Amino acid insertions and deletions contribute to diversify the human Ig repertoire

DNA repair mechanisms that promote insertion-deletion events during immunoglobulin gene diversification

Insertions and deletions (indels) are low-frequency deleterious genomic DNA alterations. Despite their rarity, indels are common, and insertions leading to long complementarity-determining region 3 (CDR3) are vital for antigen-binding functions in broadly neutralizing and polyreactive antibodies targeting viruses. Because of challenges in detecting indels, the mechanism that generates indels during immunoglobulin diversification processes remains poorly understood. We carried out ultra-deep profiling of indels and systematically dissected the underlying mechanisms using passenger-immunoglobulin mouse models. We found that activation-induced cytidine deaminase-dependent ±1-base pair (bp) indels are the most prevalent indel events, biasing deleterious outcomes, whereas longer in-frame indels, especially insertions that can extend the CDR3 length, are rare outcomes. The ±1-bp indels are channeled by base excision repair, but longer indels require additional DNA-processing factors. Ectopic expression of a DNA exonuclease or perturbation of the balance of DNA polymerases can increase the frequency of longer indels, thus paving the way for models that can generate antibodies with long CDR3. Our study reveals the mechanisms that generate beneficial and deleterious indels during the process of antibody somatic hypermutation and has implications in understanding the detrimental genomic alterations in various conditions, including tumorigenesis.

Learning the statistics and landscape of somatic mutation-induced insertions and deletions in antibodies

Affinity maturation is crucial for improving the binding affinity of antibodies to antigens. This process is mainly driven by point substitutions caused by somatic hypermutations of the immunoglobulin gene. It also includes deletions and insertions of genomic material known as indels. While the landscape of point substitutions has been extensively studied, a detailed statistical description of indels is still lacking. Here we present a probabilistic inference tool to learn the statistics of indels from repertoire sequencing data, which overcomes the pitfalls and biases of standard annotation methods. The model includes antibody-specific maturation ages to account for variable mutational loads in the repertoire. After validation on synthetic data, we applied our tool to a large dataset of human immunoglobulin heavy chains. The inferred model allows us to identify universal statistical features of indels in heavy chains. We report distinct insertion and deletion hotspots, and show that the distribution of lengths of indels follows a geometric distribution, which puts constraints on future mechanistic models of the hypermutation process.

Affinity maturation of B cell receptors is an important mechanism by which our body designs neutralizing antibodies to defend us against pathogens, including broadly neutralizing antibodies, which target a wide range of variants of the same pathogen. Such antibodies often contain key insertions and deletions to the germline gene, or “indels”, which are caused by somatic hypermutations. However, the mechanism, frequency and role of these indels are still elusive. We designed a computational method based on a probabilistic framework to infer the characteristics of this mutational process from high-throughput antibody sequencing experiments. Applied to human data, our approach provides a comprehensive quantitative description of insertions and deletions, opening avenues for better understanding the process of affinity maturation and the design of vaccines for eliciting a broad antibody response.

A proposed reverse transcription mechanism for (CAG)n and similar expandable repeats that cause neurological and other diseases

The mechanism of (CAG)n repeat generation, and related expandable repeat diseases in non-dividing cells, is currently understood in terms of a DNA template-based DNA repair synthesis process involving hairpin stabilized slippage, local error-prone repair via MutSβ (MSH2-MSH3) hairpin protective stabilization, then nascent strand extension by DNA polymerases-β and -δ. We advance a very similar slipped hairpin-stabilized model involving MSH2-MSH3 with two key differences: the copying template may also be the nascent pre-mRNA with the repair pathway being mediated by the Y-family error-prone enzymes DNA polymerase-η and DNA polymerase-κ acting as reverse transcriptases. We argue that both DNA-based and RNA-based mechanisms could well be activated in affected non-dividing brain cells in vivo. Here, we compare the advantages of the RNA/RT-based model proposed by us as an adjunct to previously proposed models. In brief, our model depends upon dysregulated innate and adaptive immunity cascades involving AID/APOBEC and ADAR deaminases that are known to be involved in normal locus-specific immunoglobulin somatic hypermutation, cancer progression and somatic mutations at many off-target non-immunoglobulin sites across the genome: we explain how these processes could also play an active role in repeat expansion diseases at RNA polymerase II-transcribed genes.

