Generation of the primary antibody repertoire in rabbits: expression of a diverse set of Igk-V genes may compensate for limited combinatorial diversity at the heavy chain locus

 In mouse and human, generation of combinatorial diversity through use of different heavy and light chain variable region genes in immunoglobulin rearrangements can be a major contributor to the primary antibody repertoire. In rabbits, the contribution of the combinatorial mechanism to heavy chain diversity is minimal, as only a few Igh-V genes are rearranged and expressed. To investigate the contribution of combinatorial diversity toward generation of the rabbit V_κ repertoire, we constructed five genomic libraries from rabbit kidney DNA and 1 cDNA library from the bone marrow of a 1-day-old rabbit using a series of polymerase chain reaction-based strategies. Our analyses indicate that most of the sequences that we recovered from our libraries belong to a single family and some are extremely similar. The actual number of germline Igk-V genes is potentially greater than our conservative estimate of at least 39, 28 of which we found expressed as mRNA. The germline Igk-V genes display different lengths of the coding region 3′ of Cys 88 ranging from 7 to 12 amino acids, resulting in CDR3 length heterogeneity among functional V_κJ_κ sequences ranging from 8 to 15 amino acids. Some of the V_κJ_κ junctions had N and P nucleotide additions. Thus, in contrast to limited combinatorial diversity of its heavy chain, the rabbit can draw upon a diverse set of germline Igk-V genes. The κ light chain has the potential to be a major contributor toward generation of the antibody specificities of the rabbit pre-immune repertoire. Received: 14 April 1999 / Revised: 8 June 1999     

Evolutionary relationship between human and mouse immunoglobulin kappa light chain variable region genes

Similar to the Igh-V multigene family, the human or mouse Igk-V repertoirer is a distorted continuum of homologous genes that may be grouped into families displaying >80% nucleic acid sequence similarity among their members. systematic interspecies sequence comparisons reveal that most human Igk-V gene families exhibit clear homology to mouse Ogk-V families (sequence similarity >74%). A hypothetical phylogenetic tree of Igk-V genes predicts that a minimum of seven Igk-V genes/families predate mammalian radiation. In two cases, several interrelated mouse Igk-V families exhibit phylogenetic equidistance with just one human Igk-V family, implying a more pronounced divergence for the elevated number of Igk-V gene families in the mouse. Mouse-human Igk-V comaprisons, moreover, illustrate how expansion, contraction, and perhaps deletion of Igk-V gene families shape the Igk-V repertoire during mammalian evolution.     

Camelid Ig V genes reveal significant human homology not seen in therapeutic target genes,providing for a powerful therapeutic antibody platform

Camelid immunoglobulin variable (IGV) regions were found homologous to their human counterparts; however, the germline V repertoires of camelid heavy and light chains are still incomplete and their therapeutic potential is only beginning to be appreciated. We therefore leveraged the publicly available HTG and WGS databases of Lama pacos and Camelus ferus to retrieve the germline repertoire of V genes using human IGV genes as reference. In addition, we amplified IGKV and IGLV genes to uncover the V germline repertoire of Lama glama and sequenced BAC clones covering part of the Lama pacos IGK and IGL loci. Our in silico analysis showed that camelid counterparts of all human IGKV and IGLV families and most IGHV families could be identified, based on canonical structure and sequence homology. Interestingly, this sequence homology seemed largely restricted to the Ig V genes and was far less apparent in other genes: 6 therapeutically relevant target genes differed significantly from their human orthologs. This contributed to efficient immunization of llamas with the human proteins CD70, MET, interleukin (IL)-1β and IL-6, resulting in large panels of functional antibodies. The in silico predicted human-homologous canonical folds of camelid-derived antibodies were confirmed by X-ray crystallography solving the structure of 2 selected camelid anti-CD70 and anti-MET antibodies. These antibodies showed identical fold combinations as found in the corresponding human germline V families, yielding binding site structures closely similar to those occurring in human antibodies. In conclusion, our results indicate that active immunization of camelids can be a powerful therapeutic antibody platform.     

