Templated insertions in the rearranged chicken IgL V gene segment arise by intrachromosomal gene conversion

A comprehensive analysis of the genomic organization, expression and phylogeny of immunoglobulin light chain genes in pigeon (Columba livia)

Previous studies on immunoglobulin light chain (IgL) genes in avian species are limited to Galloanseres, and few studies have investigated IgL genes in Neoaves, which includes most living birds. Based on published genome data, we demonstrate that the pigeon (Columba livia) IgL locus spans approximately 24 kb of DNA and contains twenty Vλ segments located upstream of a single pair of Jλ-Cλ. Among the identified Vλ gene segments, four segments are structurally intact and all four segments are able to recombine with Jλ. Moreover, the four functional Vλ segments are preferentially utilized in VλJλ recombination. Phylogenetic analysis suggests that the presence of the four functional Vλ segments in pigeon was likely generated by gene duplication that occurred after the divergence of pigeon and other birds. Our study provides insight into IgL gene evolution and evolutionary diversity of Ig genes in birds.

V(D)J Rearrangement Is Dispensable for Producing CDR-H3 Sequence Diversity in a Gene Converting Species

An important characteristic of chickens is that the antibody repertoire is based on a single framework, with diversity found mainly in the CDRs of the light and heavy chain variable regions. Despite this apparent limitation in the antibody repertoire, high-affinity antibodies can be raised to a wide variety of targets, including those that are highly conserved. Transgenic chickens have previously been generated that express a humanized antibody repertoire, with a single framework that incorporates diversity by the process of gene conversion, as in wild-type chickens. Here, we compare the sequences and antibodies that are generated purely by gene conversion/somatic hypermutation of a pre-rearranged heavy chain, with the diversity obtained by V(D)J rearrangement followed by gene conversion and somatic hypermutation. In a gene converting species, CDR-H3 lengths are more variable with V(D)J rearrangement, but similar levels of amino acid diversity are obtainable with gene conversion/somatic hypermutation alone.

Chickens with humanized immunoglobulin genes generate antibodies with high affinity and broad epitope coverage to conserved targets

Transgenic animal platforms for the discovery of human monoclonal antibodies have been developed in mice, rats, rabbits and cows. The immune response to human proteins is limited in these animals by their tolerance to mammalian-conserved epitopes. To expand the range of epitopes that are accessible, we have chosen an animal host that is less phylogenetically related to humans. Specifically, we generated transgenic chickens expressing antibodies from immunoglobulin heavy and light chain loci containing human variable regions and chicken constant regions. From these birds, paired human light and heavy chain variable regions are recovered and cloned as fully human recombinant antibodies. The human antibody-expressing chickens exhibit normal B cell development and raise immune responses to conserved human proteins that are not immunogenic in mice. Fully human monoclonal antibodies can be recovered with sub-nanomolar affinities. Binning data of antibodies to a human protein show epitope coverage similar to wild type chickens, which we previously showed is broader than that produced from rodent immunizations.

Insights into the chicken IgY with emphasis on the generation and applications of chicken recombinant monoclonal antibodies

The advantages of chicken (Gallus gallus domesticus) antibodies as immunodiagnostic and immunotherapeutic biomolecules has only been recently recognized. Even so, chicken antibodies remain less-well characterized than their mammalian counterparts. This review aims at providing a current overview of the structure, function, development and generation of chicken antibodies. Additionally, brief but comprehensive insights into current knowledge pertaining to the immunogenetic framework and diversity-generation of the chicken immunoglobulin repertoire which have contributed to the establishment of recombinant chicken mAb-generating methods are discussed. Focus is provided on the current methods used to generate antibodies from chickens with added emphasis on the generation of recombinant chicken mAbs and its derivative formats. The advantages and limitations of established protocols for the generation of chicken mAbs are highlighted. The various applications of recombinant chicken mAbs and its derivative formats in immunodiagnostics and immunotherapy are further detailed.

A double-strand break can trigger immunoglobulin gene conversion

All three B cell-specific activities of the immunoglobulin (Ig) gene re-modeling system—gene conversion, somatic hypermutation and class switch recombination—require activation-induced deaminase (AID). AID-induced DNA lesions must be further processed and dissected into different DNA recombination pathways. In order to characterize potential intermediates for Ig gene conversion, we inserted an I-SceI recognition site into the complementarity determining region 1 (CDR1) of the Ig light chain locus of the AID knockout DT40 cell line, and conditionally expressed I-SceI endonuclease. Here, we show that a double-strand break (DSB) in CDR1 is sufficient to trigger Ig gene conversion in the absence of AID. The pattern and pseudogene usage of DSB-induced gene conversion were comparable to those of AID-induced gene conversion; surprisingly, sometimes a single DSB induced multiple gene conversion events. These constitute direct evidence that a DSB in the V region can be an intermediate for gene conversion. The fate of the DNA lesion downstream of a DSB had more flexibility than that of AID, suggesting two alternative models: (i) DSBs during the physiological gene conversion are in the minority compared to single-strand breaks (SSBs), which are frequently generated following DNA deamination, or (ii) the physiological gene conversion is mediated by a tightly regulated DSB that is locally protected from non-homologous end joining (NHEJ) or other non-homologous DNA recombination machineries.

Diversification of the Primary Antibody Repertoire by AID-Mediated Gene Conversion

Gene conversion, mediated by activation-induced cytidine deaminase (AID), has been found to contribute to generation of the primary antibody repertoire in several vertebrate species. Generation of the primary antibody repertoire by gene conversion of immunoglobulin (Ig) genes occurs primarily in gut-associated lymphoid tissues (GALT) and is best described in chicken and rabbit. Here, we discuss current knowledge of the mechanism of gene conversion as well as the contribution of the microbiota in promoting gene conversion of Ig genes. Finally, we propose that the antibody diversification strategy used in GALT species, such as chicken and rabbit, is conserved in a subset of human and mouse B cells.

