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.     

The generation of major and minor idiotype-bearing families of anti-p-azophenylarsonate antibodies; stochastic utilization of VH gene segments

An average of 50% of anti-p-azophenylarsonate (Ars) antibodies bear a cross-reactive idiotype, IdCR, and an average of 15% bear a relatively minor idiotype, Id, in A/J mice. To begin to investigate the processes that influence the expressed levels of these idiotype-bearing antibodies in serum, we have examined the frequency among preimmune B cells of cells that utilize the heavy chain variable region gene segment (VH) needed for IdCR and that which is needed for Id anti-Ars antibody expression. Our results indicate these VH gene segments are functionally rearranged at frequencies one would expect for random usage. The frequency of VH gene segment utilization is similar to, if not higher than, that of VHCR, arguing that the predominance of IdCR-over Id-bearing antibodies is not due to preferential usage of the VHCR gene segment. In addition to the analysis of Ars-immune sera pooled from several mice, we have examined 20 individual A/J mice to determine whether the relative serum levels of IdCR- and Id-bearing antibodies are strictly regulated relative to each other. Among individuals, we find that IdCR and Id antibody levels fluctuate over a 28-fold and a 120-fold range, respectively. The ratio of IdCR to Id antibody levels was found not to be strictly regulated, varying over a 300-fold range. Linear regression analysis of IdCR relative to Id concentrations shows a correlation coefficient of only 0.093. Indeed, rare mice can be found that generate greater levels of Id-bearing antibodies than those bearing IdCR. These results are indicative of a stochastic process involved during the generation of these IdCR-and Id-bearing antibody families. Models accounting for the generation of this highly variable serologic response derived from a preimmune repertoire in which VH gene segments are equivalently utilized are discussed.     

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

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

Germline V genes encode viable motheaten mouse autoantibodies against thymocytes and red blood cells

Autoantibodies against thymocytes and RBC may contribute to the pathophysiology of homozygous viable motheaten (mev) autoimmune disease. Whether the production of these autoantibodies in mev mouse results from polyclonal nonspecific B cell activation or specific Ag-driven stimulation is not known. To understand the mechanisms involved in the induction of antithymocyte autoantibody response in mev mouse, we have studied the fine antigenic specificity, structure, and origin of three antithymocyte autoantibodies derived from mev splenic B cell hybridomas. Western blot analysis showed that these mAb bind to polypeptides of 33 and 105 kDa present in RBC and thymocytes, respectively. Additional specificities for the epitopes present in other polypeptides distinguished these three autoantibodies. Northern hybridization and flow microfluorimetry analysis indicated that these hybridomas are derived from the Ly1+ B cell subset. These autoreactive Ly-1 B cell hybridomas, chosen on the basis of their specificity, expressed L chain V genes from a single VK family (VK9) and VH genes from J606 and S107 families. Hybridomas UN34.11 and UN42.5 expressed the VK9 gene identical to that used by peritoneal Ly1+ B cells from various mouse strains and malignant B lymphoma cells secreting anti-mouse RBC treated with proteolytic enzyme bromelin and anti-SRBC antibodies. The third hybridoma, S2-14.2, used a VK9 gene identical to that expressed by MOPC41. None of the VK genes encoding these autoantibodies showed any somatic mutations. In the case of VH genes, the two hybridomas UN42.5 and S2-14.2 derived from two separate fusions, used identical VH genes from the J606 family. The third hybridoma UN34.11 used unmutated V11 germline VH gene, a member of the S107 family. Southern hybridizations, using oligonucleotide probes specific for CDR1 and CDR2, showed that the VH genes encoding the J606 autoantibodies were derived from a germline gene found in the 6.7-kb fragment of EcoRI-digested germline DNA. This germline VH gene is distinct from VH22.1 germline gene that codes for antigalactan antibodies. Sequence analysis of this gene showed perfect homology with the rearranged VH genes confirming the lack of somatic mutations. Thus, our data demonstrate that antithymocyte antibody response occurring in mev mouse is polyclonal and it involves Ly-1 B cells expressing unmutated germline VH and VK genes. These results indicate that antigen driven stimulation may not play an important role in the induction of anti-thymocyte antibody response in mev mouse.     