A yeast artificial chromosome contig spanning the mouse immunoglobulin kappa light chain locus

 A single contig spanning the entire mouse immunoglobulin kappa light chain (Igk) locus on chromosome 6 has been established using yeast and bacterial artificial chromosome clones. Detailed mapping of the Igk locus indicates that a member of the Igk-V2 gene family, located about 3.5 megabases upstream of the Igk-J-C complex, is the most distal functional Igk-V gene. Sequence analyses of Igk-V genes and anonymous DNA segments provide indications for internal duplications at the 5′ end of the Igk-V locus and identify the likely origin of Igk-V orphon gene clusters located elsewhere in the mouse genome. Received: 17 July 1996 / Revised: 2 September 1996     

Vκ polymorphisms in NOD mice are spread throughout the entire immunoglobulin kappa locus and are shared by other autoimmune strains

The diversity of immunoglobulin (Ig) and T cell receptor (TCR) genes available to form the lymphocyte repertoire has the capacity to produce a broad array of both protective and harmful specificities. In type 1 diabetes (T1D), the presence of antibodies to insulin and other islet antigens predicts disease development in both mice and humans, and demonstrate that immune tolerance is lost early in the disease process. Anti-insulin T cells isolated from T1D-prone non-obese diabetic (NOD) mice use polymorphic TCRα chains, suggesting that the available T cell repertoire is altered in these autoimmune mice. To probe whether insulin-binding B cells also possess polymorphic V genes, Ig light chains were isolated and sequenced from NOD mice that harbor an Ig heavy chain transgene. Three insulin-binding Vκ genes were identified, all of which were polymorphic to the closest germline sequence matches present in the GenBank database. Additional analysis of over 300 light chain sequences from multiple sources, including germline DNA, shows that polymorphisms are spread throughout the entire NOD Igκ locus, as these polymorphic sequences represent 43 distinct Vκ genes which belong to 14 Vκ families. Database searches reveal that a majority of polymorphic Vκ genes identified in NOD are identical to Vκ genes isolated from SLE-prone NZBxNZW F1 or MRL strains of mice, suggesting that a shared Igκ haplotype may be present. Predicted amino acid changes preferentially occur in CDR, and thus could alter antigen recognition by the germline B cell repertoire of autoimmune versus non-autoimmune mouse strains.     

The mouse antibody heavy chain repertoire is germline-focused and highly variable between inbred strains

The human and mouse antibody repertoires are formed by identical processes, but like all small animals, mice only have sufficient lymphocytes to express a small part of the potential antibody repertoire. In this study, we determined how the heavy chain repertoires of two mouse strains are generated. Analysis of IgM- and IgG-associated VDJ rearrangements generated by high-throughput sequencing confirmed the presence of 99 functional immunoglobulin heavy chain variable (IGHV) genes in the C57BL/6 genome, and inferred the presence of 164 IGHV genes in the BALB/c genome. Remarkably, only five IGHV sequences were common to both strains. Compared with humans, little N nucleotide addition was seen in the junctions of mouse VDJ genes. Germline human IgG-associated IGHV genes are rare, but many murine IgG-associated IGHV genes were unmutated. Together these results suggest that the expressed mouse repertoire is more germline-focused than the human repertoire. The apparently divergent germline repertoires of the mouse strains are discussed with reference to reports that inbred mouse strains carry blocks of genes derived from each of the three subspecies of the house mouse. We hypothesize that the germline genes of BALB/c and C57BL/6 mice may originally have evolved to generate distinct germline-focused antibody repertoires in the different mouse subspecies.     

Convergent mechanisms favor fast amyloid formation in two lambda 6a Ig light chain mutants

Extracellular deposition as amyloids of immunoglobulin light chains causes light chain amyloidosis. Among the light chain families, lambda 6a is one of the most frequent in light chain amyloidosis patients. Its germline protein, 6aJL2, and point mutants, R24G and P7S, are good models to study fibrillogenesis, because their stability and fibril formation characteristics have been described. Both mutations make the germline protein unstable and speed up its ability to aggregate. To date, there is no molecular mechanism that explains how these differences in amyloidogenesis can arise from a single mutation. To look into the structural and dynamical differences in the native state of these proteins, we carried out molecular dynamics simulations at room temperature. Despite the structural similarity of the germline protein and the mutants, we found differences in their dynamical signatures that explain the mutants’ increased tendency to form amyloids. The contact network alterations caused by the mutations, though different, converge in affecting two anti‐aggregation motifs present in light chain variable domains, suggesting a different starting point for aggregation in lambda chains compared to kappa chains.     