Immunogenetic factors driving formation of ultralong VH CDR3 in Bos taurus antibodies

The antibody repertoire of Bos taurus is characterized by a subset of variable heavy (VH) chain regions with ultralong third complementarity determining regions (CDR3) which, compared to other species, can provide a potent response to challenging antigens like HIV env. These unusual CDR3 can range to over seventy highly diverse amino acids in length and form unique β-ribbon 'stalk' and disulfide bonded 'knob' structures, far from the typical antigen binding site. The genetic components and processes for forming these unusual cattle antibody VH CDR3 are not well understood. Here we analyze sequences of Bos taurus antibody VH domains and find that the subset with ultralong CDR3 exclusively uses a single variable gene, IGHV1-7 (VHBUL) rearranged to the longest diversity gene, IGHD8-2. An eight nucleotide duplication at the 3' end of IGHV1-7 encodes a longer V-region producing an extended F β-strand that contributes to the stalk in a rearranged CDR3. A low amino acid variability was observed in CDR1 and CDR2, suggesting that antigen binding for this subset most likely only depends on the CDR3. Importantly a novel, potentially AID mediated, deletional diversification mechanism of the B. taurus VH ultralong CDR3 knob was discovered, in which interior codons of the IGHD8-2 region are removed while maintaining integral structural components of the knob and descending strand of the stalk in place. These deletions serve to further diversify cysteine positions, and thus disulfide bonded loops. Hence, both germline and somatic genetic factors and processes appear to be involved in diversification of this structurally unusual cattle VH ultralong CDR3 repertoire.

Clonify: unseeded antibody lineage assignment from next-generation sequencing data

Defining the dynamics and maturation processes of antibody clonal lineages is crucial to understanding the humoral response to infection and immunization. Although individual antibody lineages have been previously analyzed in isolation, these studies provide only a narrow view of the total antibody response. Comprehensive study of antibody lineages has been limited by the lack of an accurate clonal lineage assignment algorithm capable of operating on next-generation sequencing datasets. To address this shortcoming, we developed Clonify, which is able to perform unseeded lineage assignment on very large sets of antibody sequences. Application of Clonify to IgG+ memory repertoires from healthy individuals revealed a surprising lack of influence of large extended lineages on the overall repertoire composition, indicating that this composition is driven less by the order and frequency of pathogen encounters than previously thought. Clonify is freely available at www.github.com/briney/clonify-python.

Tissue-specific expressed antibody variable gene repertoires

Recent developments in genetic technologies allow deep analysis of the sequence diversity of immune repertoires, but little work has been reported on the architecture of immune repertoires in mucosal tissues. Antibodies are the key to prevention of infections at the mucosal surface, but it is currently unclear whether the B cell repertoire at mucosal surfaces reflects the dominant antibodies found in the systemic compartment or whether mucosal tissues harbor unique repertoires. We examined the expressed antibody variable gene repertoires from 10 different human tissues using RNA samples derived from a large number of individuals. The results revealed that mucosal tissues such as stomach, intestine and lung possess unique antibody gene repertoires that differed substantially from those found in lymphoid tissues or peripheral blood. Mutation frequency analysis of mucosal tissue repertoires revealed that they were highly mutated, with little evidence for the presence of naïve B cells, in contrast to blood. Mucosal tissue repertoires possessed longer heavy chain complementarity determining region 3 loops than lymphoid tissue repertoires. We also noted a large increase in frequency of both insertions and deletions in the small intestine antibody repertoire. These data suggest that mucosal immune repertoires are distinct in many ways from the systemic compartment.

JEC. Secondary mechanisms of diversification in the human antibody repertoire

V(D)J recombination and somatic hypermutation (SHM) are the primary mechanisms for diversification of the human antibody repertoire. These mechanisms allow for rapid humoral immune responses to a wide range of pathogenic challenges. V(D)J recombination efficiently generate a virtually limitless diversity through random recombination of variable (V), diversity (D), and joining (J) genes with diverse non-templated junctions between the selected gene segments. Following antigen stimulation, affinity maturation by SHM produces antibodies with refined specificity mediated by mutations typically focused in complementarity determining regions (CDRs), which form the bulk of the antigen recognition site. While V(D)J recombination and SHM are responsible for much of the diversity of the antibody repertoire, there are several secondary mechanisms that, while less frequent, make substantial contributions to antibody diversity including V(DD)J recombination (or D-D fusion), SHM-associated insertions and deletions, and affinity maturation and antigen contact by non-CDR regions of the antibody. In addition to enhanced diversity, these mechanisms allow the production of antibodies that are critical to response to a variety of viral and bacterial pathogens but that would be difficult to generate using only the primary mechanisms of diversification.