The association of various D elements with a single-immunoglobulin VH gene segment: influence on the expression of a major cross-reactive idiotype

A large fraction of the anti-p-azophenylarsonate antibodies of strain A/J mice share a major cross-reactive idiotype (IdCR). Structural analysis of monoclonal antibodies expressing this idiotype (IdCR+) indicates that a particular combination of variable region gene segments (Vk, Jk, VH, D, and JH) encodes the variable regions of the light and heavy chains of these IdCR+ antibodies. With the use of serologic methods, hybridoma cell lines have been isolated that produce monoclonal antibodies lacking IdCR determinants (IdCR-), but that are derived from most of the same combination of variable region gene segments that encode IdCR+ monoclonal antibodies. Structural analysis of these IdCR- monoclonal antibodies demonstrates that they are very homologous to each other and to IdCR+ monoclonal antibodies with respect to VH and VL sequences, but are markedly different from IdCR+ monoclonal antibodies in their utilization of D region segments. Comparisons of antigen avidity of these IdCR+ and IdCR- antibodies indicates that conservation of D region structure is not crucial for effective antigen binding. These results indicate the importance of the D region in idiotypy in the IdCR system and demonstrate the variation permitted in D region structure while maintaining antigen recognition.     

A molecular and structural analysis of the VH and VK regions of monoclonal antibodies bearing the A48 regulatory idiotype

The results presented in this paper explore the molecular basis for expression of the A48 regulatory Id (RI). A48 RI+ mAb derived from idiotypically manipulated mice molecularly resembled the A48 and UPC 10 prototypes of this system by utilizing a VHX24-Vk10 combination. Id expression by these antibodies was not restricted by a particular D region sequence, JH, or JK segment, but quantitative differences in Id expression were associated with utilization of different members of the VK10 germ-line gene families. The VL sequences of these A48 RI+ mAb has identified amino acid residues lying in four different idiotope-determining regions which may contribute to the structural correlate of this Id. A comparative sequence analysis of the VH regions of these VHX24 utilizing A48 RI+ mAb with several A48 RI+ mAb utilizing VHJ558 or VH7183 VH genes as well as a hybrid transfectoma antibody derived from two A48 RI-, VHJ558 utilizing hybridomas, all suggested that four nonconsecutive positions which lie outside the idiotope-determining regions may contribute structural elements toward expression of this Id. The VH and VL regions of the A48RI+, VHX24-Vk 10+ mAb showed low to moderate levels of somatic mutation which showed different patterns of distribution between the complementary determining region (CDR) and framework regions in the H and L chains. Although the VK sequences contained 50% of the replacement mutations in the CDR, with a replacement/silent mutation ratio of 10, the CDR of the VH sequences contained only 31% of the replacement mutations with a replacement/silent mutation ratio of 0.69.     

Mouse monoclonal antibodies to chicken VH idiotypic determinants reactivity with B and T cells

We have prepared mouse monoclonal antibodies against idiotypic (Id) determinants on chicken antibodies to N-acetylglucosamine (NAGA) and p-aminobenzoic acid (PABA) made by inbred line EL 6(3) birds. The monoclonal anti-NAGA Id antibody, termed CId-1, reacted with affinity purified antibodies to NAGA, but not with antibodies specific for PABA, arsanilic acid (Ars), phosphorylcholine (PC), or with normal chicken IgG and IgM. The monoclonal anti-PABA ID antibody, termed CId-2, reacted with anti-PABA antibodies and to a lesser extent with anti-Ars antibodies, but not with anti-NAGA, anti-PC, and normal IgG and IgM. The Id determinants were found among antibodies to NAGA and PABA made by outbred and inbred lines of White Leghorn chickens. The binding of the CId-1 and CId-2 antibodies to intact homologous anti-NAGA and anti-PABA antibodies, respectively, was not hapten-inhibitable in either case. Both anti-Id antibodies reacted specifically with isolated homologous heavy chains, suggesting VH Id specificities. The monoclonal CId-1 and CId-2 antibodies were reactive by immunofluorescence with approximately 0.9 and 0.2%, respectively, of the circulating lymphocytes and with approximately 0.4 and 0.15 of plasma cells. CId-1+ and CId-2+ bursal cells were first detected on the 16th and 14th days of incubation, respectively; both reached maximal frequencies by the 17th day of incubation. The CId-2 antibody reacted exclusively with immunoglobulin-positive cells. The CId-1 antibody also reacted with a subpopulation (0.4%) of immunoglobulin-negative lymphocytes from normal and agammaglobulinemic chickens, and thus would appear to recognize an idiotypic determinant expressed by certain clones of B and T cells.     