A comparative overview of immunoglobulin genes and the generation of their diversity in tetrapods

In the past several decades, immunoglobulin (Ig) genes have been extensively characterized in many tetrapod species. This review focuses on the expressed Ig isotypes and the diversity of Ig genes in mammals, birds, reptiles, and amphibians. With regard to heavy chains, five Ig isotypes - IgM, IgD, IgG, IgA, and IgE - have been reported in mammals. Among these isotypes, IgM, IgD, and IgA (or its analog, IgX) are also found in non-mammalian tetrapods. Birds, reptiles, and amphibians express IgY, which is considered the precursor of IgG and IgE. Some species have developed unique isotypes of Ig, such as IgO in the platypus, IgF in Xenopus, and IgY (ΔFc) in ducks and turtles. The κ and λ light chains are both utilized in tetrapods, but the usage frequencies of κ and λ chains differ greatly among species. The diversity of Ig genes depends on several factors, including the germline repertoire and recombinatorial and post-recombinatorial diversity, and different species have evolved distinct mechanisms to generate antibody diversity.

Somatic hypermutation leads to diversification of the heavy chain immunoglobulin repertoire in cattle

The availability of unique variable (VH), diversity (D), and joining (JH) gene segments in the vertebrate germline determines the extent to which a primary immunoglobulin (Ig) repertoire can be generated through combinatorial rearrangement. Although bovine D segments possess unusual properties, the diversity of the primary Ig heavy chain (IgH) repertoire in cattle is restricted by the dominance of a single family of germline VH genes of limited number and diversity. Cattle therefore must employ other diversification strategies in order to generate a functional IgH repertoire, the main candidates being gene conversion and somatic hypermutation. In considering these possibilities, we predicted that if somatic hypermutation was active during B lymphocyte development, the process would introduce nucleotide substitutions to the VDJ exon and also non-coding region lying downstream of the rearranged JH segment. In contrast, our expectation was that gene conversion would show a greater tendency to confine modification to the IgH coding sequence, leaving intron regions substantially unmodified. An analysis of rearranged IgH sequences from cattle of different ages revealed that the diversification of germline sequences could be observed in very young calves and that substitution frequency increased with age. The age-dependent accumulation of mutations was particularly apparent in the second IgH complementarity-determining region (CDR2). Single base substitutions were found to predominate, with purines targeted more frequently than pyrimidines and transitions favoured over transversions. In non-coding regions, mutations were detected at a normalised frequency that was indistinguishable from that observed in CDR2. These data are consistent with a process of IgH diversification driven predominantly by somatic hypermutation.

Analysis of the immunoglobulin light chain genes in zebra finch: evolutionary implications

All jawed vertebrates produce immunoglobulins (IGs) as a defense mechanism against pathogens. Typically, IGs are composed of two identical heavy chains (IGH) and two identical light chains (IGL). Most tetrapod species encode more than one isotype of light chains. Chicken is the only representative of birds for which genomic information is currently available and is an exception to the above rule because it encodes only a single IGL isotype (i.e., lambda). Here, we show that the genome of zebra finch, another bird species, encodes a single IGL isotype, that is, lambda, like the chicken. These results strongly suggest that the second isotype (i.e., kappa) present in both reptiles and mammals was lost in a very early stage of bird evolution. Furthermore, we show that both chicken and zebra finch contain a single set of functional variable, joining, and constant region genes and multiple variable region pseudogenes. The latter finding suggests that this type of genomic organization was already present in the common ancestor of these bird species and remained unchanged over a long evolutionary time. This conservation is in contrast with the high levels of variation observed in the mammalian IGL loci. The presence of a single functional variable region gene followed by multiple variable pseudogenes in zebra finch suggest that this species may be generating antibody diversity by a gene conversion-like mechanism like the chicken.

Genomic organization of the chicken CD8 locus reveals a novel family of immunoreceptor genes

The genomic organization of the chicken CD8alpha gene was investigated to determine the basis of its polymorphism. Contiguous to the CD8alpha gene we identified multiple DNA blocks possessing sequences homologous to CD8alpha. Gene conversions and recombination over evolutionary time among CD8alpha and these CD8alpha homologous genes seem to account for the observed polymorphism. Furthermore, these CD8alpha-like DNAs encode a distinct multigene family of immunoreceptors that have a charged or polar residue in place of the interspecies-conserved CD8alpha transmembrane proline residue and a short cytoplasmic tail nonhomologous to CD8alpha. The identification of this novel multigene family with an organization reminiscent of human killer Ig-like receptors raises compelling questions on their evolutionary relationship among immunoreceptors.

Ligand-independent signaling during early avian B cell development

Surface immunoglobulin (sIg) expression has been conserved as a critical checkpoint in B lymphocyte development. In the chicken embryo, only sIg+ B cells are selectively expanded in the bursa of Fabricius, a primary lymphoid organ unique to the avian species. We have previously demonstrated that an interaction between the antigen- binding sites of sIg and a specific bursal ligand(s) is not required to regulate this developmental checkpoint. Rather, the requirement for sIg expression can be attributed to the surface expression of the Igalpha/beta heterodimer associated with sIg. More specifically, ligand-independent signaling downstream of the Igalpha cytoplasmic domain drives all bursal stages of B cell development during embryogenesis. We discuss here a site-directed mutagenesis approach to identify the critical membrane proximal events involved in ligand-independent signaling during B cell development.

Role for RAD18 in homologous recombination in DT40 cells

RAD18 is an E3 ubiquitin ligase that catalyzes the monoubiquitination of PCNA, a modification central to DNA damage bypass and postreplication repair in both yeast and vertebrates. Although current evidence suggests that homologous recombination provides an essential backup in vertebrate rad18 mutants, we show that in chicken DT40 cells this is not the case and that RAD18 plays a role in the recombination reaction itself. Gene conversion tracts in the immunoglobulin locus of rad18 cells are shorter and are associated with an increased frequency of deletions and duplications. rad18 cells also exhibit reduced efficiency of gene conversion induced by targeted double-strand breaks in a reporter construct. Blocking an early stage of the recombination reaction by disruption of XRCC3 not only suppresses immunoglobulin gene conversion but also prevents the aberrant immunoglobulin gene rearrangements associated with RAD18 deficiency, reverses the elevated sister chromatid exchange of the rad18 mutant, and reduces its sensitivity to DNA damage. Together, these data suggest that homologous recombination is toxic in the absence of RAD18 and show that, in addition to its established role in postreplication repair, RAD18 is also required for the orderly completion of gene conversion.

