Immunologic memory to phosphocholine. IV. Hybridomas representative of Group I (T15-like) and Group II (non-T15-like) antibodies utilize distinct VH genes

The anti-phosphocholine (PC) memory response elicited in BALB/c mice by phosphocholine-keyhole limpet hemocyanin (PC-KLH) contains two groups of antibodies distinguished by their fine specificity for PC and p-nitrophenylphosphocholine (NPPC). Group I antibodies are inhibited by both PC and NPPC, while Group II antibodies are inhibited appreciably only by NPPC; only Group I antibodies are dominated by the T15 idiotype. Anti-PC hybridomas representative of the memory response to PC-KLH were produced to examine the variable region genes expressed by memory B cells. Two IgM hybridomas were of the Group I type, because they were inhibited by both PC and NPPC and they bound to the pneumococcus R36A. However, only one of these antibodies (PCM-2) expressed a T15 idiotope, while the other (PCM-1) did not express any of three T15 idiotopes. Despite its negative T15 idiotype profile, N-terminal amino acid sequencing of PCM-1 purified heavy chain and Southern blots of the hybridoma DNA indicated that it utilizes the T15 VH and JH1 genes. Three hybridomas, IgG1, IgM, and IgE, typical of Group II antibodies, were examined; these were negative for three T15 idiotopes and displayed measurable avidity only for NPPC in a PC-protein binding inhibition assay. These three hybridoma antibodies, like serum Group II IgG1, did not measurably bind to the bacterium R36A. The heavy chain amino termini of all three of these antibodies were inaccessible for Edman degradation. Southern blots of DNA from the IgG1 hybridoma revealed the T15 VH gene to be in the germ line configuration only and unassociated with any JH segment, indicating that this Group II antibody utilizes a VH gene different from the T15 family. These results signify that, whereas some diversity of the (anti-PC) memory response may be generated by somatic diversification of variable regions important in the primary response, a significant contribution to the overall heterogeneity of memory antibodies originates in the expression of additional variable region genes.     

Specific VDJ gene combinations contribute to the specificity of memory antibodies to the phosphorylcholine hapten.

Based on their fine specificity, two groups of antibodies against the phosphorylcholine (PC) hapten have been described. Group I antibodies react predominantly with the PC moiety of the hapten and group II are directed against the entire hapten including the azophenyl spacer to the protein carrier. We have analyzed the VH gene segment utilization of hybridomas from the memory response to PC by Southern blot analysis and nucleotide sequencing of the functional VDJ rearrangements. Three main specificities of anti-PC antibodies could be distinguished. Anti-PC hybridomas with group I fine specificity utilize the VH1-DFL 16.1-JH1 rearrangement. A major portion of group II antibodies recognized the phenyl-PC part and expressed the same VH1 gene in combination with a member of the SP2 family and JH1 or JH2. The other anti-PC antibodies either used the PJ14-DFL16-JH3 rearrangement in combination with a lambda 1 L chain or a member of the VGam3.8 VH family rearranged to the DFL16.1 and the JH3 gene segments. The PJ14 and VGam3.8 V gene expressing antibodies were directed to the phenyl group and were either not or barely inhibitable by PC chloride. Thus, specific VDJ gene combinations contribute to the fine specificity of antibodies in the memory response to the PC hapten. The use of the S107, Q52, and VGam3.8. VH gene families, together with FL16.1 or SP2 D segments and JH1, JH2, or JH3 results in different fine specificities to the PC, phenyl-PC, or the azophenyl moiety of the PC hapten. These fine specificities of the memory response use V, D, and J segments of the initial T15Id+ response in combination with gene segments usually related to phenyl specificity.     