Location and length distribution of somatic hypermutation-associated DNA insertions and deletions reveals regions of antibody structural plasticity

Following the initial diversity generated by V(D)J recombination, somatic hypermutation is the principal mechanism for producing further antibody repertoire diversity in antigen-experienced B cells. While somatic hypermutation typically results in single nucleotide substitutions, the infrequent incorporation of genetic insertions and deletions has also been associated with the somatic hypermutation process. We used high throughput antibody sequencing to determine the sequence of thousands of antibody genes containing somatic hypermutation-associated insertions and deletions (SHA indels), which revealed significant differences between the location of SHA indels and somatic mutations. Further, we identified a cluster of insertions and deletions in the antibody framework 3 region which corresponds to the hypervariable region 4 (HV4) in T cell receptors. We propose that this HV4-like region, identified by SHA indel analysis, represents a region of under-appreciated affinity maturation potential. Finally, through analysis of both location and length distribution of SHA indels, we have determined regions of structural plasticity within the antibody protein.

Human peripheral blood antibodies with long HCDR3s are established primarily at original recombination using a limited subset of germline genes

A number of antibodies that efficiently neutralize microbial targets contain long heavy chain complementarity determining region 3 (HCDR3) loops. For HIV, several of the most broad and potently neutralizing antibodies have exceptionally long HCDR3s. Two broad potently neutralizing HIV-specific antibodies, PG9 and PG16, exhibit secondary structure. Two other long HCDR3 antibodies, 2F5 and 4E10, protect against mucosal challenge with SHIV. Induction of such long HCDR3 antibodies may be critical to the design of an effective vaccine strategy for HIV and other pathogens, however it is unclear at present how to induce such antibodies. Here, we present genetic evidence that human peripheral blood antibodies containing long HCDR3s are not primarily generated by insertions introduced during the somatic hypermutation process. Instead, they are typically formed by processes occurring as part of the original recombination event. Thus, the response of B cells encoding antibodies with long HCDR3s results from selection of unusual clones from the naïve repertoire rather than through accumulation of insertions. These antibodies typically use a small subset of D and J gene segments that are particularly suited to encoding long HCDR3s, resulting in the incorporation of highly conserved genetic elements in the majority of antibody sequences encoding long HCDR3s.

Novel atypical nucleotide insertions specifically at VH-DH junction generate exceptionally long CDR3H in cattle antibodies

Some IgM cattle antibodies are amongst the largest known to exist in jawed vertebrates where CDR3H size may extend up to 61 amino acids. To understand the origin of such an exceptionally long CDR3H, bovine D(H) gene locus was completely characterized from Holstein cattle that revealed the presence of a total of eight D(H) genes, including D(H)Q52, with a distinct organization in sub-clusters. However, a total of 10 D(H) genes are identified at the polymorphic D-gene locus in cattle that are classified into four families, designated as BovD(H)A, BovD(H)B, BovD(H)C and BovD(H)D. In fetal B-cells, VDJ recombinations encoding long CDR3H (>50 codons) are directly encoded by the single germline V(H) gl.110.20, the longest D(H)2 and the J(H)1 genes, apart from few N- and P-nucleotide additions at the junctions. Further, non J-proximal D(H)7 gene is preferentially expressed in fetal B cells. The adult VDJ recombinations, however, are distinctly remarkable for 'conserved short nucleotide sequence' ('CSNS'; 13-18 nucleotides), of non-V(H) or D(H) gene origin, inserted specifically at V(H)-D(H) junctions resulting in extension of CDR3H size up to 61 codons. Together with P-nucleotides, N-additions (1-9 nucleotides) are noted at both the V(H)-D(H) and D(H)-J(H) junctions. Such 'CSNS' insertions at V(H)-D(H) junction of adult VDJ recombinations encoding exceptionally long CDR3H provide novel mechanism of antibody diversification in cattle, not yet observed in other species. Further, analysis of V(H)-D(H)-J(H) recombinations originating from fetal B-cells reveals the presence of substitution, deletion or addition mutations without prior exposure to external antigen. Thus, somatic hypermutations may contribute towards diversification of the developing nascent antibody repertoire in cattle. In conclusion, the outlined experiments provide novel antibody diversification mechanism via 'CSNS' insertions, specifically at the V(H)-D(H) junction, in generating exceptionally long CDR3H extending up to 61 codons in cattle antibodies.