Crystal structures of human antibodies: a detailed and unfinished tapestry of immunoglobulin gene products

Sequencing of all human immunoglobulin (Ig) germline gene segments has recently been completed. However, our first glimpses of the recombined products of this combinatorial gene system were in the 1970s, in landmark publications, reporting the crystal structures of two human myeloma proteins, the Mcg lambda light chain dimer and the New IgG1(lambda) Fab. Although numerous crystal structures of murine and human antibodies have now been determined, only a relatively small proportion of the human germline genes have had their corresponding protein three-dimensional structures resolved. Therefore, further structural investigations are required before the inherent diversity of the antibody repertoire can be fully appreciated. We discuss the detailed structural information available for human antibodies with regard to their immune functions. Also discussed, is how the structural information is finding application in the 'humanization' of murine antibodies as part of their development as 'biopharmaceuticals' for the treatment of human disease.     

Primary structure of the variable region of a human lambda VI light chain: Bence Jones protein SUT

To ascertain if lambda VI light chains have unique structural features that account for the preferential association of these proteins with primary or multiple myeloma-related amyloidosis (amyloidosis AL) we have determined the complete amino acid sequence of the variable (V) region of the lambda VI Bence Jones protein SUT. This protein, obtained from a patient with amyloidosis AL, represents a complete light chain consisting of 216 residues and it has structural and serologic properties characteristic for lambda VI light chains. The sequence of the joining segment (J) (positions 100 to 111) of protein SUT is identical to that of the J lambda I segment of the mouse IG lambda light chain gene. V region SUT is closely homologous in sequence to that of another lambda VI amyloid fibrillar protein, AR, differing by 21 residues. The V regions of proteins SUT and AR contain a two-residue insertion at positions 68 and 69 that has also been found in two other lambda VI human light chains but not in the lambda-chains of other V region subgroups.     

Comparison of human and mouse T-cell receptor variable gene segment subfamilies

Like the immunoglobulin Igh-V and Igk-V gene families, the human or mouse TCRV gene families may be grouped into subfamilies displaying >75% nucleic acid sequence similarity among their members. Systematic interspecies sequence comparisons reveal that most mouse Tcr-V subfamilies exhibit clear homology to human TCRV subfamilies (>60% amino acid sequence similarity). Homologous pairs of TCRV genes in mice and humans show higher sequence similarity than TCRV genes from different subfamilies within either species, indicating transpecies evolution of TCRV genes. Mouse and human homologues show conservation of their relative map order, particularly in the 3' region and a similar sequential and developmentally programmed expression. When the V regions from both species were analyzed together, local length differences and conserved residues in the loop regions were revealed, characteristic of each of the four TCRV families.The alignment data reported in this paper have been submitted to the EMBL nucleotide sequence database and have been assigned the alignment number DS23485. The data are available by the EBI FTP server and file server     

Structural studies of monoclonal human cryoprecipitable immunoglobulins

The light chain type, immunoglobulin class and when possible, heavy chain subclass of eleven monoclonal human cryoglobulins were correlated with the variable region subgroup of their light chains. The variable region subgroups were assigned by determining the primary amino acid sequence for the first 15 amino-terminal residues of these light chains. $\text{5}\text{5}$ IgM cryoglobulins which react with human IgG had light chains of the variable region-III kappa chain subgroup (vK-III). $\text{4}\text{4}$ IgG and $\text{2}\text{2}$ IgM cryoglobulins with undefined antibody specificity had both lambda and kappa light chains none of which were vK-III. The data support the concept that there is marked restriction of the IgM anti-IgG antibody response to the IgG auto-antigen.     