Immunologic memory to phosphocholine. VII. Lack of T15 V1 gene utilization in Xid anti-PC hybridomas

CBA/N mice carrying the Xid defect fail to make antibodies expressing the T15 idiotype in response to immunization with PC-KLH. Antibodies predominating in the Xid response have binding properties characteristic of group II antibodies that emerge in the memory response in BALB/c; the prototype group II antibody utilizes a VH gene product distinct from the V1 gene product expressed by T15 idiotype-positive antibodies. To examine VH gene usage in the anti-PC response of Xid B cells, hybridomas were produced from Xid mice immune to PC-KLH. Four hybridomas possessing properties typical of the predominant group II antibody response in Xid mice and two representing minor components of the response were studied. Analysis of DNA by Southern blot hybridization revealed that none of the hybridomas utilized the T15 V1 gene segment, nor did they share use of a common VDJ gene product. These results indicate that Xid group II antibodies either make use of different VH gene segments or use the same VH in combination with various D and JH segments.     

Restricted Ig variable region gene expression among Ly-1+ B cell lymphomas

The majority of the characterized Ly-1+ B cell lymphomas of B10.H-2aH-4bp/Wts origin (the CH series) bear surface Ig related by Ag specificity or idiotype or both. To determine the genetic basis for these structural similarities, we have sequenced the VH and VL region genes expressed by 10 CH lymphomas, and have compared their VH and V kappa gene rearrangements by Southern blot analysis to one another and to those of four other CH lymphomas. Sequence analysis identified only five different VH, and seven different VL genes, and indicated that these V genes are essentially unmutated. CH lymphomas which express the identical VH gene share at least one idiotope. Thus, the basis for shared idiotype and specificity is due in most cases to the use of the same V gene. This restriction in V gene expression is not due to the preferential use of V genes of any particular VH family or VL group, as the expressed V genes belong to four different VH families and four V kappa groups, and include V lambda 1 and V lambda 2. We hypothesize that Ag selection accounts for the restriction in V gene usage among CH lymphomas.     

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.     

Genetics of the phosphocholine-specific antibody response to Streptococcus pneumoniae. Germ-line but not mutated T15 antibodies are dominantly selected

The role that somatic mutations play in the phosphocholine-specific, antibody response to Streptococcus pneumoniae was examined by studying sets of hybridomas from different individual mice. As expected most of the cell lines were from the T15 anti-phosphocholine family and were not encoded by the v1 gene of the T15 VH family and V kappa 22. A minority of antibodies were from the M603 (v1/V kappa 8) and M511 (v1/V kappa 24) families. Three additional antibodies were encoded by the v11 gene of the T15 family; two were paired with a V lambda and the other with a V kappa 1 gene. In vitro binding studies showed that T15- and M603-like antibodies had the highest affinity for S. pneumoniae. Complete sequencing of the VH and VL mRNA from 25 of the hybridomas revealed somatic mutations in 11 of the antibodies. A total of 17 independently derived T15 positive cell lines were studied in detail, six of these were mutated. These mutations were scattered throughout the V regions and the replacement to silent ratio was typical of that for framework regions. Statistical evaluation of the placement of mutations showed that there was a slight but significantly decreased frequency of mutations in complementarity determining regions. Comparisons of mutated and unmutated T15-related antibodies showed that mutations caused a decrease in binding to S. pneumoniae in every case. These results argue that the optimal specificity for this molecular form of phosphocholine is encoded in the germline and that Ag-driven events favor selection of B cells expressing these germ-line encoded antibodies.     

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.     

Ig gene rearrangement and expression in the progeny of B-cell progenitors in the course of clonal expansion in bone marrow cultures.

In cultures of murine bone marrow cells colonies of 10(3)-10(4) cells were identified which consisted to a large part of pre-B and B cells. Cell mixing experiments with genetically marked cells indicated that each colony is derived from a single progenitor cell not yet committed to the expression of either IgH locus. A concanavalin-A-mediated electrofusion method allowed us to rescue and amplify individual cells from a given colony by hybridization with X63.Ag8.653 cells. The molecular analysis of 12 such hybridomas revealed that all IgH loci were rearranged into DJH or productive or nonproductive VHDJH complexes. Most kappa and all lambda light chain loci were in germline configuration. Kappa chain expression was only seen in heavy (mu) chain expressing hybridomas. Hybridomas from a given colony were heterogeneous in terms of DJH and VHDJH rearrangements and in no cell was more than one productive VHDJH complex detected. None of the productive VHDJH complexes contained a VH gene of group 1 (J558), the largest VH gene family with about half of the VH genes. This is in marked contrast to VH gene usage in splenic B cells.     

