrangement of VH genes that are over-represented in the fetal pre-B cell repertoire. Moreover, Kim4.6 and three of four other sequenced human anti-DNA antibodies appear to use a germ-line diversity gene, DXP'1, which may represent a counterpart of the DFL16.1 segment utilized in murine responses to the hapten nitrophenyl. Taken together, our findings indicate that anti-DNA immune responses can be encoded by nonmutated VH genes and that the elements and molecular mechanisms which engender this response are essentially the same among natural and lupus-associated anti-DNA antibodies. Our data also suggest that natural autoimmune responses originate early in B cell ontogeny as is consistent with the hypothesis that autoreactivity plays a major role in shaping the normal immune repertoire.     

The effect of isotype and the J kappa region on antigen binding and idiotype expression by antibodies binding alpha (1----6) dextran

Gene transfection and expression techniques have been used to produce three antibodies specific for alpha (1----6) linked dextran B512 with altered isotypes and J kappa regions. Expression of the L chain V region joined to J kappa 4 or J kappa 5 instead of to J kappa 2 reduced or abolished dextran binding. One antidextran with a reduced binding constant for dextran had the same combining site size as the parental mAb. Transfectoma Ig unreactive with dextran B512 did not bind to other class I or class II dextrans. Antibodies with J kappa 4-containing L chains expressed the 10.16.1 (anti-alpha(1----6) dextran) idiotype. In contrast variants expressing L chains with J kappa 5 lost idiotype expression, except when oligosaccharide is present on VH; all antibodies with J kappa 5 L chains continued to bind dextran but with reduced affinity. The presence of carbohydrate in VH may alter the conformation of both paratope and idiotope. Alteration of H chain isotype did not appear to significantly alter the ability of the antidextran to bind Ag; an exception may be that switching V regions to the IgM C region may decrease the apparent affinity for Ag.     

A single VH gene is utilized predominantly in anti-BrMRBC hybridomas derived from purified Ly-1 B cells. Definition of the VH11 family

By establishing hybridomas from two distinct surface IgM+ splenic B cell populations, Ly-1 B cells and "conventional" (Ly-1-) B cells, we found that the Ly-1 B population includes a 30 to 70 times higher frequency (1 to 2%) of cells with specificity for bromelain treated autologous red blood cells (anti-BrMRBC) when compared with conventional B cells (0.03%). We cloned and sequenced the V genes encoding anti-BrMRBC antibody from two hybridomas made with Ly-1 B cells sorted from the spleen of SM/J mice. The VH sequence (for both) is identical with the previously reported sequence associated with this specificity and belongs to a new VH gene family. This gene family, defined here as VH11, has only two members and is the predominant VH rearranged in a collection of Ly-1 B derived anti-BrMRBC hybridomas, always in association with a single VL gene (a member of the V kappa 9 family). Furthermore, analysis of hybridomas made with Ly-1 B cells sorted from the peritoneum reveals a yet higher increased frequency of VH11-encoded anti-BrMRBC specificity (30%). This variation in frequency of anti-BrMRBC in the Ly-1 population depending on location, together with the repeated association of VH11 with a particular V kappa gene suggest that antigen driven selection is (at least in part) responsible for the biased V gene expression seen in this population. Furthermore, a mechanism that might contribute to biased expression, preferential rearrangement due to close proximity to J (as seen in pre-B lines), is excluded by localization of VH11 5' to several of the more J-proximal families (Q52, 7183).     

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.     

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.     

Comparison of variable region primary structures within an anti-fluorescein idiotype family

Previous reports described the properties of a high affinity (Ka = 1.7 X 10(10) M-1) prototype anti-fluorescein monoclonal antibody 4-4-20, an intermediate affinity (Ka = 3.7 X 10(7) M-1) prototype 9-40, and Ig members of the 9-40 idiotype family (comprised of 3-24, 5-14, 5-27, 10-25 and 12-40). Although the seven monoclonal anti-fluorescein antibodies expressed similar active site structural determinants (idiotypes) as determined serologically, each was characterized by different affinities for fluorescein and fine specificity binding patterns. Partial heavy (H)- and light (L)-chain N-terminal amino acid sequence analyses revealed all antibodies (except 5-27) were composed of highly homologous VHIII(C) and V kappa II subgroup genes, respectively. Antibody 5-27 utilized a VHIII(B) and a V kappa V subgroup genes and shared low V-region sequence homology with 4-4-20, 9-40 and the remaining 9-40 idiotype family. In addition, complete 4-4-20, VH- and VL-region primary structures were determined to better understand antibody-antigen interactions. Antibody 4-4-20 utilized a VHIII(C) subgroup VH-gene, a truncated Sp2 D gene segment, JH4, a V kappa II subgroup VL-gene, and J kappa 1. Antibody 4-4-20 VH and VL complementarity-determining regions contained many basic and aromatic amino acid residues capable of interaction with fluorescein. Results are discussed in terms of idiotypic and fluorescein-binding characteristics as well as antibody structural and functional diversity in the immune response.     