Length of the hypermutation motif DGYW/WRCH in the focus of statistical limits. Implications for a double-motif or extended motif recognition models

The motif DGYW/WRCH (Mh) and its frequently discussed simplified derivative GYW/WRC (Mhs) are involved in immunoglobulin (Ig) hypermutation. Both these motifs appear to be markedly shorter than the corresponding conventionally predicted minima of valid sequence lengths (MVSL). The same conclusion concerning both Mh and Mhs can also be obtained in the combined case including a less strict semi-empirically defined w-value and one nucleotide length tolerance related to MVSL. Such disagreement indicates considerably low information content in Mh and Mhs when evaluating these motifs as alphabetical structures (words). This fact raises a question of actually recognized structures (presumably longer than Mh and Mhs). Interestingly, both Mh and Mhs dimers or pairs of closely located Mh or Mhs achieve confirmation of length validity in the case of w=0.05, suggesting thus double-motif recognition as one of statistically consistent explanations. This possibility is also in agreement with the results of our model sequence study of mRNA derived from variable Ig gene sequences (rIgV) with respect to the most frequently occurring structures formed by motif overlaps in all model sequence sets. On the other hand, additional superior occurrence of motif pairs at a structurally important distance of a single DNA thread was found in the conserved domain (cd00099) related sequences of Elasmobranchii origin and less markedly in the corresponding human rIgV, but not in a randomly selected human subset of rIgV. The data are discussed with respect to statistical evaluation and structural properties of hypermutation motifs or the competent enzyme, i.e. activation-induced cytidine deaminase.

Codon insertion and deletion functions as a somatic diversification mechanism in human antibody repertoires

It has been suggested that codon insertion and/or deletion may represent a mechanism that, along with hypermutation, contributes to the affinity maturation of antibodies. We used repertoire cloning to examine human antibodies directed against 3 carbohydrate antigens and 1 protein antigen for the presence of such modifications. We find that both the insertion and deletion of codons occur frequently in antigen-specific responses following vaccination. Codon insertions and deletions were observed most often in the complementarity determining regions, and less frequently in the framework regions, of VH, Vkappa, and Vlambda gene segments, and involved motifs known to be preferred targets of somatic hypermutation. Clonal lineage analysis shows that these events occur through out the course of the somatic maturation of individual antibody clones. We also determined that these alterations of paratope structure have varying effects on the relative affinity of the binding site for its cognate antigen.

REVIEWERS

This article was reviewed by Mark Shlomchik, Deborah Dunn-Walters (nominated by Dr. Andrew Macpherson), and Rachel M. Gerstein.

OPEN PEER REVIEW

Reviewed by Mark Shlomchik, Deborah Dunn-Walters (nominated by Dr. Andrew Macpherson), and Rachel M. Gerstein. For the full reviews, please go to the Reviewers' comments section.

Developmental progression of immunoglobulin heavy chain diversity in sheep

In order to assess the respective impacts of combinatorial rearrangement, junctional diversification, somatic hypermutation and gene conversion in the generation of immunoglobulin heavy chain variable regions diversity, the sequences of 42 variable regions from late fetal, newborn and young sheep were determined and compared to those of adult animals. At earlier stages of development, the use of germline diversity segments appears restricted, junctional variability is already established, and somatic hypermutations are scarce. The sequence diversity in adults is much higher, which we suggest results from a higher hymermutation activity and possibly from the use of a variety of diversity segments. Altogether, this pattern is very reminiscent of the situation observed in cattle, except for the length of the third complementarity determining regions (CDR3) which are shorter in sheep than in bovine. Unlike the chicken and rabbit systems, it seems that new rearrangements continue to occur in sheep for at least several months after birth.

