Cell-type preference of immunoglobulin kappa and lambda gene promoters.

Immunoglobulin gene constant regions are known to be associated with strictly tissue-specific enhancer elements. Until recently the promoter of the variable region, which becomes linked to the constant region by somatic rearrangement, could have been viewed as a passive recipient of the enhancer stimulus. Here we show that the promoters of the immunoglobulin kappa and lambda light chain genes are approximately 20-30 times more active in lymphoid cells than in non-lymphoid cells. To avoid the problem of differential mRNA stability upon transfection of immunoglobulin genes into non-lymphoid cells we have constructed chimeric genes. All kappa mRNA sequences were progressively deleted to fuse the kappa gene promoter to a globin gene coding body. A similar chimeric gene was constructed with the promoter of the lambda gene. The cell-type preference of the promoter may be exploited during B-lymphocyte differentiation to regulate the immunoglobulin gene promoter independently from the enhancer.     

Comparing domain interactions within antibody Fabs with kappa and lambda light chains

IgG antibodies are multi-domain proteins with complex inter-domain interactions. Human IgG heavy chains (HCs) associate with light chains (LCs) of the κ or λ isotype to form mature antibodies capable of binding antigen. The HC/LC interaction involves 4 domains: VH and CH1 from the HC and VL and CL from the LC. Human Fabs with κ LCs have been well characterized for their unfolding behaviors and demonstrate a significant level of cooperativity and stabilization when all 4 domains are intact. Very little is known regarding the thermodynamic properties of human Fabs with λ LCs. Here, we dissect the domain contributions to Fab stability for both κ and λ LC-containing Fabs. We find the cooperativity of unfolding between the constant domains, CH1/Cλ, and variable domains, VH/Vλ, within λ LC-containing Fabs is significantly weaker than that of κ LC-containing Fabs. The data suggests there may not be an evolutionary necessity for strong variable/constant domain cooperativity within λ LC-containing Fabs. After investigating the biophysical properties of Fabs with mismatched variable and constant domain subunits (e.g., VH/Vκ paired with CH1/Cλ or T cell receptor Cα/Cβ), the major role of the constant domains for both κ- and λ-containing Fabs may be to reduce the hydrophobic exposure at the VH/VL interface. Even though Fabs with these non-native pairings were thermodynamically less stable, they secreted well from mammalian cells as well behaved monodisperse proteins, which was in contrast to what was observed with the VH/Vκ and VH/Vλ scFvs that secreted as a mixture of monomer and aggregates.     

Production of antigen-specific human monoclonal antibodies: comparison of mice carrying IgH/kappa or IgH/kappa/lambda transloci

Here we compare human monoclonal antibody (MAb) production from mouse strains that carry disruptions of their endogenous mouse IgH/IgK loci and harbor human IgM + Igkappa(BABkappa) or human IgM + Igkappa + IgA transloci (BABkappa,lambda). We found that whereas both strains proved effective for the isolation of antigen-specific IgM antibodies, many of the IgM MAbs elicited from BABkappa comprise human mu chains that are associated with mouse lambda chains. In contrast, BABkappa,lambda mice gave rise to fully functional, polymeric human IgM antibodies comprising both human IgH and human IgL chains. Therefore, the inclusion of a human Iglambda translocus (in addition to the human IgH + Igkappa transloci) not only diminishes problems of endogenous mouse Iglambda expression but also provides a strain of mice that yields fully human MAbs to a wide range of antigens, as witnessed by the isolation of MAbs to human blood cells, tumor cell lines, and an immunoglobulin idiotype.     

Gene targeting in the Ig kappa locus: efficient generation of lambda chain-expressing B cells, independent of gene rearrangements in Ig kappa.

