Patterns of mutations and selection in antibodies to the phosphocholine-specific determinant in Proteus morganii

The contribution of somatic mutation to the generation of an antibody response was investigated by using the phosphocholine (PC) determinant in the bacterium Proteus morganii as the model Ag. The response to this determinant is restricted to a single VH/VL pair and apparently is derived from only one or two precursors per mouse. In this study we examined hybridoma antibodies from nine individual mice which produced representatives of 12 different clones. We found that all antibodies reactive with the PC Ag of P. morganii contained somatic mutations; the number ranged from 2 to 20. Two clusters of mutations were observed, one in complementarity-determining residue (CDR) 2 and the other in CDR 3 of VH. Examination of a three-dimensional model of M603, an antibody with the same V region composition as the anti-PC antibodies under study, showed that these clusters occupied an area of the binding site which presumably interacts with carrier elements of the PC epitope in P. morganii. A high incidence of recurring mutations were found in both clusters, and one of these was invariant, leading to an Asn for Asp substitution at 95. Ag binding studies with these antibodies and an additional one, which was unmutated except for the invariant substitution at 95, showed that: 1) antibodies having only the 95Asn mutation failed to bind the PC Ag of P. morganii, 2) addition of a second recurring mutation, at 52a (CDR 2), was sufficient to create strong binding to the P. morganii Ag, and 3) accumulation of mutations was directly correlated with increased binding activity for Ag. These results show that somatic mutations play a critical, if not essential, role in generating specificity for this PC Ag, and that Ag, and most likely a carrier element of the epitope, is a primary force in the continued selection and expansion of Ag-reactive B cells.     

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.     

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.     

T15 D region germ line amino acid sequences distinguished by monoclonal anti-idiotope antibody

Monoclonal antibody NL16, prepared with phosphorylcholine (PC)-binding myeloma protein C.BBPC3 (C3), identified an idiotope (C3-16 Id) that was present on T15 IdX+ myeloma proteins (MP) C3, T15, and H8, but not the T15 IdX- MP M167 and M603. The binding of C3 to NL16 is PC inhibitable, indicating that C3-16 Id is site associated. Inhibition studies with PC-specific hybridoma proteins (HP) demonstrated that the T15-type L chain VK22 and elements of the H chain were required for C3-16 Id expression. Studies of amino acid sequences of these PC-binding HP and MP showed that VK22+, T15 IdX+ HP, and MP that use the T15 D region (YYGSS) sequences were always C3-16 Id+. However, the reverse was not true, because all but one VK22+, T15 IdX+ HP with D region sequence changes were C3-16 Id-. This suggested that NL16 defined a specificity mainly determined by the D region of the H chain. A direct test of this hypothesis with heterologous heavy/light chain recombinant molecules obtained from C3-16 Id+ and C3-16 Id- HP of known sequence, showed that the D region was critical to idiotope expression. Additionally, an examination of the amino acid sequences of VK22+, T15 IdX- HP, HPCG14, and HPCM6 suggest that profound changes in the D region may also alter the expression of T15 IdX (an Id defined by a multispecific antiserum from A/He mice). The C3-16 Id+ was found in anti-PC serum of most Ig haplotype-inbred strains except for CBA/J, C3H, and PL, which are all of the Igh-Cj haplotype. Amino acid sequences of PC-binding CBA and PL HP showed marked changes in the D region from the T15 type, and this may account for the C3-16 Id- character of Igh-Cj strains.     