Sequence similarities of protein kinase substrates and inhibitors with immunoglobulins and model immunoglobulin homologue: cell adhesion molecule from the living fossil sponge Geodia cydonium. Mapping of coherent database similarities and implications for evolution of CDR1 and hypermutation

Sequences of immunoglobulin (Ig) domains of adhesive molecule GSAMS from the living fossil sponge Geodia cydonium were compared with the important motif of peptide protein kinase substrates and inhibitors (PKSI), detail PKSI sequences, and a common template sequence, derived from structures determined previously. We found the site-restricted sequence similarities to these peptide sequences predominantly in the GSAM Ig1 domain of GSAMS in the domain region related to corresponding Ig similarities detected earlier. Additional sequence block-related analysis revealed the presence of CDR1-like segments within PKSI-related regions and resulted in the detection of increased numbers of hypermutation motifs just in the CDR1-like segment of GSAM Ig1 (GSAM(cdrl.1)). In the following database searches with PKSI-related regions and GSAM(cdr1.1) we looked for: (i) peptide similarities present in the context of Ig domains or related structures in a large range of species from Archaea to Vertebrata, and (ii) some special nucleotide similarities.

Somatic hypermutation and diverse immunoglobulin gene usage in the human antibody response to the capsular polysaccharide of Streptococcus pneumoniae Type 6B

Combinatorial cloning and expression library analysis were used to determine the expressed human antibody repertoire specific for the capsular polysaccharide (PS) of Streptococcus pneumoniae serotype 6B. Sequence analysis of 55 6B-specific antibody Fab fragments isolated from six vaccinated donors reveal that different individuals used a variety of heavy and light chain germ line variable (V) region genes to form pneumococcal capsular PS (PPS) 6B-specific paratopes. Within each donor, however, the response was more restricted, with five of the six donors using at most one or two gene pairs to form combining sites. Analysis also indicated that although the response in each donor was oligoclonal in terms of variable gene usage, the combination of extensive somatic hypermutation, deletion of germ line-encoded residues, insertion of non-germ line-encoded residues, and intraclonal isotype switching generated a surprising degree of paratope diversity within the individuals analyzed. In contrast to previously studied PS-specific responses, we find that the PPS 6B repertoire makes use of a diverse collection of heavy-chain and light-chain V region gene products to form specific paratopes, with no apparent tendency for conservation of immunoglobulin gene usage between individuals.

Exploring the sialome of the blood-sucking bug Rhodnius prolixus

Rhodnius prolixus is a Hemiptera that feeds exclusively on vertebrate blood in all life stages. Its salivary glands produce potent pharmacological substances that counteract host hemostasis, including anti-clotting, anti-platelet, and vasodilatory substances. To obtain a further insight into the salivary biochemical and pharmacological complexity of this insect, a cDNA library was randomly sequenced, and salivary gland homogenates were fractionated by HPLC to obtain aminoterminal sequences of abundantly expressed proteins. Results indicate a remarkable expansion of the lipocalin family in Rhodnius salivary glands, among other protein sequences described. A summary of 31 new full length proteins deducted from their mRNA sequence is described, including several new members of the nitrophorin, triabin, and pallidipin families. The electronic version of the complete tables is available at http://www.ncbi.nlm.nih.gov/projects/vectors/rhodnius_prolixus.

Diversification of the Ig variable region gene repertoire of synovial B lymphocytes by nucleotide insertion and deletion

Although the changes that occur in Ig V region genes during a B lymphocyte's response to antigen usually result from point mutations, nucleotide insertion and deletion also alter gene sequence. We identified nucleotide insertions and deletions (3 to 12 bp) at a frequency of 1.34%, in Ig V gene cDNA from B lymphocytes residing in the synovial tissues of patients with rheumatoid arthritis. Because the added or lost nucleotides occurred in multiples of 3, they maintained the original reading frame and coded a potentially intact receptor. These V gene modifications were generated somatically, because they were identified in the original cDNA by HCDR3-specific polymerase chain reaction and were not found in other B cells using the same VH genes. Insertions and deletions were detected only in IgG+ and IgA+ transcripts, which exhibited 3 times more point mutations than IgM+ transcripts. In addition, they were usually found in the complementarity determining region, typical targets of somatic mutation. The occurrence of insertion/ deletion in isotype-switched cDNA with higher numbers of V gene mutations that localized to hot spots for V gene mutation suggests that these diversification events were related to the somatic hypermutation process. In support of this, an AGY hot spot motif and a short stretch of DNA similar in sequence to the inserted or deleted segments could be found next to the insertions/deletions, suggesting that these modifications arose from DNA duplication following DNA stand breaks. Thus, nucleotide insertion/deletion can lead to B-cell receptor diversification in B lymphocytes that clonally expand in synovial tissues of patients with rheumatoid arthritis.

