Immunocytochemical detection of kappa and lambda light chain V region subgroups in human B-cell malignancies.

We have used a sensitive immunoperoxidase method and highly specific anti-light chain antisera to determine the light chain variable region (VL) subgroup nature of cytoplasmic (c) and cell surface (s) Ig expressed by human monoclonal plasma cells and B lymphocytes. The immunocytochemical characterization of cIg and sIg used antisera specific for the established kappa light chain V kappa subgroups (V kappa I, V kappa II, V kappa III, and V kappa IV) and the lambda light chain V lambda subgroups (V lambda I, V lambda II/V, V lambda IV, and V lambda VI). Studies were performed using cytospin preparations of bone marrow-, peripheral blood-, and lymph node-derived cells from patients with multiple myeloma, amyloidosis AL, and Waldenström''s macroglobulinemia and with low-, mid-, and high-grade B-cell malignancies. The V kappa or V lambda subgroup of the cIg or sIg also could be identified after deparaffinization and enzyme treatment of formalin-fixed, paraffin-embedded specimens. For those patients who had monoclonal serum or urinary Igs, there was complete concordance between the VL subgroup of the secreted Ig and that of the cIg or sIg. The percentage distribution of V kappa or V lambda subgroups on the sIg of cells from patients with chronic lymphocytic leukemia (CLL) and other cytomorphologic types of B-cell malignancies differed from that found for kappa- or lambda-type Bence Jones proteins obtained from patients with multiple myeloma, amyloidosis AL, and Waldenström''s macroglobulinemia. In contrast to the plasma cell and lymphocytoid plasma cell diseases, a relative predominance of certain VL subgroups, ie, V kappa IV, V lambda III, and V lambda IV, and the absence of the amyloid-associated V lambda VI subgroup were found in CLL and related diseases. The immunocytochemical techniques used make possible a rapid means to demonstrate B-cell monoclonality and provide further evidence for the selective expression of certain VL genes in human B-cell neoplasia.     

Comparison between hybridoma and Fab/phage anti-RhD: their V gene usage and pairings

Our 11 anti-RhD's in conjunction with 37 previously published RhD antibodies, produced by hybridoma technology were analysed for germline gene usage and restriction in VH and VL pairings. The 17 VH germline genes used by the hybridoma anti-RhD IgG were derived from 4 VH families (VH1, VH2, VH3 and VH4). Eighteen kappa chains were restricted to only 5 germline genes from only 2 V kappa families (V kappa 1 and V kappa 3). However, the 13 lambda chains were not as restricted, using 10 V lambda germline genes from 4 families (V lambda 1, V lambda 2, V lambda 3 and V lambda 8). Fifty six unique Fab/phage anti-RhD were also analysed. In all cases the Fab/phage VH germline genes were derived from the VH3 family (41/41). The 29 kappa chains were restricted to 4 germline genes primarily from V kappa 1 (97%) and the 24 lambda chains used 10 V lambda germline genes from 5 families (V lambda 1, V lambda 2, V lambda 3, V lambda 4 and V lambda 7). The VH germline genes of the Fab/phage were restricted to 4 of the 17 used by the hybridoma anti-RhD IgG (DP46, DP49, DP50 and DP77). Ninety percent of the Fab/phage were restricted to 1 of the 5 V kappa germline genes used by the IgG (DPK9). However, the repertoire of the V lambda germline genes used in these two systems is different, with analysis showing greater diversity in V lambda gene usage with 8 unique germline genes used by 76% Fab/phage compared to 4 unique genes used by 46% of the IgG hybridoma anti-RhD.     

The repertoire of human antibody to the Haemophilus influenzae type b capsular polysaccharide.