Neonatal and adult primary B cells use the same germ-line VH and V kappa genes in their (T,G)-A-L-specific repertoire

Although there is a nonrandom usage of VH gene families by primary B cells early in ontogeny, at issue is whether the preferential rearrangement of 3' germ-line VH genes, e.g., VH7183 and VHQ52 family genes, influences the neonatal B cell repertoire that can be expressed in response to Ag. In order to address this issue, and to determine whether neonatal B cells can use the same germ-line VH and V kappa genes as adult B cells in their primary response, we have analyzed at the molecular level the neonatal antibody response to (T,G)-A-L and compared it with the adult primary response. Among the TGB5 Id+, GT+ antibodies, which dominate the neonatal response to (T,G)-A-L, two VH gene families were used: J558 (high frequency) and 36-60 (low frequency). The majority of Id+ neonatal hybridomas used the same germ-line VH gene (H10, from the VHJ558 family), but with enormous diversity in the D region, and one of two germ-line V kappa 1 genes (V kappa 1A, V kappa 1C). These are the same germ-line V-genes used by most primary adult Id+ hybridomas, and the frequency of expression of this germ-line V-gene combination appears equivalent in the neonatal and adult primary repertoires. Therefore, it is clear from this study that as early as day 5, neonatal B cells can use the same germ-line V-genes as adult primary B cells in their Ag-specific repertoire.     

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.     

抗A型产气荚膜梭菌α毒素单链抗体基因的克隆和表达

应用RT PCR技术 ,从分泌具有中和活性的抗A型产气荚膜梭菌α毒素单克隆抗体的杂交瘤细胞中 ,扩增出抗体V_H 和V_L 基因 ,连接成ScFv基因 ,并将其克隆至pGEM T载体中构建了重组质粒pXScFv 2E3。经序列分析证实 ,V_H 和V_L 基因及linker基因拼接正确 ,基因全长为 726bp ,编码 242个氨基酸。随后将其定向克隆于表达载体pHOG21,转化至大肠杆菌XL1 BLUE筛选出表达菌株XL1 BLUE(pHOG 2E3)。经ELISA和SDS PAGE分析表明 ,在20℃用IPTG诱导培养时 ,表达的ScFv蛋白占菌体总蛋白的 25 %。并且ScFv基因表达产物能够中和α毒素的磷酯酶C活性     

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.     

Natural auto- and polyreactive antibodies differing from antigen-induced antibodies in the H chain CDR3

We describe three sets of natural (preimmune) polyreactive antibodies and Ag-induced antibodies that share the same VH-VL combinations. The amino acid homology in the VH and VL segments averaged 92%. These sets were found among 49 neonatal and adult natural mAb that were compared with 35 Ag-induced monoclonals produced during the memory response to phosphocholine (PC)-keyhole limpet hemocyanin. Both groups of monoclonals had been selected on the basis of a restricted fine specificity pattern, namely the ability to recognize PC-protein and p-nitrophenyl phosphocholine but not PC. All of the antibodies were tested for reactivity against a panel of 15 self and foreign Ag. Despite their common fine specificity as the basis for selection, 33/49 natural antibodies were poly/auto reactive whereas 0/35 Ag-induced antibodies had such poly/auto reactive properties. The natural antibodies were encoded by genes representing nine different VH families and several V kappa and V lambda families. There were a few replacement substitutions distinguishing the Ag-induced antibodies from the natural antibodies in each set; however, the most noteworthy difference was the extreme variability of CDR3 in the natural antibodies that differed in both length and amino acid sequence from each other and from Ag-induced antibodies. The results suggest that CDR3 of the H chain may play a critical role in distinguishing poly- from monospecific combining sites in natural and Ag-induced antibodies.     

High frequency expression of S107 VH genes by peritoneal B cells of B10.H-2aH-4bP/WTS mice

Our previous analyses of peritoneal Ly-1 B cells indicate that a high percentage express VH genes of the VH11 and VH12 families, and that this bias is due to clonal selection. The antibodies encoded by these genes bind the same hapten, phosphatidyl choline (PtC). Twenty-one of 73 hybridomas generated from fusions with peritoneal Ly-1 and Ly-1 sister population B cells of B10.H-2aH-4bp/Wts mice produce anti-PtC specific antibodies. We show here that 19 of these express VH11 and VH12 family genes and two express VH36-60 family genes. To assess whether there is a bias in VH gene use among non-PtC-specific hybridomas we analyzed the remaining 52 hybridomas for VH family expression by using VH family-specific probes in an RNA dot blot assay and by Ig mRNA sequencing. We find a seven-fold increase in the expression of the VHS107 family genes, and only slight differences in the expression of VH genes of other families relative to splenic B cells. We attribute the increase in VHS107 gene expression to clonal selection inasmuch as five of the seven VHS107+ hybridomas express the same VH gene (V11) and VL association is nonrandom. The bias in VH gene use among the entire panel of 73 peritoneal hybridomas is to the extent that approximately one-third express one of three genes: the V11 gene of the S107 family, the CH34 gene of the VH11 family, and the VH12 family gene.     

Idiotypical identity of IgG myeloma protein with monoclonal IgM, Bence Jones protein, and Fv derived from one patient.