A new model of sheep Ig diversification: shifting the emphasis toward combinatorial mechanisms and away from hypermutation

The current model of Ig repertoire development in sheep focuses on the rearrangement of a small number (approximately 20) of Vlambda gene segments. It is believed that this limited combinatorial repertoire is then further diversified through postrearrangement somatic hypermutation. This process has been reported to introduce as many as 110 mutations/1000 nucleotides. In contrast, our data have that indicated somatic hypermutation may diversify the preimmune repertoire to a much lesser extent. We have identified 64 new Vlambda gene segments within the rearranged Ig repertoire. As a result, many of the unique nucleotide patterns thought to be the product of somatic hypermutation are actually hard-coded within the germline. We suggest that combinatorial rearrangement makes a much larger contribution, and somatic hypermutation makes a much smaller contribution to the generation of diversity within the sheep Ig repertoire than is currently acknowledged.

Binding characteristics determine the neutralizing potential of antibody fragments specific for antigenic domain 2 on glycoprotein B of human cytomegalovirus

Site I of antigenic domain 2 (AD-2) on human cytomegalovirus glycoprotein B (gB) is poorly immunogenic in both man and mouse and knowledge about antibody repertoires reactive with this epitope is thus limited. Here we have characterized a phage display-derived repertoire of antibody fragments specific for this epitope in terms of antigen recognition, fine-specificity, and virus-neutralizing capacity. Our results show that the functional properties within a closely related repertoire may differ widely and that the effectiveness of the members of the repertoire to neutralize the virus is determined by the fine-specificity and kinetics of the interaction with the antigen. The half-life of the interaction between monomeric antibody fragments and gB seems to be particularly critical for the neutralizing capacity. We also demonstrate that sequence variation within gB allows virus variants to escape at least a part of the AD-2-specific neutralizing antibody repertoire, apparently without preventing antibody binding to the epitope.

Sequence similarities of protein kinase peptide substrates and inhibitors: comparison of their primary structures with immunoglobulin repeats

Forty original sequences of peptide substrates and inhibitors of protein kinases and phosphatases were aligned in a chain matrix without artificial gaps. Fifteen protein kinase peptide substrates and inhibitors (PKSI peptides) contained a common dipeptide ArgArg and also additional important tetra-, tri- and dipeptide homologies. Three further peptide substrates were significantly similar to these peptides but lacked the ArgArg dipeptide. Sequence comparison of individual PKSI peptides revealed probabilistically restricted consensus sequence--PKSI motif--comprising 8 homologous and 13 non-randomly distributed amino acids without considering mutation analysis. This template motif was compared with the consensus sequences of 12 different immunoglobulin domains. In 11 of 12 these domains, the starts of homologous segments were found at nearly the same domain related sites, beginning with serine. A single-triplet mutation of any of the first two triplet bases that encode equally localized amino acids in each of the two sequence sets (PKSI and Ig) revealed additional homologies with the other set. A primary derived motif version composed of 9 homologous and seven non-randomly distributed amino acids was consequently established by its feedback projection into the original sequence sets. This procedure yielded a second preliminary motif version (revised motif) formed by a sequence of 9 homologous amino acids and two non-randomly distributed amino acids. In addition, three shorter oligopeptide motifs called important stereotypes were derived, based on repeated homology between Ig chains and the revised motif. The most extensive similarities in terms of these stereotypes occurred in the CH2 and CH4 domains of Ig peptides, and inhibitors of cAMP dependent protein kinase and protein kinase A. Further comparisons based on a reference sequence set arranged with the aid of feedback projection revealed a lower similarity between variable Ig chains reflected in a decreased number of homologous amino acids. Two final motif versions, FMC and FMV, were found in two different subsets of constant and variable Ig chains, respectively. FMC was composed of seven homologous and one non-randomly distributed amino acids forming the dispersed structure STLR(C)LVSD, whereas 6 homologous and one questionable amino acid constituted FMV. Only CH4 and CH1 domain segments contained all five high-incidence amino acids, which represented a higher level of similarity than homologous amino acids of all preliminary and final motifs. Four such amino acids were present also in three PKSI peptides. All similarities described here occur in domain segments positionally overlapping with the CDR1 region of variable chains. The results are discussed in terms of immunoglobulin evolution, the position of Fc receptor binding sites and degeneration or mutability of the triplets of motif-constituting amino acids.