Somatic insertions and deletions shape the human antibody repertoire

We have sequenced the heavy and light chain genes from 365 IgG(+) B cells and found that 24 (6.5 %) contain somatically introduced insertions or deletions. These insertions and deletions are clustered at "hot-spots" in the antigen-binding site and frequently result in the creation of new combinations of canonical loop structures or entirely new loops that are not present in the human germline repertoire, but are similar to those seen in other species. Somatic insertion and deletion therefore provides a further mechanism for introducing structural diversity into antibodies in addition to somatic point mutation and receptor editing, which have small (single amino acid changes) and large (chain replacement) impacts on structural diversity, respectively.     

Wild mice express an Ig V lambda gene that differs from any V lambda in BALB/c but resembles a human V lambda subgroup.

The lambda L chain locus in the inbred mouse strains commonly used in the laboratory contains a limited number of germ-line genes; only three V lambda and three functional J lambda-C lambda genes have been identified in BALB/c mice. Previous studies indicated that wild mice may have a considerably expanded number of C lambda genes, as judged by the number of DNA restriction fragments that hybridize to C lambda probes derived from BALB/c. In order to evaluate the expression of these putative lambda genes, we have determined sequences of cDNA encoding lambda-chains in hybridomas from wild mice of the subspecies Mus musculus musculus from two different geographic regions, Denmark and Czechoslovakia. Two of these hybridomas produce L chains with J and C regions that are very similar to those of BALB/c lambda 1 chains, but the V regions of these L chains are only approximately 40% identical in amino acid sequence to the known murine V lambda. Indeed, these wild mouse V lambda are closer in sequence to human V lambda than they are to BALB/c V lambda, especially to human V lambda of subgroup VI, with which they share an unusual two-residue insertion in framework 3; L chains bearing V regions of this rare human type have a marked tendency to enter into amyloid deposits. These findings suggest that similar V lambda may be widespread in mammalian populations, although analysis by Southern blotting indicates that they are not found in BALB/c mice. A third hybridoma produces a L chain whose V lambda resembles BALB/c V lambda 1. The J lambda and C lambda segments of the cDNA encoding all three hybridoma L chains are identical; evidently, of the several putative genes that hybridize to C lambda 1 probes, one is expressed preferentially.     

Allelic polymorphisms and RFLP in the human immunoglobulin lambda light chain locus

The organization of the human immunoglobulin lambda light chain locus (IGL) was recently described. This locus has been entirely sequenced. To evaluate the extent of the genomic variability existing inside that locus, we compiled all the available sequences of germline IGLV genes to find variants of Vλ sequences. We also looked for RFLP polymorphisms in a reputedly highly polymorphic human population from eastern Senegal, and compiled all RFLP data previously published. Analysis of these data indicates that IGLV alleles are frequent and increase the diversity of the lambda light chain repertoire in the human population. In contrast, RFLP and polymorphism by insertion and/or deletion are limited in that locus. This observation reinforces our hypothesis that the human IGL locus has undergone less evolutionary shuffling than the human kappa or heavy-chain loci. Received: 23 December 1998 / Accepted: 1 March 1999     

Molecular characterization of a human anti-Rh(D) antibody with a DH segment encoded by a germ-line sequence.

The lambda-light-chain and lambda-heavy-chain variable-region genes of an anti-Rh(D) (Rh, Rhesus; D, heavy-chain diversity region) human monoclonal antibody secreted by lymphocytes transformed by the Epstein-Barr virus have been cloned and sequenced. Sequence comparison of the anti-Rh(D)mAb lambda-chain variable region with those of the other available human lambda chains revealed that it belonged to the human V lambda I (V lambda, variable region of lambda chain) subgroup. The greatest sequence similarity (80%) was observed with that of another anti-Rh antibody lambda-chain directed against the Rh(c) antigen. For the VH (VH, variable region of heavy chain) sequence, the highest similarity (86%) was observed with the germline VHG3 gene which belongs to the VHI subgroup. The expressed DH sequence of the anti-Rh(D) antibody is also of germline origin and complementarity-determining region 3 is thus produced by VH-DH and DH-JH (J, joining region) joining without recombination of multiple DH gene segments.     