Human antibody to the Haemophilus influenzae capsular polysaccharide (Hib CP) is restricted in diversity in the individual and the population with a limited number of variable region genes encoding antibody. Antibody to the Hib CP shows restricted isoelectric focusing gel patterns and light chain usage with frequent restriction to use of only kappa light chains. Shared cross-reactive idiotypes are expressed on antibody. The heavy chain of antibody to the Hib CP is predominantly encoded by two members of the VH3 family--LSG 6.1/M85-like and VH26/30P1-like. In VH the CDR1, based on complete identity in LSG 6.1/M85-like antibodies, CDR2, based on the suggestion of mutation in this region, and CDR3, based on conserved CDR3 usage in unrelated individuals, may be important for antigen binding. Six or more different VL gene families encode antibody. The predominant antibody of the majority of individuals uses the A2-V kappa II gene in germline or near germline configuration, which encodes an idiotype designated HibId-1. Antibody can also be encoded by V kappa I, non-A2 V kappa II, V kappa III, V kappa IV, V lambda II, and V lambda VII genes. Although different VL genes can be used, unrelated individuals appear to use the same V kappa III (A27), V lambda II (V lambda 2.1 and V lambda VII (4A) genes. The VL diversity accounts for differences in fine binding specificity, with A2-V kappa II genes not encoding E. coli K100 CP cross-reactive antibodies and V lambda VII genes and some of the non-A2 V kappa genes encoding cross-reactive antibodies. The arginine in CDR3 of both antibody kappa and lambda light chains and the asparagine in CDR2 of VL sequences and in CDR1 of LSG6.1-M85 VH sequences of antibody appear to be important residues for antigen binding. A relatively limited degree of somatic mutation has occurred in the non-A2 VL genes, V lambda VII, and the VH genes. Further studies comparing the polymorphism of germline V genes to antibody-encoding V genes are needed to clarify this issue. Research comparing this repertoire to repertoires directed to other bacterial CP and to self antigens and defining structure-antigen binding relationships is in progress.     

Preferential VH/V lambda pairings occur in the available B cell repertoire of adult BALB/c mice.

To gain insights into the composition of the B cell repertoire, we have investigated VH gene family expression associated with individual light chains. For this purpose, we have examined the use of 12 VH gene families in a large collection of hybridomas expressing one of the four lambda light chains [lambda 1 (V1J1), lambda 2 (V2J2 and V x J2) and lambda 3 (V1J3)]. Our results show that the distribution of the VH families is very different from one lambda subtype to another. This suggests that a few substitutions between VL regions are sufficient to generate very different associated repertoires by strong selection mechanisms. Moreover, we assume that the global VH expression pattern is not random but rather composed of many preferential VH/VL associations.     

V genes of the primary antibody response of C57BL/10 mice to the hapten phenyloxazolone

The mRNA of ten monoclonal phenyloxazolone (phOx) antibodies originating from the primary (day 7) response of C57BL/10 mice were partially sequenced. The sequences were analyzed together with those of two previously published antibodies. The C57BL response does not have a predominant subset of antibodies like the BALB/c response has (VH-Ox1/V kappa-Ox1 JK5). Probably, C57BL mice lack the VH-Ox1 gene and, as a consequence, their V kappa-Ox1 gene does not have a main role in the anti-phOx response. Five V kappa and six VH genes were found to participate. All five V kappa genes or their "alleles" had previously been found from the BALB/c response to 2-phenyloxazolone (phOx). On the other hand, the two strains use different VH genes for the anti-phOx response. Most C57BL antibodies were coded by VH genes of group 1 which has only minor role in the BALB/c response. The remaining VH genes were from group 7. Our data show that one V kappa segment (e.g. V kappa-Ox1) can code for anti-phOx antibodies with several, even widely different, VH genes. On the other hand, they emphasize the role of certain VH/VL gene combinations for the anti-phOx specificity. Thus, VH genes of group 7 were found to code for anti-phOx antibodies only together with the V kappa 45.1 gene.     

Complete sequence of the genes encoding the VH and VL regions of low- and high-affinity monoclonal IgM and IgA1 rheumatoid factors produced by CD5+ B cells from a rheumatoid arthritis patient.

We have characterized the VH and VL genes of three low-affinity polyreactive and two high-affinity monoreactive IgM and IgA1 rheumatoid factor (RF) mAb generated using circulating CD5+ B cells from a single rheumatoid arthritis patient. We found that four and one RF mAb utilized genes of the VHIV and VHIII families, respectively. The VHIV gene usage by these RF mAb differs from the preferential VHIII, VHI, and, to a lesser extent, VHII gene usage by the IgM with RF activity found in patients with mixed cryoglobulinemia, Waldenstrom's macroglobulinemia, and other monoclonal gammopathies. In addition, in contrast to the preponderant kappa L chain usage by the RF in these patients, a lambda L chain was utilized by all RF mAb from our rheumatoid arthritis patient. Two RF mAbs utilized V lambda I, two V lambda IV, and one V lambda III L chains. The VH genes of the two low-affinity polyreactive IgM RF mAb were in germline configuration. When compared with the deduced amino acid sequence of the putatively corresponding genomic segment, the VH gene of the high-affinity monoreactive IgM RF mAb displayed five amino acid differences, all of which are in the complementarity determining regions (CDR), possibly the result of a process of somatic point mutation and clonal selection driven by Ag. The unavailability of the corresponding genomic VH segment sequences made it impossible to infer whether the VH genes utilized by the two IgA1 RF were in a germline or somatically mutated configuration. Sequencing of the genes encoding the H chain CDR3 (D segments) revealed that all three low-affinity polyreactive RF mAb displayed a much longer D segment (36-45 bases) than their high-affinity monoreactive counterparts (15-24 bases), raising the possibility that a long D segment may be one of the factors involved in antibody polyreactivity.     