DNA breaks in hypermutating immunoglobulin genes: evidence for a break-and-repair pathway of somatic hypermutation

To test the hypothesis that immunoglobulin gene hypermutation in vivo employs a pathway in which DNA breaks are introduced and subsequently repaired to produce mutations, we have used a PCR-based assay to detect and identify single-strand DNA breaks in lambda1 genes of actively hypermutating primary murine germinal center B cells. We find that there is a two- to threefold excess of breaks in lambda1 genes of hypermutating B cells, relative to nonhypermutating B cells, and that 1.3% of germinal center B cells contain breaks in the lambda1 gene that are associated with hypermutation. Breaks were found in both top and bottom DNA strands and were localized to the region of lambda1 that actively hypermutates, but duplex breaks accounted for only a subset of breaks identified. Almost half of the breaks in hypermutating B cells occurred at hotspots, sites at which two or more independent breaks were identified. Breaksite hotspots were associated with characteristic sequence motifs: a pyrimidine-rich motif, either RCTYT or CCYC; and RGYW, a sequence motif associated with hypermutation hotspots. The sequence motifs identified at breaksite hotspots should inform the design of substrates for characterization of activities that participate in the hypermutation pathway.

Comparative characteristics of mu chain and alpha chain transcripts expressed by individual tonsil plasma cells

Plasma cells (PCs) are one of the two major cell types generated during germinal center reactions. To test the hypothesis that PCs express a unique repertoire of immunoglobulin (Ig) genes resulting from intensive antigenic stimulation and selection, the mutational pattern and distribution of V(H) gene segments within 178 transcripts amplified from individual IgM and IgA secreting tonsil PCs were analyzed. The results demonstrated that both mu and alpha transcripts expressed repertoires with limited diversity. Moreover, both mu and alpha transcripts were heavily mutated, with a significantly increased mutational frequency noted for alpha compared to mu transcripts (5.0 x 10(-2) vs 1.8 x 10(-2), P<0.001). In addition, both mu and alpha transcripts showed significantly greater targeting of mutations to RGYW motifs (purine/guanine/pyrimidine/A or T) compared to memory B cells. Finally, clonally expanded cells were detected in alpha but not mu PC compartments. These results indicate that antigen driven stimulation and selection shape the entire expressed PC repertoire, but the impact is greater in alpha expressing PCs.

Immunoglobulin heavy chain variable region gene replacement As a mechanism for receptor revision in rheumatoid arthritis synovial tissue B lymphocytes

Mature B cells can alter their antibody repertoires by several mechanisms, including immunoglobulin heavy chain variable region (V(H)) replacement. This process changes the antigen combining site by replacing a portion of the original V(H)/diversity/heavy chain joining region (V(H)DJ(H)) rearrangement with a corresponding portion of a new V(H) segment. This exchange can involve cryptic heptamer-like sequences embedded in the coding regions of V(H) genes. While studying the B lymphocytes that expand in the synovial tissues of patients with rheumatoid arthritis (RA), clones with V(H)DJ(H) variants that were apparently generated by V(H) replacement were identified with surprising frequency (approximately 8%). Examples of multiple independent V(H) replacement events occurring in distinct progeny clones were also identified. These secondary V(H) rearrangements were documented at both the cDNA and genomic DNA levels and involved several heptamer-like sequences at four distinct locations within V(H) (three sites in framework region 3 and one in complementarity determining region 2). The identification of blunt-ended double-stranded DNA breaks at the embedded heptamers and the demonstration of recombinase activating gene (RAG) expression suggested that these rearrangements could occur in the synovial tissues, presumably in pseudo-germinal centers, and that they could be mediated by RAG in a recognition signal sequence-specific manner. The presence of V(H) mutations in the clones that had undergone replacement indicated that these B cells were immunocompetent and could receive and respond to diversification signals. A relationship between these secondary V(H) gene rearrangements and the autoimmunity characteristic of RA should be considered.