Patterns of Ig V region expression among neonatal hemagglutinin-responsive B cells. Evidence for non-random VH gene representation during later stages of development

Hybridoma libraries were established whose specificities reflect those within the BALB/c hemagglutinin-responsive B cell repertoire at 1 or 2 wk of age. These libraries were generated through chronic immunization regimes that induce responses dominated by clonotypes available at the age of initial immunization. Dot blot analyses of cytoplasmic RNA from these hybridomas were performed to determine the Ig H chain V region (VH) families associated with the repertoire at each age. Although genes from most known VH families can generate hemagglutinin-specific antibodies, clonotypes prevalent during the first week of life disproportionately use VH7183 gene segments. In contrast, hybridomas representative of the repertoire in 2-wk-old individuals preferentially use VHS107, VH36-60, and VHX24 gene segments. These results demonstrate changes in VH gene family predominance that correlate with the age-related patterns of clonal emergence and turnover previously shown in the hemagglutinin-reactive B cell pool. Taken together, these findings suggest that the very early neonatal Ag-responsive B cell pool closely reflects preferential VH gene rearrangements within the pre-B cell compartment. Further, they suggest that either non-random strategies of VH gene expression, or selective clonal expansion strategies based on VH, operate even at later stages of development.     

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)     

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.     

Immunologic memory to phosphocholine. V. Hybridomas representative of group II antibodies utilize V kappa 1-3 gene(s)

The anti-phosphocholine (PC) memory response of BALB/c mice to PC-KLH contains two groups of antibodies distinguished by fine specificity and by expression of the T15 idiotype that dominates Group I but not Group II anti-PC antibodies. The contribution of V kappa genes to this diversity was investigated by the analysis of L chains from PC-binding hybridoma proteins (PCBHP) representative of Group I and Group II. N-terminal amino acid sequence analysis was performed on the L chains of three independently derived Group II PCBHP up to residue 23 (PCG1-1) or 21 (aPC-111-1 and aPC-12-3). These three sequences differed from each other by only one or two residues, but differed by approximately 50% from the L chains of the Group I-like PC-binding myeloma proteins (PCBMP); the Group II sequences are closely related to V kappa 1-3. Isoelectric focusing analysis was also performed on the L chain of PCG1-1, as well as on L chains from PCBHP typical of Group I antibodies, and from an atypical PCBHP differing from Groups I and II in fine specificity. A Group I PCBHP and the atypical PCBHP expressed L chains related to V kappa 8 and V kappa 24, respectively. The L chains of another Group I PCBHP and of the Group II protein, PCG1-1, appeared different from those found in the PCBMP and from each other. The results indicate a more diverse expression of L chains in the memory anti-PC response than is represented by the PCBMP; both V kappa 8- and V kappa 24-derived L chains (and, presumably, somatic variants), as well as products of additional V kappa genes (V kappa 1-3), appear to be present in the anti-PC memory pool.     

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.     

Variable regions of antibodies to synthetic polypeptides. II. Analysis of variable region genes encoding antibodies specific for (T,G)-A--L

Monoclonal antibodies specific for the synthetic polypeptide antigen (T,G)-A--L have been produced in two strains of mice, C57BL/10 and C3H.SW. The genes encoding the variable (V) regions of these antibodies have been studied by using the DNA hybridization technique of Southern, as well as by gene cloning and sequencing. Hybridization of DNA from 14 different cell lines with a kappa-chain probe revealed that the different cell lines used one of two different gene rearrangements to encode the recombined V region gene. There was a perfect correlation between light chain rearrangement, idiotype expression, and fine specificity. Hybridization analyses of the heavy chain revealed a more complex pattern. Seven hybridomas had the rearranged heavy chain V region genes on a 4.4 kb EcoRI restriction fragment. Others were found on restriction fragments that differed in length by several hundred base pairs. The recombined heavy chain V region genes were cloned from three different hybridoma cell lines secreting anti-(T,G)-A--L antibodies, all of which express the same idiotype and fine specificity pattern. Restriction mapping and sequencing indicate that all three utilize the same V gene, identified as the 186-2 germline gene. However, different D and J genes are used to encode each of the antibodies. In contrast to the results seen in other antigen systems, heavy chain D and J genes do not have a major influence on idiotype expression and fine specificity of antibodies to the synthetic polypeptide (T,G)-A--L.     