Repertoire of human antibodies against the polysaccharide capsule of Streptococcus pneumoniae serotype 6B

We examined the repertoire of antibodies to Streptococcus pneumoniae 6B capsular polysaccharide induced with the conventional polysaccharide vaccine in adults at the molecular level two ways. In the first, we purified from the sera of seven vaccinees antipneumococcal antibodies and determined their amino acid sequences. Their VH regions are mainly the products of VH3 family genes (candidate genes, 3-23, 3-07, 3-66, and 3-74), but the product of a VH1 family gene (candidate gene, 1-03) is occasionally used. All seven individuals have small amounts of polyclonal kappa+ antibodies (Vkappa1 to Vkappa4 families), although kappa+ antibodies are occasionally dominated by antibodies formed with the product of the A27 Vkappa gene. In contrast, lambda+ anti-6B antibodies are dominated by the antibodies derived from one of 3 very similar Vlambda2 family genes (candidate genes, 2c, 2e, and 2a2) and Clambda1 gene product. The Vlambda2(+) antibodies express the 8.12 idiotype, which is expressed on anti-double-stranded-DNA antibodies. In one case, Vlambda is derived from a rarely expressed Vlambda gene, 10a. In the second approach, we studied a human hybridoma (Dob1) producing anti-6B antibody. Its VH region sequence is closely related to those of the 3-15 VH gene (88% nucleotide homology) and JH4 (92% homology). Its VL region is homologous to the 2a2 Vlambda2 gene (91%) and Jlambda1/Clambda1. Taken together, the V region of human anti-6B antibodies is commonly formed by a VH3 and a Vlambda2 family gene product.     

Structural polymorphism of V kappa 21 E and V kappa 21 D gene products in laboratory mice

The aim of the present work was to study structural polymorphism of V kappa genes products. To this end we isolated immunoglobulins expressing the V kappa 21 D and V kappa 21 E gene products from the normal sera of several inbred strains of mice using a monoclonal antibody that selectively recognizes V kappa 21 D and V kappa 21 E subgroups. Analysis of the isoelectric focusing pattern of the light chain of these immunoglobulins revealed the existence of 3 clearly different phenotypes. The first one is shared by most inbred strains of mice, the second one is expressed by C58/J, AKR and PL/J and the third one defines V kappa 21 D-E light chains of SJL and SJA mice. Genetic analysis revealed that the locus controlling V kappa 21 D-E chain structure is closely linked to the Ly2-3 and to the Ig Kappa-Ef1 loci. Finally, using recombinant mouse strains, we could also order V kappa 21 D-E genes with respect to the known loci affecting V kappa polymorphism. Taken together our data argue against the possibility that the polymorphism observed results from strain-specific expression of V kappa genes common to all mice, but rather suggest that different allelic form of the same V kappa gene subgroup exist in different strains.     

Biphenotypic plasma cell myeloma: two cases of plasma cell neoplasm with a coexpression of kappa and lambda light chains

Plasma cell neoplasm (PCM) is a medullary and extra medullary proliferation of clonal plasma cells that occurs due to accidental translocation of proto-oncogenes into immunoglobulin (Ig) gene loci. While the majority of plasma cell neoplasms are monoclonal, up to 2% of the PCMs [1] considered being biclonal based on electrophoretic analysis, characterized by secretion of paraprotein with two distinct heavy chains or light chains are possible and present unique diagnostic challenges. Methods: Traditionally protein electrophoresis has been used to diagnose, characterize, and monitor progression of plasma cell neoplasm. To characterize neoplastic plasma cells, in our institution, other ancillary studies, including in situ hybridization, flow cytometric analyses of plasma cell surface markers and cytoplasmic immunoglobulins with DNA ploidy, are also utilized routinely. Results: We present two cases of plasma cell myeloma in which the neoplastic plasma cells shows production of cytoplasmic kappa and lambda light chain, with secretion of free lambda light chain only. Co-expression of kappa and lambda light chain by the same neoplastic plasma cells is a rare but reported phenomenon. Conclusions: Our study indicates that serum electrophoresis alone could mischaracterize biphenotypic myeloma as monotypic plasma cell myelomas in the absence of additional testing methods.     