The production of lambda chain-expressing B cells was studied in mice in which either the gene encoding the constant region of the kappa chain (C kappa) or the intron enhancer in the Ig kappa locus was inactivated by insertion of a neomycin resistance gene. The two mutants have similar phenotypes: in heterozygous mutant mice the fraction of lambda chain-bearing B cells is twice that in the wildtype. Homozygous mutants produce approximately 7 times more lambda-expressing B cells (and about 2.3 times fewer total B cells) in the bone marrow than their normal counterparts, suggesting that B cell progenitors can differentiate into either kappa- or lambda-producing cells and do the latter in the mutants. Whereas gene rearrangements in the Ig kappa locus are blocked in the case of enhancer inactivation, they still occur in that of the C kappa mutant, although in this mutant RS rearrangement is lower than in the wildtype. This indicates that gene rearrangements in the Ig lambda locus can occur in the absence of a putative positive signal resulting from gene rearrangements in Ig kappa, including RS recombination. Complementing these results, we also present data indicating that in normal B cell development kappa chain rearrangement can be preceded by lambda chain rearrangement and that the frequency of kappa/lambda double producers is small and insufficient to explain the massive production of lambda chain-expressing B cells in the mutants.     

Autoantibody-encoding kappa L chain genes frequently rearranged in lambda L chain-expressing chronic lymphocytic leukemia

Patients with kappa L chain expressing chronic lymphocytic leukemia (CLL) frequently have leukemia cells reactive with a murine mAb, designated 17.109. Raised against a monoclonal IgM rheumatoid factor autoantibody, this mAb recognizes a major kappa-L chain-associated cross reactive Id, designated 17.109-CRI. Molecular studies reveal that the 17.109-CRI in CLL is a serologic marker for expression of a conserved kappa L chain V region gene (V Kappa gene) of the V Kappa 3 subgroup, designated Humkv325. We isolated an upstream gene fragment of Humkv325 to examine for Ig gene rearrangements of this and other closely related V Kappa 3 genes by Southern analyses. Consistent with Humkv325 encoding the 17.109-CRI, we find that the genomic DNA from all 17.109-reactive leukemia cell populations have gene rearrangements that are detected using this probe. In addition, we observe V Kappa 3 gene rearrangements frequently in the genomic DNA of lambda L chain-expressing leukemia cells. Of the genomic DNA from 33 lambda-L chain-expressing CLL samples, 8 (24%) had additional nongerm-line bands detected with the Humkv325 probe. Consistent with these bands representing Ig gene rearrangements, the additional band in each but one sample also hybridized with probes specific for the J Kappa region and/or the kappa-deleting element. Using the polymerase chain reaction (PCR), we examined the genomic DNA from all lambda L chain-expressing CLL for V Kappa 3 gene rearrangements to J Kappa and/or Kde. PCR on each DNA sample with V Kappa 3 gene rearrangements detected by Southern analysis generated gene fragments that hybridized specifically with oligonucleotides corresponding to framework or CDR of the Humkv325 gene. Nucleic acid sequence analyses of representative samples confirmed that these DNA contained abortive Humkv325 gene rearrangements. PCR for rearranged V Kappa 3 genes in the DNA of other lambda-L chain-expressing CLL either did not generate any PCR product or produced fragments that failed to hybridize with all Humkv325 oligonucleotide probes. Nucleic acid sequence analyses of the latter demonstrated that these represent abortive V Kappa gene rearrangements involving another conserved V Kappa 3 gene, designated Vg. These studies indicate that Humkv325 and Vg frequently may undergo Ig gene rearrangement independent of their expression. As such, the frequent use of Humkv325 in CLL may be secondary, in part, to an enhanced propensity of this V Kappa 3 gene to undergo genetic rearrangement during B cell ontogeny.     

Three M components IgA lambda, + IgG kappa n + IgG kappa h in one patient. II. Structurally different kappa n and kappa h chains associated with H(gamma) chains sharing idiotypic determinants

Structural analysis of purified IgG kappa h and IgG kappa n molecules of DA myeloma paraproteins indicated that the two IgG had different electrophoretic mobility and that L-kappa h had an unusually heavy m.w. (30,000). Peptide mapping showed the existence of additional peptides in the L-kappa h map when compared to the L-kappa n map. Total amino acid analysis showed that L-kappa h contained two additional cysteine residues and certain other amino acids than L-kappa n contained. Sequence of the first 25 NH2-terminal amino acids showed differences at positions 4, 5, 15, 18, and 21, but both L-kappa h and L-kappa n belong to the same V kappa IV subgroup. IgG kappa n but not IgG kappa h reacted with anti-gamma 1 antiserum, indicating that H chains of these two paraproteins were also different. Sera from rabbits immunized with IgG kappa n or IgG kappa h, and rendered specific for idiotypic determinants by appropriate absorption, were used for idiotype characterization of these components. Immunodiffusion, immunoelectrophoresis, and direct hemagglutination demonstrated that IgG kappa h and IgG kappa n cross-reacted partially. Inhibition tests disclosed that the main anti-idiotypic antibody was directed against a conformation structure of the complete IgG kappa h molecule, whereas cross-reaction was due to partial idiotypic similarity between H chains of the IgG kappa h and IgG kappa n. In addition, each of these paraproteins seemed also to bear private idiotypes on their H and L chains.     