Resistance to Streptococcus pneumoniae is induced by a phosphocholine-protein conjugate

Previous studies demonstrated that naturally occurring antibodies to the pneumococcal cell wall hapten phosphocholine (PC) are important for the survival of mice against infection with Streptococcus pneumoniae, and that passively administered hybridoma antibody to PC results in added resistance. To determine if a PC-protein conjugate could elicit protective levels of anti-PC antibody, mice were immunized with PC-keyhole limpet hemocyanin (KLH) and tested for their ability to resist challenge with virulent S. pneumoniae. PC-KLH-immunized mice were observed to be resistant to 10- to 1000-fold more organisms than unimmunized control animals. The levels of protection were comparable to those induced with capsular polysaccharide antigens, but had the advantage of not being type-specific; immunization with PC-KLH protected mice against both type 1 and type 3 organisms. The induced immunity appeared to be antibody-mediated; it could be passively transferred with immune serum, and absorption of the immune serum with PC-Sepharose removed its protective capacity. Anti-PC antibodies in the serum of immunized mice were primarily IgM and IgG3 and possessed predominantly the T15 idiotype. Antibodies with these particular isotypes and this idiotype also arise after immunization with heat-killed rough pneumococci and recently were shown to be important in the resistance of mice to pneumococcal infection.     

Helper T lymphocytes from xid and normal mice support anti-phosphocholine antibody responses with equivalent T15, 511, and 603 idiotypic composition

We have examined the idiotypic composition of secondary adoptive transfer antibody responses to phosphocholine (PC) supported by KLH-primed helper T cells derived from normal mice or xid mice. CBA/N x BALB/c F1 male xid mice have diminished anti-PC responses and virtually undetectable levels of the T15 idiotype; xid mice do express the 511 and 603 idiotypes. Nonetheless, we find helper T cells derived from such mice are indistinguishable from T cells primed in a normal environment in their ability to cooperate with B cells producing anti-PC antibody bearing the T15, 511, or 603 idiotype markers. This result is in contrast to a previously published report from this laboratory. T cells from xid mice did support more IgG PFC than normal T cells, but serum IgG anti-PC antibody levels were similar in both groups. The IgM anti-PC response was predominantly of the T15 idiotype, whereas the 511 idiotype was associated with a minor fraction of IgG1 antibodies. The majority of the secondary IgG "anti-PC" antibody response bore none of the idiotypic markers associated with PC-binding myeloma or hybridoma antibodies, and was directed against phenyl-PC rather than PC. The phenomenon of T15 clonal dominance in the anti-PC response therefore is largely confined to the IgM response. We would conclude that the idiotype levels in the T cell priming environment do not influence the subsequent ability of such primed T cells to support anti-PC antibody responses.     

Isoelectric focus analysis of rat anti-phosphocholine antibodies.

Anti-phosphocholine (PC) antibodies in sera from four strains of rats were examined before and afterimmunization with either Streptococcus pneumoniae R36A, which contains PC as a cell wall component, or with PC-coupled keyhole limpet hemocyanin (PC-KLH). PC-specific protein was purified from pooled immune sera and shown by a combination of isoelectric focus (IEF) in acrylamide and crossed immunoelectrophoresis, as well as by molecular weight determination in NaDodSO4-acrylamide, to be immunoglobulin. An additional, small molecular weight, nonimmunoglobulin protein (pI = 7.1-7.3) was present in sera from normal and germ-free rats which had the ability to bind the C-carbohydrate of S. pneumoniae R36A, but without specificity for PC. The IEF profile of normal and immune sera showed marked sharing of bands of anti-PC antibody between individual rats as well as between strains. In addition, other anti-PC antibodies which focused between pH 8.5 and 9.5 were less regularly shared. The uniformity of IEF profile of the bulk of anti-PC antibodies in rats is most consistent with their being the products of germ line genes.     

Structural evidence for a polymorphic or allelic form of the heavy chain variable region.