Origin and diversification of the clonogenic cell in multiple myeloma: lessons from the immunoglobulin repertoire

The study of immunoglobulin genes in multiple myeloma over the last decade has provided important information regarding biology, ontogenetic assignment, disease evolution, pathogenic consequences and tumor-specific therapeutic intervention. Detailed analysis of VH genes has revealed the clonal relationship between switch variants expressed by the bone marrow plasma cell and myeloma progenitors in the marrow and peripheral blood. Regarding VH usage, a bias was found against the V4-34 gene encoding antibodies with cold agglutinin specificity (anti-I/i), thus explaining in part the absence of autoimmune phenomena in myeloma compared to other B cell lymphoproliferative disorders. However, in some studies a substantial number of cases analyzed were carrying the rearranged Humkappav325 Vkapppa gene, known to be over utilized by B cell chronic lymphocytic leukemia clones and possessing autoantibody binding activity. VH genes accumulate somatic hypermutations following a distribution compatible with antigen selection, but with no intraclonal heterogeneity. The analysis of Vkappa genes indicates a bias in usage of Vkappa family members; somatic hypermutation, in line with antigen selection, of the expressed Vkappa genes is higher than any other B cell lymphoid disorder. Similar conclusions were reached for Vlambda genes; in this case, the analysis raises the controversial issue of N nucleotide insertion at Vlambda-Jlambda junctions, apparently as a result of TdT activity. A complementary imprint of antigen selection as evidenced by somatic hypermutation of either the VH or VL clonogenic genes has been observed. The absence of ongoing somatic mutations in either VH or VL genes gives rise to the notion that the cell of origin in myeloma is a post-germinal center memory B cell.

Class switch recombination and hypermutation require activation-induced cytidine deaminase (AID), a potential RNA editing enzyme

Induced overexpression of AID in CH12F3-2 B lymphoma cells augmented class switching from IgM to IgA without cytokine stimulation. AID deficiency caused a complete defect in class switching and showed a hyper-IgM phenotype with enlarged germinal centers containing strongly activated B cells before or after immunization. AID-/- spleen cells stimulated in vitro with LPS and cytokines failed to undergo class switch recombination although they expressed germline transcripts. Immunization of AID-/- chimera with 4-hydroxy-3-nitrophenylacetyl (NP) chicken gamma-globulin induced neither accumulation of mutations in the NP-specific variable region gene nor class switching. These results suggest that AID may be involved in regulation or catalysis of the DNA modification step of both class switching and somatic hypermutation.

Somatic hypermutation in MutS homologue (MSH)3-, MSH6-, and MSH3/MSH6-deficient mice reveals a role for the MSH2-MSH6 heterodimer in modulating the base substitution pattern

Although the primary function of the DNA mismatch repair (MMR) system is to identify and correct base mismatches that have been erroneously introduced during DNA replication, recent studies have further implicated several MMR components in somatic hypermutation of immunoglobulin (Ig) genes. We studied the immune response in mice deficient in MutS homologue (MSH)3 and MSH6, two mutually exclusive partners of MSH2 that have not been examined previously for their role in Ig hypermutation. In Msh6(-)/- and Msh3(-)/-/Msh6(-)/- mice, base substitutions are preferentially targeted to G and C nucleotides and to an RGYW hot spot, as has been shown previously in Msh2(-)/- mice. In contrast, Msh3(-)/- mice show no differences from their littermate controls. These findings indicate that the MSH2-MSH6 heterodimer, but not the MSH2-MSH3 complex, is responsible for modulating Ig hypermutation.

Secret sharers in the immune system: a novel RNA editing activity links switch recombination and somatic hypermutation

A new mechanism for regulation in the immune system has been identified: a cytidine deaminase is critical for both class switch recombination and somatic hypermutation, revealing an unanticipated link between these two processes.