Sequence transfers between variable regions in a mouse antibody transgene can occur by gene conversion

Different vertebrate species show widely differing usage of somatic hyperconversion (SHC) as a mechanism for diversifying expressed Ab V genes. The basis for the differing levels of SHC in different species is not known. Although no clear evidence for SHC has been found in normal mouse B cells, transgenic mice carrying high-copy numbers of a gene construct designed to optimize detection of SHC have previously been shown to exhibit sequence transfers that resemble gene conversion events. However, these transgene sequence transfers could reflect multistep or reciprocal DNA recombination events rather than gene conversions. We now find in low-copy number transgenic mice that transgene sequence transfers can exhibit the unidirectional sequence information movement that is a hallmark of gene conversion. This indicates that gene conversion between V region sequences can occur in mouse B cells; we propose that the lack of efficient SHC contributions to Ab diversification in normal mice may be due, at least in part, to the particular pattern of V gene recombinational accessibility that occurs in differentiating mouse B cells.

Antibodies, immunoglobulin genes and the bursa of Fabricius in chicken B cell development

The bursa of Fabricius is critical for the normal development of B lymphocytes in birds. It is productively colonized during embryonic life by a limited number of B cell precursors that have undergone the immunoglobulin gene rearrangements required for expression of cell surface immunoglobulin. Immunoglobulin gene rearrangement occurs in the absence of terminal deoxynucleotidyl transferase and generates minimal antibody diversity. In addition, observations that immunoglobulin heavy and light chain variable gene rearrangement occur at the same time and that allelic exclusion of immunoglobulin expression is regulated at the level of variable region gene rearrangement provide a striking contrast to rodent and primate models of immunoglobulin gene assembly. Following productive colonization of the bursa, developing B cells undergo rapid proliferation and the immunoglobulin V region genes that generate the specificity of the B cell surface immunoglobulin receptor undergo diversification. Immunoglobulin diversity in birds is generated by somatic gene conversion events in which sequences derived from upstream families of pseudogenes replace homologous sequences in unique and functionally rearranged immunoglobulin heavy and light chain variable region genes. This mechanism is distinct from and much more efficient than mechanisms of antibody diversification seen in rodents and primates. While the bursal microenvironment is not required for immunoglobulin gene rearrangement and expression, it is essential for the generation of antibody diversity by gene conversion. Following hatch, gut derived antigens are taken up by the bursa. While bursal development prior to hatch occurs in the absence of exogenous antigen, chicken B cell development after hatch may therefore be influenced by the presence of environmental antigen. This review focuses on the differences between B cell development in the chicken as compared to rodent and primate models.

The catalytic activity of REV1 is employed during immunoglobulin gene diversification in DT40

REV1 plays a key role in vertebrate translesion synthesis. Although its deoxycytidyl transferase activity is dispensable for tolerance of DNA damage caused by a number of mutagens, its extreme C terminus, which interacts with other translesion polymerases and PCNA, is essential. By examining immunoglobulin diversification in the genetically tractable chicken cell line DT40 we show that the generation of non-templated point mutations from C/G to G/C does require the catalytic activity of REV1. This provides the first clear evidence that the catalytic activity of REV1 is utilised in vivo in higher eukaryotes and is involved in immunoglobulin diversification. Although rev1 DT40 cells incorporate few point mutations, a mutant lacking the C terminus of REV1 exhibits a similar level to that seen in wild-type cells. Thus, the polymerase selection or stabilisation role of REV1 does not appear to play a major role in the bypass of AID-dependent abasic sites.

Immunoglobulin diversification in DT40: a model for vertebrate DNA damage tolerance

Studies of recombination in vertebrates have rather lagged behind those in yeast and bacteria in large part due to the relative genetic intractability of vertebrate model systems. Immunoglobulin diversification in the chicken cell line DT40 provides a powerful combination of a physiological recombination process coupled with facile genetic modification. The immunoglobulin variable regions of DT40 constitutively diversify by a combination of gene conversion, in which sequence changes are templated from one of a number of upstream pseudogenes or by non-templated point mutation. Both of these events are initiated by abasic sites in the variable region DNA generated following the targeted deamination of cytidine by activation induced deaminase. Recent work has shown that the two outcomes, gene conversion and somatic mutation, are likely to reflect alternate pathways for the processing of these abasic sites. In this review I will discuss the current data on avian Ig gene diversification and examine how the immunoglobulin loci of DT40 may provide a useful model system for studying the mechanisms and interactions of vertebrate recombination and pathways of DNA damage tolerance.

Activation-induced cytidine deaminase initiates immunoglobulin gene conversion and hypermutation by a common intermediate

Depending on the species and the lymphoid organ, activation-induced cytidine deaminase (AID) expression triggers diversification of the rearranged immunoglobulin (Ig) genes by pseudo V (psiV) gene- templated gene conversion or somatic hypermutation. To investigate how AID can alternatively induce recombination or hypermutation, psiV gene deletions were introduced into the rearranged light chain locus of the DT40 B-cell line. We show that the stepwise removal of the psiV donors not only reduces and eventually abolishes Ig gene conversion, but also activates AID-dependent Ig hypermutation. This strongly supports a model in which AID induces a common modification in the rearranged V(D)J segment, leading to a conversion tract in the presence of nearby donor sequences and to a point mutation in their absence.