Characterization of a human monoclonal autoantibody directed to cardiolipin/beta 2 glycoprotein I produced by chronic lymphocytic leukaemia B cells.

We determined the specificity and sequence of immunoglobulin molecules synthesized by monoclonal B cells from a patient with chronic lymphocytic leukaemia (CLL) who presented with a number of clinical and biological autoimmune symptoms. Heterohybrids obtained by fusion of CLL cells with the mouse X63-Ag 8.653 myeloma produced IgM lambda MoAbs directed to the cardiolipin/beta 2 glycoprotein I (beta 2GPI) complex and ssDNA. They were devoid of polyreactivity. Nucleotide sequence analysis of the variable domain of the mu chain indicated the utilization of the VH4 71.2 gene or one allotypic variant, DXP4 and JH3 segments. The lambda light chain used the single gene from the V lambda 8 subfamily, J lambda 3 and C lambda 3 genes. The VH gene displayed 11 nucleotide changes in comparison with its putative germline counterpart. However, these nucleotide changes correspond to variations observed in other published VH4 sequences, suggesting gene polymorphism rather than somatic mutation. DXP4 and JH3 were also in germline configuration. The VL gene exhibited a single replacement mutation in CDR1. These data suggest that the monoclonal CLL B cells in this patient retained VH and VL genes in germline configuration although they secreted a pathogenic anti-cardiolipin antibody associated with clinical symptoms, vasculitis and thrombosis, which may be provoked by antibodies to the phospholipid/beta 2GPI complex.     

The V-region repertoire of Haemophilus influenzae type b polysaccharide antibodies induced by immunization of infants.

Haemophilus influenzae type b (Hib) is a significant pathogen for young children, and three Hib vaccines (named PRP-OMPC, HbOC, and PRP-T) are currently available for young children. Extensive studies of anti-Hib polysaccharide (PS) antibodies (Abs) have shown that the V regions of Abs against the Hib PS comprise a VH gene in the VH3 gene family and a VL gene from various K kappa and V lambda subgroups. To study immunogenic properties of the three vaccines in young children, we determined the VL subgroups and avidities of anti-Hib-PS Abs induced by the three clinically available conjugate vaccines. Ab avidity was measured by determining the concentration of a Hib-PS oligomer that abrogates half of the binding of immunoglobulin G anti-Hib-PS Abs to microwells. The PRP-OMPC vaccine induced lower-avidity Abs than the prelicensure HbOC vaccine (P = 0.05). When we compared anti-Hib-PS Abs expressing V kappa Ia, V kappa II, and V lambda subgroups, a greater Ab response was induced by the prelicensure HbOC vaccine than other vaccines (P < 0.05). When anti-Hib-PS Abs with the V kappa III subgroup were compared, however, both PRP-T and prelicensure HbOC vaccines induced a comparable response, which in turn was greater than those induced by the PRP-OMPC or the postlicensure HbOC vaccine (P < 0.001). The VL repertoire of Abs induced with the prelicensure HbOC or PRP-T vaccine in young children is dominated (about 80%) by anti-Hib-PS Abs using subgroup V kappa II. However, anti-Hib-PS using V kappa II VL accounts for only about 40% of the total anti-Hib-PS Abs induced with the PRP-OMPC vaccine or the postlicensure HbOC. Our data suggest that immunogenic properties of Hib vaccines in young children vary depending on the vaccine preparations as well as the vaccine types.     

Crosslinking of the cell surface immunoglobulin (mu-surrogate light chains complex) on pre-B cells induces activation of V gene rearrangements at the immunoglobulin kappa locus.