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

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

Humanized mouse G6 anti-idiotypic monoclonal antibody has therapeutic potential against IGHV1-69 germline gene-based B-CLL

In 10–20% of the cases of chronic lymphocytic leukemia of B-cell phenotype (B-CLL), the IGHV1-69 germline is utilized as VH gene of the B cell receptor (BCR). Mouse G6 (MuG6) is an anti-idiotypic monoclonal antibody discovered in a screen against rheumatoid factors (RFs) that binds with high affinity to an idiotope expressed on the 51p1 alleles of IGHV1-69 germline gene encoded antibodies (G6-id⁺). The finding that unmutated IGHV1-69 encoded BCRs are frequently expressed on B-CLL cells provides an opportunity for anti-idiotype monoclonal antibody immunotherapy. In this study, we first showed that MuG6 can deplete B cells encoding IGHV1-69 BCRs using a novel humanized GTL mouse model. Next, we humanized MuG6 and demonstrated that the humanized antibodies (HuG6s), especially HuG6.3, displayed ～2-fold higher binding affinity for G6-id⁺ antibody compared to the parental MuG6. Additional studies showed that HuG6.3 was able to kill G6-id⁺ BCR expressing cells and patient B-CLL cells through antibody-dependent cell-mediated cytotoxicity (ADCC) and complement-dependent cytotoxicity (CDC). Finally, both MuG6 and HuG6.3 mediate in vivo depletion of B-CLL cells in NSG mice. These data suggest that HuG6.3 may provide a new precision medicine to selectively kill IGHV1-69-encoding G6-id⁺ B-CLL cells.     

Molecular analysis of heavy and light chains used by primary and secondary anti-(T,G)-A--L antibodies produced by normal and xid mice

The primary (1 degree) antibody response to (T,G)-A--L shows limited heterogeneity, consisting mostly of side chain-specific antibodies that bind GT and that express the TGB5 idiotype (Id). The secondary (2 degrees) response is very diverse: antibodies that bind the backbone A--L constitute a third of the response, and a high proportion of the side chain-specific antibodies do not bind GT and are TGB5 Id-. To provide a molecular basis for understanding this difference in repertoire expression, we analyzed the Ig genes used by heavy and light chains of 1 degree and 2 degrees side chain-specific anti-(T,G)-A--L hybridoma antibodies (HP). Southern blot restriction analysis and nucleotide sequence analysis of the expressed genes used by three TGB5 Id+ 2 degrees HP showed usage of three different VH genes in two VH gene families (36-60 and J558), different D segments, and two different Vk1 genes (the Vk1A and Vk1C subgroups). Thus, antibody heterogeneity in the 2 degrees response is contributed by combinatorial diversity of distinct germ-line genes. Nucleotide sequence analysis of the expressed genes used by TGB5 Id+ 1 degree HP showed use of highly homologous VH genes in the J558 VH gene family and highly homologous Vk1A genes. The majority of TGB5 Id+ 1 degree HP from different donors gave similar heavy and similar light chain gene rearrangements by Southern blot restriction analysis, after correction for known or potential J region differences. The combined nucleotide sequence and Southern blot restriction analysis data suggest that most 1 degree B cells use the same or very similar VH and Vk genes, i.e., the 1 degree response is paucigenic. Different D segments were used by the TGB5 Id+ 1 degree and 2 degrees HP that were sequenced, and there was no apparent correlation between TGB5 idiotypy and VH, D gene, or JH gene usage. However, all TGB5 Id+ HP sequenced used highly homologous genes from the Vk1 group. Expression of a Vk1 light chain correlates with, but is not sufficient for, TGB5 idiotypy, because one GT-binding, TGB5 Id- HP was found to use a Vk1C subgroup light chain. By Southern blot and nucleotide sequence analysis, the Vk genes used by two TGB5 Id+ 2 degrees HP from xid mice are highly homologous, if not identical to the Vk1A gene(s) used by 1 degree and 2 degrees Id+ HP from wild-type mice.     

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

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

The BALB/c secondary response to the Sb site of influenza virus hemagglutinin. Nonrandom silent mutation and unequal numbers of VH and Vk mutations