The heavy (H) chains of anti-phosphocholine (PC) antibodies from C57BL/6J and CBA/J were sequenced through the N-terminal 36 residues and compared with previously published sequences of A/J anti-PC antibody and BALB/c PC-binding myeloma proteins T15, M603, and M511. Each of these antibody preparations contained molecules having light (L) chains and idiotypic determinants of T15, M511, and M603 indicating the presence of at least three different anti-PC antibodies in each pool. The structures of the C57BL/6J and CBA/J H chains each revealed a single sequence from positions 1 to 36 (which includes the first complementarity determining region (CDR), and they were identical. The first CDR was identical to that previously found for BALB/c and A/J indicating that this portion of these antibody molecules is highly conserved throughout inbred mice and is probably critical to PC-binding. A surprising finding was that both C57NL/6 and CBA sequence differed from the BALB/c and A/J sequences at two positions, residue 14 and 16. Since each of these strains differs at the allotype locus, the data indicates that the evolution of allotypy in mice occurred after variable region diversity for the particular genes.     

Amino acid sequence of a phosphocholine-binding antibody from an immune defective CBA/N mouse employing the T15 VH region associated with unusual DH, JH, and V kappa segments

Mice expressing the xid gene exhibit an altered immune response to phosphocholine (PC)-conjugated keyhole limpet hemocyanin (KLH). Less than 25% of their anti-PC-KLH response is PC specific, and most of these antibodies lack the normally predominant T15 idiotype. These findings suggested that immune defective mice might employ different variable region genes than normal mice in their anti-PC response. To examine this possibility, we characterized by Southern blot analysis the gene family encoding PC-VH regions and determined the amino acid sequence and fine specificity of binding of a T15-, IgG2, PC-specific hybridoma (1B8E5) produced by fusion of the SP2/O cell line and PC-KLH immune CBA/N spleen cells. Southern blot analysis of DNA from CBA/N mice by using a PC-VH probe (S107 VH) revealed a hybridization pattern virtually identical to that of DNA from normal CBA/J mice, indicating that CBA/N mice do not suffer from a gross deletion of PC-VH genes. Analysis of the 1B8E5 antibody reveals that both the binding specificity and relative affinity of this antibody are different from the anti-PC antibodies of the T15, M167-M511, and M603 families. The complete amino acid sequence of the heavy (H) chain variable region shows that 1B8E5 uses a VH segment identical to the allelic form of T15 (C3) but has a unique D region of three amino acids and use the JH1 joining segment. Both the DH and JH regions are unusual when compared to PC-specific antibodies from normal mice, which have a D region composed of five to eight amino acids and use the JH1 joining segment. The amino terminal sequence of the 1B8E5 light (L) chain demonstrates that this anti-PC antibody carries a Vk3 subgroup L chain. Chains from this subgroup have not previously been found in association with PC-binding antibodies. Thus, the Vk, DH, and JH segments expressed in 1B8E5 make this hybridoma unique in terms of the anti-PC antibodies studied to date, and suggests that additional PC-specific antibodies exist in inbred mice that employ "unusual" V gene segments.     

Induction of immune response to Streptococcus pneumoniae by administration of oral viridans streptococci via phosphorylcholine determinant

Expression of the phosphorylcholine (PC) epitope was examined in 48 viridans streptococcal strains, including Streptococcus pneumoniae R36a as the positive control, and their immunogenicity to induce an S. pneumoniae-cross-reactive response was evaluated in mice. Thirteen strains were found to express the PC epitope, while no obvious association was found between the taxonomic categories and PC expression. Serum antibody responses to S. pneumoniae cells were induced in mice by intraperitoneal injection of the PC-positive, but not PC-negative, strains. The cross-reactive antibodies induced by non-pneumococcal oral streptococci were readily inhibited by free hapten PC. IgM was the sole isotype of the anti-pneumococcal and anti-PC antibodies, and the phenomenon of immunological memory was not observed. Since the anti-PC antibody is critically important for resistance against pneumococcal infection in mice, the present results indicate the possibility that PC-expressing oral commensal bacteria have a significant influence on the hosts' responsiveness to S. pneumoniae.     