Existence of both kappa and lambda light chain messenger RNA sequences in mouse myeloma, MOPC-104E, known as a lambda chain producer.

A mouse myeloma, MOPC-104E, which is known to synthesize and secrete λ type light chain protein as a constituent of immunoglobulin M, was shown to contain mRNA sequences coding for κ as well as λ type light chain protein. Light chain mRNA sequences were quantitated by nucleic acid hybridization reaction using radioactive DNA complementary to light chain mRNAs which had been purified from other myelomas. The amount of κ type light chain mRNA present in MOPC-104E is almost equivalent to that of λ type light chain mRNA. κ chain mRNA was not separated from λ chain mRNA either by centrifugation in sucrose density gradient or by polyacrylamide gel electrophoresis in formamide.     

Deletion of the immunoglobulin kappa chain intron enhancer abolishes kappa chain gene rearrangement in cis but not lambda chain gene rearrangement in trans.

Immunoglobulins (Ig) secreted from a plasma cell contain either kappa or lambda light chains, but not both. This phenomenon is termed isotypic kappa-lambda exclusion. While kappa-producing cells have their lambda chain genes in germline configuration, in most lambda-producing cells the kappa chain genes are either non-productively rearranged or deleted. To investigate the molecular mechanism for isotypic kappa-lambda exclusion, in particular the role of the Ig kappa intron enhancer, we replaced this enhancer by a neomycin resistance (neoR) gene in embryonic stem (ES) cells. B cells heterozygous for the mutation undergo V kappa-J kappa recombination exclusively in the intact Ig kappa locus but not in the mutated Ig kappa locus. Homozygous mutant mice exhibited no rearrangements in their Ig kappa loci. However, splenic B cell numbers were only slightly reduced as compared with the wild-type, and all B cells expressed lambda chain bearing surface Ig. These findings demonstrate that rearrangement in the Ig kappa locus is not essential for lambda gene rearrangement. We also generated homozygous mutant mice in which the neoR gene was inserted at the 3' end of the Ig kappa intron enhancer. Unexpectedly, mere insertion of the neoR gene showed some suppressive effect on V kappa-J kappa recombination. However, the much more pronounced inhibition of V kappa-J kappa recombination by the replacement of the Ig kappa intron enhancer suggests that this enhancer is essential for V kappa-J kappa recombination.     

Genes encoding Xenopus laevis Ig L chains. Implications for the evolution of kappa and lambda chains.

Xenopus laevis Ig contain two distinct types of L chains, designated rho or L1 and sigma or L2. We have analyzed Xenopus genomic DNA by Southern blotting with cDNA probes specific for L1 V and C regions. Many fragments hybridized to the V probe, but only one or two fragments hybridized to the C probe. Corresponding C, J, and V gene segments were identified on clones isolated from a genomic library prepared from the same DNA. One clone contains a C gene segment separated from a J gene segment by an intron of 3.4 kb. The J and C gene segments are nearly identical in sequence to cDNA clones analyzed previously. The C segment is somewhat more similar and the J segment considerably more similar in sequence to the corresponding segments of mammalian kappa chains than to those of mammalian lambda chains. Upstream of the J segment is a typical recombination signal sequence with a spacer of 23 bp, as in J kappa. A second clone from the library contains four V gene segments, separated by 2.1 to 3.6 kb. Two of these, V1 and V3, have the expected structural and regulatory features of V genes, and are very similar in sequence to each other and to mammalian V kappa. A third gene segment, V2, resembles V1 and V3 in its coding region and nearby 5'-flanking region, but diverges in sequence 5' to position -95 with loss of the octamer promoter element. The fourth V-like segment is similar to the others at the 3'-end, but upstream of codon 64 bears no resemblance in sequence to any Ig V region. All four V segments have typical recombination signal sequences with 12-bp spacers at their 3'-ends, as in V kappa. Taken together, the data suggest that Xenopus L1 L chain genes are members of the kappa gene family.     