We constructed an expression vector encoding a truncated Ig mu chain that lacks both VH and CH1 domains (mu delta m chain) and introduced the mu delta m vector into the Ig negative Abelson pre-B cell line P17-27. The transfectants expressed a large amount of the mu delta m chain on their surface, which was not complexed with the lambda 5 and VpreB surrogate light chain molecules. While P17-27 transfected with a vector for the intact micron chain (P17-27 micron) shows V kappa rearrangements in culture, V kappa rearrangements were not detected in P17-27 mu delta m cells. When the mu delta m chains on the cell surface were crosslinked by anti-mu antibodies, V kappa gene rearrangements were induced in P17-27 mu delta m. These results strongly suggest that crosslinking of the micron-lambda 5-VpreB complex on the pre-B cell surface generates a signal that activates V kappa gene rearrangement, and that the lambda 5 and VpreB molecules are necessary for the spontaneous crosslinking of surface Ig on pre-B cells.     

Restricted usage of VH and V kappa genes by murine monoclonal antibodies against 3-fucosyllactosamine

We are studying the structure and regulation of murine antibodies against the 3-fucosyllactosamine antigenic determinant. Analysis of the sequences of seven BALB/c IgM, kappa monoclonal antibodies (mAb), obtained from four fusions, indicates that these antibodies exhibit restriction in their usage of VH and VL genes. Based on a combination of mRNA sequences and Southern filter hybridization data, all seven light chains are encoded by V kappa 24B and J kappa 1 gene segments. Complete mRNA sequences of the heavy chains revealed that all seven mAb are encoded by VH441, six antibodies are encoded by JH4 and one uses a JH3 gene segment. The VH441 gene segment and all seven mAb contain a potential glycosylation site at Asn 58 in complementarity-determining region (CDR)2. In contrast to the similarity of the VH regions, the heavy chain CDR3 segments exhibit considerable heterogeneity. They are encoded by three D segments, they vary in length from 7-9 amino acids and display differences in their deduced amino acid sequences. The VH441 gene segment also encodes antibodies against four other carbohydrate antigens, levan, galactan, dextran and galactosyl globoside. The use of a single gene segment to encode antibodies against five different antigens suggests that the domain encoded by VH441 might be particularly well adapted for forming sites that bind carbohydrate determinants. Glycosylation of CDR2 might contribute to the unique properties of this VH domain.     

A rearranged lambda 2 light gene chain retards but does not exclude kappa and lambda 1 expression

Mice transgenic for the lambda 2 light chain of MOPC315 were established. In newborn transgenics (TG), lambda 2 was the only light chain found on B cells. However, by day 21, lambda 2 high kappa low as well as lambda 2 low kappa high double expresser populations were emerging. lambda 2 was found on an increased fraction of serum immunoglobulins (Ig), this fraction declined with age. Correspondingly, kappa and lambda 1 expression was suppressed in young mice but increased with age. In adult mice kappa or lambda 1 were often co-expressed with lambda 2 in single serum Ig molecules. Most B cell hybridomas from and adult TG secreted lambda 2,kappa mixed molecules and had rearranged their kappa chain genes. One lambda 2,lambda 1 hybridoma and even a lambda 2,kappa,lambda 1 hybridoma were also found. In conclusion, isotypic exclusion in lambda 2 TG is complete in newborns but becomes increasingly leaky with age. Antigen probably expands the lambda 2 low kappa high B cell population; this population is most likely the major source of serum Ig in adult lambda 2 TG mice. In contrast, the lambda 2 high kappa low population, a major fraction of which is CD5+ Mu low delta low, appears only infrequently to develop into antibody-secreting plasma cells.     

V genes of oxazolone antibodies in 10 strains of mice

One pair of V genes (V kappa 45.1 and V11) code for a great portion of phenyloxazolone (anti-phOx) antibodies in 10 strains of mice. This combination replaces the first-known major combination VHOx1-V kappa Ox1 in some strains, and is important in most strains. C57BL/10 and SJL mice have an additional subset of antibodies encoded by genes V kappa 45.1 and V13 (a relative of V11). All three genes involved (V kappa 45.1, V11 and V13) have "allelic" variation. Four alleles of V11 were found, one in Igh haplotypes a, c and g, the second in haplotypes d, j and n, the third in b, and the fourth in f. The most distant alleles d, j, n and f had 10 nucleotide differences out of 429 determined (97.7% homology). Only one allele of the V13 gene was found from anti-phOx hybridomas but two others have been published. Three alleles of the V kappa 45.1 gene were found; one in NZB mice (Ig kappa haplotype b) another in CE (haplotype f), and the third in eight strains including representatives of three Ig kappa haplotypes (a, c and e). The three alleles had greater than 99.0% homology. The V11 and V13 genes that code for anti-phOx antibodies in C57BL/10 and SJL mice were different from the related genes found from the C57BL/10 germ line. C57BL/10 mice must have a chromosome bearing two V11 and two V13 genes. RF mice were found to have two V11 genes, and both code for anti-phOx antibodies. Our data show that the majority of antibodies in the anti-phOx response are encoded by the same restricted collection of V genes in most mouse strains. Antibody responses appear to be no less heritable than other functions of the body.     