Properties of anti-idiotypic T cell lines propagated with syngeneic B lymphocytes. I. T cells bind intact idiotypes and discriminate between the somatic idiotypic variants in a manner similar to the anti-idiotopic antibodies

We describe the development of T cell lines possessing a binding specificity for syngeneic T15 idiotopes (Id) expressed on phosphorylcholine (PC)-reactive Ig. The lines were obtained by cultivation of BALB/c splenic T cells with T15 Id+ stimulator cells BCg3R-1d, a BALB/c lymphoma transfected with genomic sequences mu and kappa with S107 (T15) variable regions. Resulting Thyl-2+, L3T4+ cell lines depend on the T15 Id+ BCg3R-1d cells for growth and demonstrate the ability to bind TEPC15, a S107 germline-encoded, PC-specific Ig alpha. The specificity of the 125I-TEPC15 binding was studied in a competitive RIA with various unlabeled Ig. The isolated H and L chains of TEPC15 failed to inhibit the 125I-TEPC15 binding, and the T15-, PC-binding proteins M603 (alpha) and M511 (alpha) inhibited the binding either poorly or not at all. Moreover, the T cell lines had a discriminatory binding specificity for various T15+ Ig that are somatic variants of TEPC15 and that differ from each other in discrete, conformational Id (epitopes) detectable with specific monoclonal anti-Id. The T cell lines could be grouped according to their binding patterns, which were comparable to the recognition patterns of certain monoclonal anti-Id. These data suggest the existence of T cells with specificity for serologically-defined determinants of syngeneic idiotypes.     

Differential L chain expression in the antibody responses to phosphorylcholine of adult bone marrow or peritoneum-derived B lymphocytes

Lethal irradiation of adult BALB/c mice followed by reconstitution with autologous bone marrow results in loss of T15 Id and IdX expression in the responses to phosphorylcholine (PC) and alpha(1-3)-dextran, respectively. T15 Id, but not IdX expression can be reconstituted with low numbers of syngeneic, T cell-depleted peritoneal resident cells. All three groups of mice produce comparable titers of specific anti-PC and anti-dextran antibodies. The inability of adult bone marrow-reconstituted BALB/c mice to produce T15 Id+ antibodies is not due to differential VH-gene expression in bone marrow or peritoneum-derived B cells. Thus, the levels of T15 VH in total serum Ig and in anti-PC antibodies are similar in all groups of mice. Furthermore, IEF patterns of T15 VH-associated L chains directly demonstrate differential Vk repertoire expression in bone marrow and peritoneum-derived B cells.     

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.     

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.     

IgA isotype-restricted idiotypes associated with T15 Id+ PC antibodies

Idiotypes are believed to be due to the structural conformation of the variable region of immunoglobulins (Ig). We have found an idiotype (C3-24) that requires both variable and constant regions of the heavy chain to be expressed. C3-24 Id is associated with both the T15 variable region from anti-phosphorylcholine (PC) antibodies and the constant region for the alpha-heavy chain. High titer anti-PC serum from a variety of inbred strains of different Ig haplotypes failed to express C3-24 Id. However, when IgA but not IgG or IgM fractions were isolated from a pool of anti-PC serum from BALB/c mice, more than 70% of the molecules expressed C3-24 Id. The high frequency of the expression of C3-24 Id in IgA anti-PC hybridoma proteins from mice of different Ig haplotypes and in the IgA fraction of normal anti-PC antibodies from BALB/c and presumably other strains of mice suggests that idiotypic determinants produced by the three-dimensional product of VH and CH regions may not be unusual.     

Alteration of the B cell surface phenotype, immune response to phosphocholine and the B cell repertoire in M167 mu plus kappa transgenic mice