We have determined the nucleotide sequences of the expressed VH and Vk genes from 13 secondary (2 degrees) hemagglutinin (HA) (Sb) specific hybridomas derived from a single mouse. These antibodies share an Id, H37-68 (68Id) that dominates the 2 degrees HA(Sb) response in this mouse, but is rare or absent from 2 degrees responses of other mice. We find that these antibodies derive from five clones. The H chains of these antibodies are encoded by a single VH gene joined to a variety of DH and JH genes. The length of complementarity-determining region (CDR) 3 and sequence of the D-J junction are restricted, suggesting selection on CDR3 of the H chain. The L chains are more diverse. In the presented examples, they are encoded by the Vk21C and Vk21E genes and a Vk9 gene, and are joined to Jk1, 2, or 4. Each antibody is extensively mutated. The nature and distribution of the mutations suggests that 68Id-producing cells have been selected by Ag, although there are differences regarding the domain (VH, Vk, or both) in which mutations were selected. The implications of these findings on the idiosyncratic nature of the 68Id antibody response to HA(Sb) are discussed. There are two unusual characteristics regarding somatic mutation in these hybridomas. Whereas the expressed VH and Vk21 genes appear to have accumulated mutations at a high rate (1 to 1.5 x 10(-3)/base pairs/division, the expressed Vk9 genes appear to have accumulated mutations at a 5 to 15-fold lower rate than the expressed VH genes in the same cells. There is also a surprisingly high number of parallel silent somatic mutations in the VH genes, of which all but one are clustered to a 28-bp region in framework region 2 and CDR 2-encoding segments. The probability that this could have occurred by a random mutational process is essentially zero.     

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

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

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.     

A single amino acid mutation in CDR3 of the 3-14-9 L chain abolished expression of the IDA 10-defined idiotope and antigen binding.

The ABPC 48 myeloma protein and the 3-14-9 mAb derive their V region genes from the same VH and V kappa gene families. They also share a cross-reactive idiotope defined by the anti-Id mAb IDA 10. Whereas ABPC 48 is specific for bacterial levan, 3-14-9 showed a significant Ag-binding activity to aminophenyl-beta-N-acetylglucosaminide (AZO). In order to define the molecular basis of idiotope expression and Ag-binding activity, we have cloned the genes encoding the 3-14-9 H and L chain V region genes, generated antibodies that carry mutations within the L chain genes, by site-directed mutagenesis, and investigated the effects of those mutations with respect to IDA 10 idiotope expression and binding to AZO. Our findings show that, whereas expression of the IDA 10-defined idiotope requires association of both the H and L chains, a single change (glycine to phenylalanine) at position 91 in the third complementarity-determining region of the L chain abolished both idiotope expression and Ag-binding activity. In addition, a L chain change of alanine to threonine at position 25 allowed idiotope expression to some extent but significantly reduced binding activity to AZO. These data suggest that a single amino acid change can play a crucial role in the functional activity and structural integrity of antibodies.     

A V kappa-J kappa junctional change in an antidigoxin recombinant antibody destroys digoxin-binding activity

A set of high affinity antidigoxin antibodies were previously identified with high homologous V kappa 1A L chain sequences but were associated with two entirely different VH regions and two dramatically different specificities for digoxin analogs. Antibodies 40-20, 40-60, 40-90, and 40-100 displayed similar binding specificities but differed from that of antibody 26-10. In a previous study using somatic cell fusion for Ig chain recombination we demonstrated that a recombinant antibody consisting of the H chain of antibody 26-10 and the L chain of antibody 40-20 retained digoxin binding and the 26-10 Id, but displayed a binding specificity pattern dominated by the 26-10 H chain donor. In the present study we produced three additional chain recombinant antibodies that contain the 26-10 H chain recombined with each of the L chains of antibodies 40-60, 40-90, and 40-100. All four recombinants expressed the 26-10 Id indistinguishably from the 26-10 antibody. Two of the recombinants (using the 40-60 and 40-90 L chains) bind digoxin; however, the recombinant using the 40-100 L chain failed to bind digoxin. Complete sequence analyses of the 40-20, 40-60, 40-90, and 40-100 VH and VL regions were performed. Antibodies 40-90 and 40-100 have identical VH region sequences but differed only in their L chains at position 96 (proline/leucine). This single difference at the VK-JK junction abolished digoxin binding in the context of one H chain (26-10), but does not cause a significant change in binding in association with the "normal" parental chains 40-90 and 40-100. Thus, structurally closely related VL regions can recombine with different VH regions to form digoxin binding sites of different specificity; in one binding site the identity of a L chain junctional residue is critical whereas in the second binding site that residue is unimportant. Molecular modeling studies revealed major differences between calculated binding site structures for 26-10 when leucine is substituted for proline at position 96 in the 26-10 VL region.     