Three M-components IgA lambda + IgG kappa n + IgG kappa h in one patient (DA): lack of shared idiotypic determinants between IgA and IgG, and the presence of an unusual kappa h chain of 30,000 M.W

Two apparently homogeneous electrophoretic bands were found in the serum of a patient (DA) with multiple myeloma. These M-components were identified as IgA-lambda and IgG-kappa paraproteins bearing different idiotypic determinants. Further analysis of the L chains showed that the lambda-chain was homogeneous but the kappa-chain could be separated by SDS-polyacrylamide gel electrophoresis into two different bands. Both of them were associated with gamma-chains but one (termed kappa n) had normal m.w. (24,500) whereas the other (termed kappa h) was larger (m.w. 30,000). Sugar content of the two DA IgG, as determined by anthrone reaction, was similar in DA IgG kappa n (0.73%) and in DA IgG kappa h (1.1%), clearly demonstrating that the difference in m.w. was not due to a large sugar chain. Furthermore, the peptide map of the kappa h chain included nine peptides absent in those of four other control kappa-chains. Sequence analysis showed that the first 25 N-terminal amino acids of the kappa n differed from those of the kappa h chain at positions 4, 5, 15, 18, and 21. Thus the two kappa-chains had different framework regions.     

Untranslated immunoglobulin kappa light chain mRNA in a lambda light chain-producing mouse myeloma, MOPC104E

Fourteen clones were isolated in culture from a mouse myeloma, MOPC104E. All clones had kappa and lambda types of light chain mRNAs in approximately equimolar quantity as assayed by hybridization with specific complementary DNA (cDNA). However, the myeloma produces and secretes only lambda-type light chain protein. Both kappa- and lambda-type mRNAs in these clones were indistinguishable from kappa- and lambda-type mRNAs of other myelomas with respect to (a) adsorption to oligo-(dT) cellulose, (b) molecular size (12.6 S), and (c) thermal stability of the hybrids formed with corresponding cDNA. The kappa chain mRNA of MOPC104E cells, however, was translated very inefficiently both in vivo and in vitro, whereas the lambda chain mRNA was translated efficiently. These results indicate that each cell of MOPC104E myeloma synthesizes a crippled kappa chain mRNA in addition to a normal lambda chain mRNA.     

A characterization of the BALB/c lambda and kappa class antibodies to alpha (1,3) glycosidic linkages

The avidity relationships of kappa and lambda antibodies with specificity for the glucosyl-alpha (1,3)-glucose disaccharide epitope were compared using a solid-phase hapten inhibition assay. The kappa class antibodies, induced by the T-cell-dependent antigen, nigerosyl-keyhole limpet hemocyanin (N-KLH), and the lambda class antibodies, induced by the T-cell-independent antigen, Dextran B1355, were only marginally distinguishable (approximately equal to 10-fold) on the basis of hapten inhibition using the free disaccharide, nigerose, as inhibitor. Analysis of the binding site sizes of antibodies induced by N-KLH through inhibition with oligosaccharides of different sizes showed that the disaccharide protein antigen did not select for antibodies with smaller binding site sizes. The cellular basis for these findings is discussed.     

A coliphage lambda vector with enhanced biological containment: lambda gtALO.lambda B.

The biological containment of the lambda gt family of cloning vectors has been enhanced by conditionally blocking DNA replication as well as head and tail morphogenesis. The vector, lambda gtALO.lambda B, was constructed by crossing the Oam29, Aama1 and Lam439 mutations into lambda gt.lambda B. The mutation blocking phage DNA replication, Oam29, is suppressed by suII+ or suIII+. The head gene mutation, Aama1, is suppressed by suIII+ but not by suII+ and the tail gene mutation, Lam439, is suppressed by suII+ but not by suIII+. This allows the option of increasing the biological containment by producing heads when a large amount of cloned DNA is being prepared from an individual isolate. A model recombinant, lambda gt Aama1 Lam439 Oam29.KmR' (lambda gtALO.KmR') was constructed and the containment of the vector was evaluated by the series of standardized experiments required for EK2 certification.