The avian B-cell receptor complex: distinct roles of Igalpha and Igbeta in B-cell development

The bursa of Fabricius has evolved in birds as a gut-associated site of B-cell lymphopoiesis that is segregated from the development of other hematopoietic lineages. Despite differences in the developmental progression of chicken as compared to murine B-cell lymphopoiesis, cell-surface immunoglobulin (sIg) expression has been conserved in birds as an essential checkpoint in B-cell development. B-cell precursors that express an sIg complex that includes the evolutionarily conserved Igalpha/beta heterodimer colonize lymphoid follicles in the bursa, whereas B-cell precursors that fail to express sIg due to non-productive V(D)J recombination are eliminated. Productive retroviral gene transfer has allowed us to introduce chimeric receptor constructs into developing B-cell precursors in vivo. Chimeric proteins comprising the extracellular and transmembrane regions of murine CD8alpha fused to the cytoplasmic domain of chicken Igalpha efficiently supported B-cell development in precursors that lacked endogenous sIg expression. By contrast, expression of an equivalent chimeric receptor containing the cytoplasmic domain of Igbeta actively inhibited B-cell development. Consequently, the cytoplasmic domains of Igalpha and Igbeta play functionally distinct roles in chicken B-cell development.

Immunoglobulin gene conversion: Insights from bursal B cells and the DT40 cell line

Chicken B cells diversify their immunoglobulin (Ig) light and heavy chain genes by pseudogene templated gene conversion within the bursa of Fabricius. Although Ig gene conversion was initially believed to occur only in birds, it is now clear that most farm animals also use this elegant mechanism to develop an immunoglobulin gene repertoire. The best model to study Ig gene conversion remains the chicken Ig light chain locus due to its compact size and the fact that all the pseudogene donors are sequenced. Furthermore, gene conversion continues in the bursa-derived DT40 cell line whose genome can be easily modified by targeted integration of transfected constructs. Disruption of the AID gene, which had been shown to control somatic hypermutation and switch recombination in mammals leads to a complete block of gene conversion in DT40 indicating that all B-cell specific repertoire formation is controlled by the same gene. Here, we review the genetics and the molecular mechanism of Ig gene conversion based on sequence analysis of bursal B cells and gene disruption studies in the DT40 cell line.

Antibody repertoire development in fetal and neonatal piglets. VI. B cell lymphogenesis occurs at multiple sites with differences in the frequency of in-frame rearrangements

B cell lymphogenesis in mammals occurs in various tissues during development but it is generally accepted that it operates by the same mechanism in all tissues. We show that in swine, the frequency of in-frame (IF) VDJ rearrangements differs among yolk sac, fetal liver, spleen, early thymus, bone marrow, and late thymus. All VDJ rearrangements recovered and analyzed on the 20th day of gestation (DG20) from the yolk sac were 100% IF. Those recovered at DG30 in the fetal liver were >90% IF, and this predominance of cells with apparently a single IF rearrangement continued in all organs until approximately DG45, which corresponds to the time when lymphopoiesis begins in the bone marrow. Thereafter, the proportion of IF rearrangements drops to approximately 71%, i.e., the value predicted whether VDJ rearrangement is random and both chromosomes were involved. Unlike other tissues, VDJs recovered from thymus after DG50 display a pattern suggesting no selection for IF rearrangements. Regardless of differences in the proportion of IF rearrangements, we observed no significant age- or tissue-dependent changes in CDR3 diversity, N region additions, or other characteristics of fetal VDJs during ontogeny. These findings indicate there are multiple sites of B cell lymphogenesis in fetal piglets and differences in the frequency of productive VDJ rearrangements at various sites. We propose the latter to result from differential selection or a developmentally dependent change in the intrinsic mechanism of VDJ rearrangement.

Distinct clonal Ig diversification patterns in young appendix compared to antigen-specific splenic clones

The young rabbit appendix is a dynamic site for primary B cell repertoire development. To study diversification patterns during clonal expansion, we collected single appendix B cells from 3- to 9-wk-old rabbits and sequenced rearranged H and L chain genes. Single cells obtained by hydraulic micromanipulation or laser capture microdissection were lysed, PCR amplified, and products directly sequenced. Gene conversion-like changes occurred in rearranged H and L chain sequences by 3-4 wk of age. Somatic mutations were found in the D regions that lack known conversion donors and probably also occurred in the V genes. A few small sets of clonally related appendix B cells were found at 3-5 wk; by 5.5 wk, some larger clones were recovered. The diversification patterns in the clones from appendix were strikingly different from those found previously in splenic germinal centers where an immunizing Ag was driving the expansion and selection process toward high affinity. Clonally related appendix B cells developed different amino acid sequences in each complementarity-determining region (CDR) including CDR3, whereas dominant clones from spleen underwent few changes in CDR3. The variety of combining sites generated by diversification within individual clones suggests that at least some clonal expansion and selection, known to require normal gut flora, may be driven through indirect effects of microbial components rather than solely by their recognition as specific foreign Ags. This diversity of combining sites within B cell clones supports the proposed role of appendix in generating the preimmune repertoire.

Somatic immunoglobulin hypermutation

Immunoglobulin hypermutation provides the structural correlate for the affinity maturation of the antibody response. Characteristic modalities of this mechanism include a preponderance of point-mutations with prevalence of transitions over transversions, and the mutational hotspot RGYW sequence. Recent evidence suggests a mechanism whereby DNA-breaks induce error-prone DNA synthesis in immunoglobulin V(D)J regions by error-prone DNA polymerases. The nature of the targeting mechanism and the trans-factors effecting such breaks and their repair remain to be determined.

Copy-number fluctuation by unequal crossing-over in the chicken avidin gene family

The chicken avidin gene (AVD) forms a closely clustered gene family together with several avidin-related genes (AVRs). In this study, we used fluorescence in situ hybridization on extended DNA fibers (fiber-FISH) to show that the number of the AVD and AVR genes differs between individuals. Furthermore, the gene copy-number showed wide somatic variation in white blood cells of the individuals. The molecular mechanism underlying the fluctuation is most probably unequal crossing-over and/or unequal sister chromatid exchange, as judged by the Gaussian distribution of the gene counts. By definition, an increase in gene number on one locus should be accompanied by a decrease on the other locus in unequal sequence exchange. The results suggest that copy-number lability may be more common among gene families than previously thought. The chicken avidin gene family also provides an excellent model for studying the mechanisms of recombination and gene conversion.