Amino terminal sequence of heavy and light chains from ratfish immunoglobulin

The ratfish,Callorhinchus callorhinchus, a representative of the Holocephali, has a natural serum hemagglutinin (M _r 960 000), composed of heavy (M _r 71000), light (M _r 22 500), and J (M _r 16 000) chains. To approach the mechanisms that generate diversity at this level of evolution, the amino terminal sequence of the heavy and light chains was determined by automated microsequencing. The chains are unblocked and have modest internal sequence heterogeneity. The heavy chains show sequence similarity with the terminal region of the heavy chain from the horned shark,Heterodontus francisci, and other species. In contrast to the heavy chain, the ratfish light chains display low sequence similarity with their shark kappa counterparts. However, their similarity with the variable region of the chicken lambda light chains is about 75%.     

Cre-loxP-mediated gene replacement: a mouse strain producing humanized antibodies

Background: The bacteriophage-derived Cre–loxP recombination system operates efficiently in mammalian cells. This system is particularly useful in gene-targeting experiments in the mouse, and has already been used to generate ‘clean’ deletions of target genes in the germ line, as well as to inactivate target genes in a conditional manner (based on regulated expression of the Cre recombinase). In principle, Cre–loxP-mediated recombination should also allow gene replacement, and thus the introduction of virtually any kind of mutation into the genome.Results We used the Cre–loxP system, in mouse embryonic stem cells, to replace the mouse gene Cγ 1, which encodes the constant region of the heavy chain of IgG1 antibodies, with its human counterpart. The mutation was transmitted through the mouse germ line, and the resulting mutant mice were crossed with mice expressing κ light chains with a human, instead of a mouse, constant region. Mice homozygous for both mutations produce humanized, κ-chain-bearing IgG1 antibodies at the same level and efficiency as wild-type mice produce murine IgG1 antibodies. These animals should enable the ex vivo production of humanized, chimeric monoclonal antibodies specific for any antigen to which the mouse can respond.Conclusion Cre–loxP-mediated gene replacement is a simple and efficient general method of targeted mutagenesis in the mouse.     

High Affinity Humanized Antibodies without Making Hybridomas; Immunization Paired with Mammalian Cell Display and In Vitro Somatic Hypermutation

A method has been developed for the rapid generation of high-affinity humanized antibodies from immunized animals without the need to make conventional hybridomas. Rearranged IgH D(J) regions were amplified from the spleen and lymph tissue of mice immunized with the human complement protein C5, fused with a limited repertoire of human germline heavy chain V-genes to form intact humanized heavy chains, and paired with a human light chain library. Completed heavy and light chains were assembled for mammalian cell surface display and transfected into HEK 293 cells co-expressing activation-induced cytidine deaminase (AID). Numerous clones were isolated by fluorescence-activated cell sorting, and affinity maturation, initiated by AID, resulted in the rapid evolution of high affinity, functional antibodies. This approach enables the efficient sampling of an immune repertoire and the direct selection and maturation of high-affinity, humanized IgGs.     

The CDR1 of the human lambdaVI light chains adopts a new canonical structure

We performed a comparative analysis of the conformation of the CDR1 of the human lambdaVI variable domains JTO and WIL and the equivalent loop of the lambdaI light chains RHE and KOL, which are representative of the type I canonical structure for lambda light chains. On the basis of the differences found in the main chain conformation, as well as the identity of the residues at key positions, we showed that the L1 of some lambdaVI light chains adopts a conformation that represents a new type of canonical structure. The conformation of the L1 of those lambdaVI light chains, is primarily determined by the presence of an Arg residue at position 25. The analysis of the lambdaVI light chain sequences so far reported, showed that near 25% of those proteins have Gly at position 25 instead of Arg, which represents an allotypic variant of the lambdaVI variable locus. The presence of Gly at position 25 in the L1 of lambdaVI light chains would imply a different conformation for this loop. Additionally, the position 68 in lambdaVI light chains, which is at the top of the FR3 loop, showed such spatial orientation and variability that suggested its participation in the conformation of the antigen recognition surface in this subgroup of lambda chains.