Molecular analysis of a germ line-encoded idiotypic marker of pathogenic human lupus autoantibodies

Id-16/6 is an idiotypic marker found in both IgM and IgG antibodies, as well as in the tissue lesions of patients with SLE. The prototypic Id-16/6+ mAb is 18/2, whose VH3-derived H chain is encoded by an unmutated germ-line gene. We found that the H chains of VH3-derived Id-16/6+ antibodies contain the major determinants of Id-16/6. Moreover, B cell clones from which those antibodies were harvested produce RNA that hybridized under conditions of high stringency to oligonucleotide probes corresponding to the CDR of the VH segment of 18/2. Western blots of Id-16/6+ mAbs with anti-Id confirmed the association of the Id with H chains. Id-16/6 can identify a subgroup of VH3-derived antibodies we have termed the 18/2 CDR family. However, Id-16/6 can also be expressed in some antibodies unrelated to the 18/2 CDR family. No characteristic Ag-binding specificity was found among the members of the 18/2 CDR family. The principal phenotypic feature shared by all known members of the family is Id-16/6.     

Regulation of idiotope expression. III. H-2 influences the magnitude and the idiotypy of a T-independent antibody response in mice of certain genetic backgrounds

Antibody response to the phosphocholine (PC) epitope on Streptococcus pneumoniae R36a (Pn), a T-independent Ag type 2, was studied in H-2 congenic mouse strains. The PC-specific antibody plaque-forming cells (PFC) were enumerated in the spleen at various intervals after the primary Pn injection, and the proportion of PFC that produced antibody expressing the AB1-2 idiotope (Id) was determined by using the corresponding monoclonal anti-Id. AB1-2 is a cross-reactive Id, detectable on germline-encoded PC antibody of the T15 family, and on most, but not all, somatic variants of that antibody. The specific PFC responses in BALB/c (H-2d) and BALB.B (H-2b) strains were of comparable magnitude and most, if not all, PFC were ABl-1 Id-positive (AB1-2+). This was not the case in the responses of the B10D2 (H-2d) vs C57BL/10 (H-2b) strains and the D1.C (H-2d) vs D1.LP (H-2b) strains (on DBA/1 background). In each of these pairs, the H-2d mice were high responders, and the response was dominated by AB1-2 Id (greater than or equal to 80% AB1-2+ PFC at the peak, on day 5). The H-2b mice were low responders, and only a minor proportion of PFC (less than or equal to 30%) were AB1-2+; an increase of AB1-2+ was seen later in the response (d.10). The results of PFC assays were confirmed by measuring the PC-binding antibody and AB1-2 Id in the sera of D1.C and D1.LP mice immunized repeatedly with Pn. Moreover, D1.LP mice that had very low levels of AB1-2 Id had higher serum levels of antibody expressing two other T15 Id, B36-82, and B24-44. The B36-82 and B24-44 Id have been previously found on somatic variants of PC antibody expressed independently of the Ab1-2 Id. The concentrations of these two Id in D1.LP mice after repeated immunization approached those in D1.C. These results indicate that 1) the H-2 allelism may have a significant effect on TID antibody response in mice of a certain genetic background, but not in the BALB/c; and 2) the idiotypic repertoire of the response may be influenced by H-2 at the level of clonal variants of PC-reactive cells.     

Expression of a cross-reactive idiotope on naturally occurring murine antibodies against 3-fucosyllactosamine, levan, and dextran

We recently identified a cross-reactive Id (6C4) that is expressed on the H chain of many BALB/c mAb against the 3-fucosyllactosamine (3-FL) determinant, Gal(beta 1-4) (Fuc(alpha 1-3] GlcNAc-R. The VH segments of seven mAb that we recently sequenced are encoded by VH441, which also encodes VH segments of antibodies against galactan, levan, and dextran. To analyze the expression of the 6C4 Id on naturally occurring anti-carbohydrate antibodies, we isolated 6C4+ antibodies by affinity chromatography from pools of normal BALB/c serum. Approximately 20 to 30% of antibodies against 3-FL and levan, and all antibodies against dextran, were removed from the sera by passage over a column containing mAb 6C4. Absorption of the eluate with 3-FL beads removed anti-3-FL antibodies but not anti-dextran or anti-levan. The expression of a cross-reactive Id on naturally occurring antibodies against several carbohydrate Ag suggests that these antibodies may participate in an Id network. We also reported previously that BALB/c mice have naturally occurring anti-3-FL antibodies and respond well to immunization against this determinant, whereas C57BL/6 mice do neither. To examine the role of the Igh-C allotype in the regulation of the anti-3-FL response, we studied congenic strains of BALB/c and C57BL/6 mice. Both congenic strains produced anti-3-FL antibodies in response to immunization, but only C.B-20 mice exhibited naturally occurring antibodies. These data suggest that the naturally occurring and elicited antibody responses against 3-FL are differentially regulated.