Generation of heterogeneous rabbit anti-DNP antibodies by gene conversion and hypermutation of rearranged VL and VH genes during clonal expansion of B cells in splenic germinal centers

The mechanisms described here account for development of the heterogeneous high-affinity anti-DNP antibodies that rabbits can produce. Rearranged immunoglobulin light and heavy chain genes from single DNP-specific splenic germinal center B cells were amplified by PCR. We found that in clonal lineages, rearranged V[kappa] and V[H] are further diversified by gene conversion and somatic hypermutation. The positive and negative selection of amino acids in complementarity-determining regions observed allows emergence of a variety of different combining site structures. A by-product of the germinal center reaction may be cells with sequences altered by gene conversion that no longer react with the immunizing antigen but are a source of new repertoire. The splenic germinal center would thus play an additional role in adults similar to that of the appendix and other gut-associated lymphoid tissues of young rabbits.

Gene conversion-like missense mutations in the human cationic trypsinogen gene and insights into the molecular evolution of the human trypsinogen family

Over the past decade, gene conversion has been shown increasingly to be a cause of human disease. Through this process, a functional gene is converted into a mutant by a homologous, nonfunctional one. In this article, we demonstrate that gene conversion is a likely cause of the mutations of the human cationic trypsinogen (PRSS1) gene that are associated with hereditary or sporadic pancreatitis, including the R122H (CGC>CAT: c.365-366 GC>AT), N29I (AAC>ATC: c.86A>T), and A16V (GCC>GTC: c.47C>T) missense mutations. This hypothesis is strongly supported by four lines of observation. First, human group I trypsinogen genes are tandemly repeated and share a high sequence homology between them. Secondly, a possible donor sequence for each variant is present in the PRSS1 gene's paralog(s). Thirdly, there exist uninterrupted sequence tracts ranging from 30 to 114 bp in the putatively converted regions. Finally, Chi-like and palindromic sequences are found in the vicinity of these missense mutations. This theory, if correct, will make the pancreatitis-associated PRSS1 mutations a unique example, as it shows that a functional gene may be converted by several paralogs, and that such an event may even occur between two functional genes (i.e., the N29I mutation), resulting in disease. This adds further to the diversity of genetic mechanisms underlying human disease. In addition, this genetic finding provides, for the first time, concrete evidence of the contribution made by gene conversion to the molecular evolution of the human trypsinogen family.

Gene-conversion in rabbit B-cell ontogeny and during immune responses in splenic germinal centers

Combinatorial diversity is limited in rabbits because only a few V(H) genes rearrange. Most diversification of the primary repertoire is generated by somatic hypermutation and gene conversion-like changes of rearranged V(H) in B cells that migrate to appendix and other gut associated lymphoid tissues (GALT) of young rabbits. The changes are referred to as gene conversion-like because the non-reciprocal nature of the alterations introduced has not yet been demonstrated. There are many similarities between rabbits and chickens in how their B cells develop and diversify their repertoires. However, although the majority of rabbit B cells may have rearranged and diversified their V genes early in life, some B cells in adult rabbits have rearranged VH sequences that are identical or nearly identical to germline sequences. We found these cells in splenic germinal centers (GC) on days 7 and 10 after immunization of normal adult rabbits with DNP-BGG. By day 15, all rearranged V(H) sequences were diversified. We find an overall pattern of splenic precursor cells whose germline or near germline sequences change both by gene conversion and point mutations during early divisions and mainly by point mutations during later divisions. These events, in parallel with diversification of light chain sequences, may produce the diverse combining sites that serve as substrates for further affinity maturation by selection either within GC or later among emigrant cells in sites such as bone marrow. Some of the sequences altered by gene conversion in splenic germinal centers may also produce new members of the B-cell repertoire in adult rabbits comparable to those produced in GALT of neonatal rabbits.

Gene Conversion and Hypermutation During Diversification of VH Sequences in Developing Splenic Germinal Centers of Immunized Rabbits

The young rabbit appendix and the chicken bursa of Fabricius are primary lymphoid organs where the B cell Ab repertoire develops in germinal centers (GCs) mainly by a gene conversion-like process. In human and mouse, V-gene diversification by somatic hypermutation in GCs of secondary lymphoid organs leads to affinity maturation. We asked whether gene conversion, somatic hypermutation, or both occur in rabbit splenic GCs during responses to the hapten DNP. We determined DNA sequences of rearranged heavy and light chain V region gene segments in single cells from developing DNP-specific GCs after immunization with DNP-bovine γ-globulin and conclude that the changes at the DNA level that may lead to affinity maturation occur by both gene conversion and hypermutation. Selection was suggested by finding some recurrent amino acid replacements that may contribute increased affinity for antigen in the complementarity-determining region sequences of independently evolved clones, and a narrower range of complementarity-determining region 3 lengths at day 15. Some of the alterations of sequence may also lead to new members of the B cell repertoire in adult rabbits comparable with those produced in gut associated lymphoid tissues of young rabbits.