Serum from a patient (KK) with IgG2-lambda myeloma was shown to contain multiple paraproteins corresponding to an IgM-lambda monoclonal protein (MMP), a lambda-type Bence Jones protein (BJP), and a 30 kDa component in addition to the IgG2 myeloma protein (GMP). These proteins possessed common idiotypic determinants, as judged by their monoclonal reactivity with rabbit anti-GMP idiotype antibody (aId) in the immunofixation electrophoresis. Analysis with aId absorbed with either H or L chain of GMP revealed that the 30 kDa component shared both VH and VL with GMP and MMP, while BJP carried only the VL idiotype. The 30 kDa component, however, failed to react with antibody to either the mu, gamma, alpha, kappa, or lambda isotype, indicating that it had an Fv-like molecular composition. These results suggest that myeloma cells of KK had diverged from the same precursor B cell clone to produce MPs of different isotypes and altered molecular constructions.     

A V region determinant (idiotope) expressed at high frequency in B lymphocytes is encoded by a large set of antibody structural genes.

Idiotope Ac38, a V region determinant of the lambda 1 chain-bearing, germ line encoded antibody B1-8, is expressed at high frequency (approximately 1/40) in lambda 1 chain-bearing B cells. Here, we describe the isolation of lambda-positive hybridomas from C57BL/6 mice which had been immunized with antibody Ac38, the antibody recognizing idiotope Ac38. In Northern blot analysis, mRNA isolated from 10 such hybridomas hybridizes with a cDNA probe from the VH gene expressed in the cell line B1-8. Amino acid sequence analysis of the VH regions of four of the hybridoma proteins reveals that they are all derived from related, though distinct, germ line VH genes. In one case the sequence data suggest that extensive somatic mutation has taken place. Only one of the four sequences derives from the same VH gene that is expressed in the cell line B1-8. Together with earlier evidence, the present data demonstrate that the Ac38 idiotope is a marker for at least five VH and three D region genes in the C57BL/6 germ line. This explains the high frequency at which this idiotope is expressed in the B cell population. In addition, our sequence determinations identify two VH genes in the C57BL/6 strain which are closely related (and possibly allelic) to two known BALB/c VH genes. One of these genes is the gene expressed in the BALB/c myeloma MOPC 104E.     

Novel V genes encode virtually identical variable regions of six murine monoclonal anti-bromelain-treated red blood cell autoantibodies

The variable (V) region sequences of six immunoglobulin M (IgM, kappa) monoclonal autoantibodies that recognize bromelinized isologous red blood cells, obtained by fusions of peritoneal cells from NZB or CBA/J nonimmunized mice with BALB/c myeloma cells, were determined by direct mRNA sequencing. The V regions of the light chains (VL) are almost identical with one another, as are the V regions of the heavy chains (VH), which, however, differ by six linked-base substitutions, depending on the strain of mice producing the autoantibodies. Such variations may reflect allelic differences. The VH segments determined have no obvious correspondence to any VH genes identified so far. They may belong to the small VH group 4, where 73% homology, at the most, can be calculated at the protein level for codons 1 to 94. Alternatively, the VH regions may be members of a new group of VH sequences not previously found. The V kappa regions appear closely homologous to members of the V kappa-9 subgroup of myeloma proteins of unknown antigen-binding specificity. The joining segments, J kappa and JH, used by the autoantibodies investigated, originate from the J kappa 2 and JH1 germ-line gene segments, respectively. The nine base-long diversity segments, D, derive from one member of the germ-line D gene SP2 family.     

Molecular analysis and fine specificity of antibodies against an organophosphorus hapten

We have identified four fine specificity groups reactive with the organophosphorus hapten Soman among 46 hybridomas generated in specific response to immunization with Soman-keyhole limpet hemocyanin (KLH). The different fine specificity groups do not appear to correlate with the use of particular V genes. Molecular analysis of VH genes demonstrates predominant use of VH J558 family members in hybridomas of all fine specificity groups although several different VH genes within this family as well as others are able to contribute. Diversity of VH gene usage was also apparent in primary IgM-producing hybridomas. In contrast, there appears to be restricted L chain usage; a large number (18/46) used the V kappa 1 family. Interestingly, the V kappa 1 family also plays an important role in the memory response to phosphocholine (PC)-KLH, a related organophosphate hapten which shares several structural features with Soman, particularly when coupled to protein carriers. The V kappa 1 C gene appears to predominate in the PC-KLH response. Restriction analysis of DNA from the V kappa 1-positive Soman-KLH-specific hybridomas suggests that a single V kappa 1 gene may be utilized by 17/18 but that this gene is different from V kappa 1 C and may be V kappa 1 A. We propose that members of the V kappa 1 family contribute favorably in generating combining sites that recognize all or part of the structural features shared by the two haptenic structures Soman and PC when they are coupled to protein. This most likely involves recognition of the phenyl linker moiety as the dominant feature. It appears that the L chain rather than the H chain may play a more significant role in forming the phenyl-Soman-specific combining site and perhaps the combining sites for phenyl or ring structures in general.