M167, mu plus kappa, transgenic mice have been analyzed for the expression of the transgene product as a cell surface, Ag-specific receptor and for their ability to respond to Ag. The vast majority of B cells in these H + L transgenics (97 to 99%) express large amounts of the transgene product on their surface and are capable of binding phosphocholine. A total of 4 to 30% of the B cells also express endogenous IgM and IgD H chain products. After immunization with phosphocholine (PC)-conjugated keyhole limpet hemocyanin, more than 1000 micrograms/ml of anti-PC antibody bearing the transgene IgMa allotype marker are produced. Surprisingly, significant amounts of anti-PC antibodies that express the endogenous, IgMb allotype, are also produced; however, these antibodies lack the T15-idiotype which dominates the anti-PC response in their nontransgenic littermate controls. The B cells producing these endogenous anti-PC antibodies also fail to switch to IgG anti-PC synthesis, whereas B cells producing anti-keyhole limpet hemocyanin antibodies readily undergo class switching. These last two observations may be due to the fact that the endogenous anti-PC antibody actually results from mixed mu a + mu b molecules in which the transgene encoded H and L chains are most likely responsible for the binding of PC. Thus, a switch of the endogenous isotype from mu b to IgG would result in a loss of specificity for PC in the IgG molecules produced using the endogenous VH-gene product(s), and mu a + gamma b hybrid molecules are not likely to be formed. This hypothesis is supported by the fact that the majority of (mu a + mu b) hybridomas have the mu b-allotype joined with a VH region other than the VH1 gene which is required for PC-binding and T15 idiotype expression.     

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.     

A phosphorylcholine idiotype related to TEPC 15 in mice infected with Ascaris suum.

A serum component, binding antigens having phosphorylcholine (PC) determinants were induced in several strains of mice by infection with Ascaris suum. This component was isolated and demonstrated to be an IgM (K) anti-PC antibody having idiotypic determinants in common with the IgA PC-binding myeloma protein TEPC 15. Rabbit anti-idiotypic antisera prepared with this component had idiotypic specificity for TEPC 15 and cross-idiotypic recognition of MOPC 167 and McPC 603, all IgA PC-binding myeloma proteins. The antisera also recognized determinants not present on TEPC 15. IgM and idiotype levels were quantitated by radial immunodiffusion and PC-specific antibody measured by hemagglutination (HA) with sheep erythrocytes coated with pneumococcal-C-polysaccharide. Mean IgM levels ranged from 2.5 to 8.7 mg/ml, idiotype from 0.54 to 5.3 mg/ml; and HA titers from 1:512 to 1:130,000 in different mouse strains. The high PC-specific antibody response was not duplicated by immunization with dead ascaris larvae or by infection with two other nematode species.     

"Nonspecific" immunoenhancing T cells in tumor-bearing mice include anti-idiotypic subsets

Splenocytes from DBA/2 mice inoculated 3 wk earlier with syngeneic P815 mastocytoma tumor cells produce increased numbers of antibody plaque-forming cells (PFC) when stimulated with either sheep red blood cells (SRBC) or phosphorylcholine (PC) on Streptococcus pneumoniae R36a in vitro. The nature of this nonspecific hyperreactivity was investigated in mixed cultures of purified splenic T and B cells. The addition of T cells from P815 tumor-bearing mice (TP815) into the cultures of normal B cells produced a significant enhancement of the PFC response to both SRBC and PC, when compared with the effect of normal T cells added to control cultures. The idiotypic profile of the enhanced anti-PC response was studied by a PFC-inhibition assay with monoclonal antibodies against two distinct idiotopic determinants (Id) of the T15 family. Normal B cells produced greater than 90% of T15 Id-positive (Id+) PFC. Addition of normal T cells diminished the proportion of T15 Id+ PFC to approximately 60%, whereas the rest of PFC were Id-. Addition of the immunoenhancing TP815 cells into the normal B cells cultures elevated the number of both T15 Id+ and Id- PFC responses, proportionally. However, when TP815 cells were first incubated on T15 protein-coated dishes and the non-adherent fraction was added to B cell cultures, the anti-PC PFC response remained enhanced but consisted of predominently T15 Id- PFC. These observations suggest that the early stage of P815 tumor growth activates various populations of specific helper/amplifier T cells including subsets with anti-idiotypic activity and that the generalized increase of antibody response to various antigens in tumor-bearing mice may be regarded as a polyclonal activation of specific T cells.