Co-existence of somatic hypermutation and gene conversion in hypervariable regions of single Igkappa clones

In the rabbit, recent investigations have provided evidence that gene conversion leads to the generation of diversity of heavy chain rearranged VH-DH-JH genes. No data have been published on a similar mechanism for rabbit light chains. In our laboratory, we initially infected rabbits with Trypanosoma brucei, which stimulates B-cell hyperplasia and hypergammaglobulinaemia. The heterozygous rabbits exhibited the Ckappa1 b4 and b9 kappa light chain allotypes. After reverse transcription of mRNA, and cloning and sequencing of cDNA, the Vkappa-Jkappa-Ckappa genes provided evidence for both somatic hypermutation and gene conversion. We saw that in each of the b4 and b9 kappa light chain cDNA, CDR1 and CDR3 carried both point mutation and provisional gene conversion traits. In the CDR2 region, point mutation and gene conversion inserts were observed in the b4 genes, with only gene conversion in two b9 genes. In the CDR regions, although some genes exhibited only somatic hypermutation or gene conversion, others showed linkage of both somatic hypermutation and gene conversion in the same sequence. This also marks the first time that somatic hypermutation and gene conversion in the same cloned CDR region has been observed in Vkappa1 genes; however, it has been seen earlier in rabbit heavy chain VH sequences. Furthermore, the addition of several codons to the CDR3 segment by gene conversion may have provided a mechanism for length variation. In addition, we demonstrated that Jkappa and framework region segments contained examples of somatic hypermutation. Confirmation of gene conversion necessitates that donor sequences be identified as providing the templated inserts. Thus after cloning two pseudogenes we found putative CDR3 donor segments for two CDR3 rearranged genes. The results offer additional mechanisms for the generation of diversity among rearranged rabbit kappa light chain genes. Whether there is a relationship or influence of gene conversion upon somatic hypermutation or vice versa is not discernable at present.

A unifying hypothesis for the molecular mechanism of somatic mutation and gene conversion in rearranged immunoglobulin variable genes

We have reviewed available data concerning the mechanism of somatic hypermutation in rearranged variable genes of Ig in B lymphocytes of mice and the gene conversion process which generates diversity in these genes in the B lymphocytes of chickens. In our view, these data are consistent with a unifying hypothesis of diversity generating mechanisms involving reverse transcription to produce cDNA from RNA transcripts followed by homologous recombination into chromosomal DNA. Thus, seemingly different processes in the mouse and chicken may have a common molecular basis.

Somatic diversification of IgH genes in rabbit

Rabbits have helped elucidate one of the major immunologic puzzles, namely the genetic control of antibody diversity. The primary IgH antibody repertoire in rabbits is dominated by B cells that use the same germline VH-gene segment in VDJ gene rearrangements. The VDJ genes of essentially all B lymphocytes undergo somatic diversification within the first few weeks of the rabbit's life. Such diversification occurs both by a somatic gene conversion-like mechanism as well as by somatic hyperpointmutation. The diversification that occurs early in ontogeny takes place in gut-associated lymphoid tissues and potentially depends on external factors such as microbial antigens. Few, if any, new B lymphocytes develop in adult rabbits and we discuss how the antibody repertoire is maintained throughout life. Finally, we discuss the molecular mechanism of somatic gene conversion of Ig genes, including the possibility that this involves the use of RAD51, an enzyme required for gene conversion-mediated mating type switch in yeast.

Evolution of somatic hypermutation and gene conversion in adaptive immunity

Examples of somatic hypermutation of antigen receptor genes can be seen in most lineages of vertebrates, including the cartilaginous fish. Analysis of the phylogenetic data reveals that two distinctive features of the mechanism are shared by most species studied: the mutation hot spot sequence AGY, and a preponderance of point mutations. These data suggest that some of the components of the machinery are shared between ectotherms and mammals. However, unique characters in particular species may have occurred by independent recruitment of novel factors onto the mechanism. A spotty phylogenetic distribution of gene conversion has also been revealed and can be explained if the two mechanisms share some characteristics. Both mutation and conversion require transcription-related sequences and/or factors. We theorized that targeting to V genes can be attained by a paused replication fork that has collided with a transcription complex stalled by a defective Ig transcription activator; the paused replication fork results in recruitment of an error-prone translesion synthesis DNA polymerase (somatic hypermutation) or of DNA repair mechanisms with homologous recombination (gene conversion). In addition, the pathway recruited in different species may be directed by the degree of homology among V genes.

The signature of somatic hypermutation appears to be written into the germline IgV segment repertoire

We present here a unifying hypothesis for the molecular mechanism of somatic hypermutation and somatic gene conversion in IgV genes involving reverse transcription using RNA templates from the V-gene loci to produce cDNA which undergoes homologous recombination with chromosomal V(D)J DNA. Experimental evidence produced over the last 20 years is essentially consistent with this hypothesis. We also review evidence suggesting that somatically generated IgV sequences from B lymphocytes have been fed back to germline DNA over evolutionary time.

The antigen-binding characteristics of mAbs derived from in vivo priming of avian B cells

In most vertebrates, a primary antibody repertoire is created through the recombination of a diverse set of Ig variable (V), diversity (D), and joining (J) gene segments. In contrast, an avian immune repertoire is generated by gene conversion of rearranged Ig genes during B cell development within the bursa of Fabricius, a lymphoid organ unique to birds. To investigate the properties of antigen-specific Igs created through the process of gene conversion, we have developed a system for the production of avian-derived mAbs. This system was used to produce multiple antibodies after a single immunization with a conserved peptide from the human cystic fibrosis transmembrane conductance regulator gene. Each antibody isolated was found to have arisen independently through a distinct series of gene conversion events. These primary antibodies displayed evidence of diversity in all of the complementarity determining regions of both heavy and light chains, and both the heavy and the light chains contributed to antigen specificity. In the light chains, diversity could be attributed to gene conversion events. The measured affinity constants of two of the antibodies were between 10(8) and 10(9) M-1, and the antibodies were functional in quantitative ELISA as well as immunohistochemical studies of cystic fibrosis transmembrane conductance regulator expression. These data demonstrate that antigen-specific antibodies produced by Ig gene conversion display both high affinity and specificity. In addition, the methods developed here provide the description of a system for the production of mAbs derived from a nonmammalian species.