Variable region sequences and idiotypic expression of a protective human immunoglobulin M antibody to capsular polysaccharides of Neisseria meningitidis group B and Escherichia coli K1.

We determined the heavy (H)- and light (L)-chain variable (V) region nucleotide and translated amino acid sequences of the human immunoglobulin M(kappa) monoclonal antibody (MAb) 5E1, which is specific for the polysaccharide capsule of Escherichia coli K1 and Neisseria meningitidis group B (poly[alpha(2-->8)-N-acetylneuraminic acid]) and which is protective in animal models of infection. The 5E1 VH gene is a member of the VHIIIb family and is 97% homologous to the 9.1 germ line gene. The 5E1 VL gene is a member of the kappa I subgroup and is 98% homologous to the germ line gene, 15A, also known as KLO12. The VL and/or VH genes used by 5E1 are highly homologous to the V genes encoding antibodies to the Haemophilus influenzae type b polysaccharide and to antibodies reactive with self-antigens such as erythrocyte "i," DNA, and thyroid peroxidase. We also produced three murine anti-idiotype (Id) MAbs against 5E1. All three anti-Ids recognize a minor subset of antimeningococcal B polysaccharide antibodies present in serum from normal adults. Two of the anti-Ids define distinct Ids associated with antibodies having kappa I-15A V regions. These 15A-associated Ids are expressed by some heterologous human antimeningococcal B polysaccharide MAbs, and they also are independently expressed by two human MAbs that are specific for either the H. influenzae b polysaccharide or the i erythrocyte antigen and that utilize the kappa I-15A V region. Taken together, these data indicate that the 5E1 antibody uses V regions that recur in the human antibody repertoires to this polysaccharide and to structurally dissimilar polysaccharides and autoantigens. Thus, the poor immunogenicity of poly[alpha(2-->8)-N-acetylneuraminic acid] cannot be explained by the unavailability of certain critical VH and VL genes required for generation of antibody response.     

Repertoire of murine lambda-positive variable domains: polyclonal induction of lambda isotypes and their associated pattern of antibody specificities

The diversity of lambda variable (V lambda) domains is extremely restricted when compared to those of VH and V kappa. In addition, each V lambda domain is determined by the C lambda domain. For these reasons, the lambda system is an excellent model for the study of the associated VH region repertoire. The study of V lambda domain diversity has been limited by the small contribution (approximately 5%) of lambda-bearing proteins to the total Ig pool. We now show that treatment of BALB/c mice with rabbit anti-lambda 1 antibodies coupled to lipopolysaccharide induces a production of polyclonal lambda 1 light chain-bearing Ig whereas, conversely, treatment with rabbit anti-lambda 2 antibodies induces a production of polyclonal lambda 2 + lambda 3 light chain-bearing Ig. The antigenic specificities of these two distinct lambda populations were then studied using B1355 dextran, (4-hydroxy-3-nitrophenyl)acetyl (NP) and 2,4-dinitrophenyl (DNP) as antigens. The anti-alpha(1-3)dextran antibody specificity was found to be mediated exclusively by antibodies bearing the lambda 1 isotype whereas the anti-NP and anti-DNP antibody specificities are mediated by both the lambda 1 and lambda 2 + lambda 3 isotypes. In addition, various mouse strains with the VHa or VHb allotypic haplotype and the rlo lambda 1 or r+ lambda 1 phenotype were treated with rabbit anti-lambda 1 antibodies. The lambda 1 anti-NP and anti-DNP antibody specificities were similar in all strains whereas the lambda 1 anti-alpha(1-3)dextran specificity was linked to the presence of the VHa allotypic haplotype. The mouse strains with the rlo lambda 1 or r+ lambda 1 phenotype did not differ in terms of their patterns of lambda 1 antibody specificities.