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.     

Murine lambda gene rearrangements: the stochastic model prevails over the ordered model.

The ontogeny of the immunoglobulin (Ig) gene rearrangement in mammalian B cells seems to be ordered. Heavy chain gene segments rearrange first, followed by light chain gene segments, kappa before lambda. The genomic organization of murine lambda locus does not preclude the simultaneous expression of two subtypes from the same chromosome. In order to distinguish between an ordered and a stochastic model of rearrangement, a panel of 67 B cell hybridomas secreting either lambda 1, lambda 2, lambda 3 or lambda x (recently described) were analysed for V lambda J lambda rearrangements. The results show that in 97% of cases, a single rearrangement occurred, favouring the stochastic model over the ordered one. Strikingly, the possibility of having a productive rearrangement if the first try results in an aberrant one is rare. We propose therefore, that the lambda Ig is not necessarily required to ensure allelic and subtypic exclusion mechanisms. Moreover, in 97% of the cases, at least one kappa allele is rearranged. Furthermore, the RS recombination has been detected in 77% of the cases. This suggests that, although the stimulation of kappa precedes that of lambda locus, the RS recombination acts as a transacting albeit dispensable lambda activator.     

Altered repertoire of endogenous immunoglobulin gene expression in transgenic mice containing a rearranged mu heavy chain gene

C57BL/6 mice transgenic for a mu heavy chain gene, the VDJ region of which came from the BALB/c hybridoma 17.2.25, expressed high levels of antibody carrying determinants specific for the transgene (idiotypes). The individual antibodies made by hybridomas from transgenic mice, however, were generally encoded by endogenous genes; in most cases the transgene was present but not expressed. The endogenous, idiotype-positive antibodies had heavy chains that were notable for the high frequencies of JH4 (as in the transgene) and VH segments from the VH81X family (unrelated to the transgene). The expression of endogenous genes mimicking the idiotype of the transgene suggests that a rearranged gene introduced into the germ line can activate powerful cellular regulatory influences.     

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.     

Relationship of human variable region heavy chain germ-line genes to genes encoding anti-DNA autoantibodies

In order to identify the V region genes encoding systemic lupus erythematosus (SLE)-derived anti-DNA autoantibodies, we have determined the nucleotide sequence of heavy chain mRNA from several DNA-binding immunoglobulins secreted by human hybridomas. We used the technique of cDNA primer extension for determining sequences of the VH, D, and JH gene segments of anti-DNA autoantibodies from three different primary hybridoma growths from an SLE patient and one hybridoma from a leprosy patient. Immunoglobulins from two of the SLE hybridomas expressed the same idiotype, Id-16/6, which is also expressed on immunoglobulins in sera of patients with active SLE. Their mRNA sequences showed complete homology to each other in the V, D, and J genes and more than 99% homology to the VH26 germ-line gene sequence, a member of the human VHIII gene family. The VH mRNA sequence of the third SLE hybridoma, 21/28, which was idiotypically unrelated to the other two, was 93% homologous to a different VH germ-line gene sequence, HA2, a member of the human VHI gene family. The fourth anti-DNA-producing hybridoma, 8E10, was derived from a leprosy patient of different ethnic origin than the SLE patient. It was idiotypically related to 21/28 and expressed a VH segment gene identical to that of 21/28. Hybridomas 21/28 and 8E10 shared sequence homology with the VH26 anti-DNA antibodies in the first complementarity-determining region. In addition, 21/28 shared sequence homology with the Id-16/6+ group in the region encoded by the D and J gene segments. Our findings indicate that some SLE autoantibodies are encoded by unmodified or scarcely modified VH germ-line genes that are conserved in the human population and identify two distinct VH germ-line genes that can encode segments of anti-DNA immunoglobulins.     

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.