Avian B cell development

Development of B cells in chickens proceeds via a series of discrete developmental stages that includes the maturation of committed B cell progenitors in the specialized microenvironment of the bursa of Fabricius. The bursa has been shown to be required for the amplification of the B cell pool and selects for cells with productive immunoglobulin rearrangement events. Other events regulating chicken B cell development such as lymphocyte trafficking and apoptosis are just beginning to be elucidated. Within the bursa, the variable regions of immunoglobulin genes of B cell progenitors are diversified by a process of intrachromosomal gene conversion, where blocks of sequence information are transferred from pseudo-V regions to the recombined variable regions of the immunoglobulin genes. Recently gene conversion has been determined to play a role in the diversification of the immune repertoire in other species. In this review we focus on the current understanding and recent advances of B cell development in the chicken.

Somatic hypermutagenesis in immunoglobulin genes. III. Somatic mutations in the chicken light chain locus

We report a new approach based on the Monte Carlo method, to analyze gene conversion. With this, we have examined 235 somatic mutations in the chicken Vlambda gene and found that about 75% of somatic mutations significantly correlated with donor sequences in 25 pseudo Vlambda genes (set C) versus about 25% that did not (set N). The RGYW and TAA consensus sequences of mutational hotspots were earlier revealed in mammalian V genes. Analysis for correlation between somatic mutations in the Vlambda gene and the consensus sequences showed that the somatic mutations of set N were correlating with the consensus sequences (P(W < Wrandom) < 0.01) and the somatic mutations of set C were not. Based on further statistical analysis, we suggest that there must be at least two mechanisms responsible for somatic hypermutagenesis in the Vlambda gene: gene conversion and another, which accounts for the elevated frequencies of somatic mutations at the RGYW and TAA consensus sequences.

The molecular basis of somatic hypermutation of immunoglobulin genes

Somatic hypermutation amplifies the variable region repertoire of immunoglobulin genes. Recent experimental evidence has thrown light on various molecular models of somatic hypermutation. A link between somatic hypermutation and transcription coupled DNA repair is shaping up.

Isolation and characterization of the chicken trypsinogen gene family

Based on genomic Southern hybridizations and cDNA sequence analyses, the chicken trypsinogen gene family can be divided into two multi-member subfamilies, a six-member trypsinogen I subfamily which encodes the cationic trypsin isoenzymes and a three-member trypsinogen II subfamily which encodes the anionic trypsin isoenzymes. The chicken cDNA and genomic clones containing these two subfamilies were isolated and characterized by DNA sequence analysis. The results indicated that the chicken trypsinogen genes encoded a signal peptide of 15 to 16 amino acid residues, an activation peptide of 9 to 10 residues and a trypsin of 223 amino acid residues. The chicken trypsinogens contain all the common catalytic and structural features for trypsins, including the catalytic triad His, Asp and Ser and the six disulphide bonds. The trypsinogen I and II subfamilies share approximately 70% sequence identity at the nucleotide and amino acid level. The sequence comparison among chicken trypsinogen subfamily members and trypsin sequences from other species suggested that the chicken trypsinogen genes may have evolved in coincidental or concerted fashion.

Rabbit IgH sequences in appendix germinal centers: VH diversification by gene conversion-like and hypermutation mechanisms

Although the rabbit IgH locus contains approximately 100 VH genes, the majority of B cells rearrange VH1. To produce a primary repertoire containing a sufficient number of protective antibodies, rearranged VH1-DH-JH sequences may diversify within rabbit B cells in an organ that functions like a chicken bursa, sheep ileal Peyer's patch, or both. It was suggested many years ago that the rabbit appendix could be a bursal equivalent. To reexamine this possibility, we analyzed rearranged heavy chain variable region sequences in B cells from light and dark zones of appendix germinal centers from 6-week-old rabbits. Our findings indicate that antibody diversification occurs by gene conversion-like and somatic hypermutation mechanisms in appendix germinal centers of young rabbits.

cDNA sequence and organization of the immunoglobulin light chain gene of the duck, Anas platyrhynchos

A cDNA was cloned which encoded an immunoglobulin (Ig) light (L) chain of the White Pekin duck. The organization of the variable (V) and constant (C) domains was analyzed by genomic Southern blotting. The duck L chain gene has a similar chromosomal organization to that of the chicken, with a single lambda-like C region and multiple VL, hybridizing elements. The amino acid sequence of the VL region of the White Pekin duck L chain showed 88% identity with the Muscovy duck and 87% identity with the chicken, the JL region showed 92% identity with these species, and the CL region showed 88% identity with Muscovy duck and 66% with chicken. The constraints imposed by the gene-conversion mechanism of generating antibody diversity might account for the similarities of the avian V region sequences.

Defining the genetic origins of three rheumatoid synovium-derived IgG rheumatoid factors

A major diagnostic marker in most rheumatoid arthritis (RA) patients is the rheumatoid factor (RF), an autoantibody that binds to the Fc region of IgG. To delineate the Ig genes and the underlying mechanism for RF production in RA patients, we applied a systematic approach to define the genetic origins of three IgG RFs derived from the synovial fluid of two RA patients. The results show that two of three IgG RF have substantial numbers of somatic mutations in their variable (V) regions, ranging from 13 to 23 mutations over a stretch of 291-313 nucleotides, resulting in a frequency of 4.4-7.8%. However, one IgG RF has only one mutation in each V region. This result indicates that an IgG RF may arise from a germline gene by very few mutations. The mutations occur mainly in the complementarity-determining regions (CDRs), and the mutations in the CDRs often lead to amino acid substitutions. Five of the six corresponding germline V genes have been found to encode either natural autoantibodies or autoantibodies in other autoimmune disorders; and three of the six V genes have been found in fetal liver. Taken together with other results, the data show that (a) several potentially pathogenic RFs in RA patients arise from natural autoantibodies, and (b) only a few mutations are required to convert the natural autoantibodies to IgG RFs.

Gene conversion in the chicken immunoglobulin locus: a paradigm of homologous recombination in higher eukaryotes

Gene conversion was first defined in yeast as a type of homologous recombination in which the donor sequence does not change. In chicken B cells, gene conversion builds the antigen receptor repertoire by introducing sequence diversity into the immunoglobulin genes. Immunoglobulin gene conversion continues at high frequency in an avian leukosis virus induced chicken B cell line. This cell line can be modified by homologous integration of transfected DNA constructs offering a model system for studying gene conversion in higher eukaryotes. In search for genes which might participate in chicken immunoglobulin gene conversion, we have identified chicken counterparts of the yeast RAD51, RAD52, and RAD54 genes. Disruption and overexpression of these genes in the chicken B cell line may clarify their role in gene conversion and gene targeting.

Polymorphism of the functional immunoglobulin variable region genes in the chicken by exchange of sequence with donor pseudogenes

We have isolated a number of new allelic variants of the unique functional genes encoding chicken immunoglobulin heavy and light chain variable regions (VH1 and VL1, respectively). The distribution and nature of nucleotide variation among these and previously identified VH1 and VL1 alleles demonstrates that random point mutations are likely not the predominant cause of allelic variation at these loci. Comparison of the variant nucleotides with sequences from the pseudo-VH and pseudo-VL gene families, which lie 5' to VH1 and VL1, respectively, suggests that the great majority of allelic variants can be accounted for by segmental transfer of sequence from donor pseudogenes into the germ-line VH1 and VL1 genes. These results demonstrate that the chicken VH1 and VL1 genes are susceptible to sequence replacement at the germ-line level as well as somatically during antibody diversification. The limited repertoire of B cell specificities produced by gene rearrangement in the chicken has led to speculation that these specificities may play a critical role in the progression of chicken B cell development. The results presented here do not support this hypothesis since many of the allelic variant nucleotides described here encode non-conservative amino acid substitutions within the antigen-binding sites of the Ig molecule.

A theory of the ontogeny of the chicken humoral immune system: the consequences of diversification by gene hyperconversion and its extension to rabbit

The immune system's repertoire is generated in two stages: Stage I results in a small size high copy number repertoire that is diversified by "mutation" to result in a large size low copy number repertoire referred to as Stage II. The Stage I or high copy number repertoire is derived from information stored directly in the genome by two mechanisms. (a) The copy-cassette mechanism: the Ig-locus has one rearrangeable V gene segment which acts as recipient for controlled gene conversion in cis from a set of donor V gene segments that results in a family of subunits, L and H. This is illustrated by the avian systems. (b) The cassette-exchange mechanism: the Ig-locus has many rearrangeable V gene segments which are fused into transcription units, the products of which are a family of L and H subunits identical in function to those resulting from the copy-cassette mechanism. This is illustrated by the murine or human systems. It is possible for a species to use both mechanisms, copy-cassette at one Ig locus and cassette-exchange at the other Ig locus. This seems to obtain in the rabbit system. Further, it is possible to encode the high copy number repertoire directly in the genome as tandemly repeated rearranged transcription units as one sees in shark (a genomic analogue of the cassette-exchange mechanism). We have discussed here and elsewhere (Cohn and Langman, 1990) the consequences of these mechanisms for haplotype exclusion and functional responsiveness to antigen. The Stage I or high copy number repertoire generated by any of the above mechanisms is now a substrate for "mutation" which generates the low copy number or Stage II repertoire. These three species are compared in table V. The high copy number repertoire is small but the response to any antigen that it recognizes is rapid. The low copy number repertoire is large but responsiveness to any antigen it recognizes is slow. Cooperativity between the two repertoires optimizes the overall responsiveness with respect to rapidity of response and range of responsiveness. The use of a copy-cassette mechanism requires that the phi B cell undergoing gene conversion have a single rearranged L- and H-chain haplotype (L+/oH+/o). The reason is that conversion can correct an aberrantly rearranged transcription unit and generate an unacceptable level of doubles. In order to have one chromosome functionally rearranged and the homologue in the germline configuration, a selection mechanism is required.(ABSTRACT TRUNCATED AT 400 WORDS)

A chicken RAD51 homologue is expressed at high levels in lymphoid and reproductive organs

Comparisons of the amino acid sequences of three yeast RecA-like proteins, Rad51 and DMC1 from S.cerevisiae and Rad51 from S.pombe, revealed several highly conserved regions. Degenerated oligonucleotides encoding two of these regions were used for the polymerase chain reaction to clone a chicken RecA-like gene. The encoded protein shares 68% and 49% identical amino acids with the Rad51 and DMC1 proteins. The strong sequence conservation between the yeast and chicken genes indicates that RecA homologues are conserved throughout evolution from prokaryotes to higher eukaryotes. High expression of the chicken Rad51 gene was found within the organs of lymphoid and germ cell development suggesting its involvement in lymphoid and meiotic recombination.

Germ line maintenance of the pseudogene donor pool for somatic immunoglobulin gene conversion in chickens

Somatic immunoglobulin diversity is generated in avian species by sequential gene conversion of variable (V) gene segments of the immunoglobulin heavy- and light-chain loci during B-cell development. The germ line pools of donor sequence information for somatic V-region gene conversion are found in families of V pseudogenes, located 5' of the single functional V gene of each locus. The sequence relationships among the pseudogenes (psi VL) and functional VL1 gene of the chicken light-chain alleles in three inbred strains were compared to determine the extent of diversity within the germ line pseudogene cluster. Numerous differences were observed. For example, compared with the previously reported CB allele and the G4 allele, the S3 allele contains two intact pseudogenes between psi VL16 and psi VL18. These two adjacent psi VL gene segments (psi VL17a and psi VL17b) could have given rise to the psi VL17 segment of the G4 and CB alleles by homologous recombination. The majority of other sequence polymorphisms among the psi VL alleles appear to be the result of meiotic gene conversion. The incidence of untemplated mutations within psi VL segments is significantly lower than the incidence of mutation within the pseudogene flanking regions. Together with the observations that most psi VL segments have open reading frames and lack stop codons, these data support the hypothesis that the psi VL cluster resembles a functional multigene family maintained by evolutionary selection for its functional role in generating somatic antibody diversity. Meiotic gene conversion events within the psi VL cluster serve both to introduce diversity by the exchange of short segments between family members and to prevent the accumulation of random mutations.