Conservation of sequence in recombination signal sequence spacers

Early steps of V(D)J rearrangement: insights from biochemical studies of RAG-RSS complexes

V(D)J recombination is initiated by the synapsis and cleavage of a complementary (12/23) pair of recombination signal sequences (RSSs) by the RAG1 and RAG2 proteins. Our understanding of these processes has been greatly aided by the development of in vitro biochemical assays of RAG binding and cleavage activity. Accumulating evidence suggests that synaptic complex assembly occurs in a step-wise manner and that the RAG proteins catalyze RSS cleavage by mechanisms similar to those used by bacterial transposases. In this chapter we will review the molecular mechanisms of RAG synaptic complex assembly and 12/23-regulated RSS cleavage, focusing on recent advances that shed new light on these processes.

An activation-induced cytidine deaminase-independent mechanism of secondary VH gene rearrangement in preimmune human B cells

V(H) replacement is a form of IgH chain receptor editing that is believed to be mediated by recombinase cleavage at cryptic recombination signal sequences (cRSS) embedded in V(H) genes. Whereas there are several reports of V(H) replacement in primary and transformed human B cells and murine models, it remains unclear whether V(H) replacement contributes to the normal human B cell repertoire. We identified V(H)-->V(H)(D)J(H) compound rearrangements from fetal liver, fetal bone marrow, and naive peripheral blood, all of which involved invading and recipient V(H)4 genes that contain a cryptic heptamer, a 13-bp spacer, and nonamer in the 5' portion of framework region 3. Surprisingly, all pseudohybrid joins lacked the molecular processing associated with typical V(H)(D)J(H) recombination or nonhomologous end joining. Although inefficient compared with a canonical recombination signal sequences, the V(H)4 cRSS was a significantly better substrate for in vitro RAG-mediated cleavage than the V(H)3 cRSS. It has been suggested that activation-induced cytidine deamination (AICDA) may contribute to V(H) replacement. However, we found similar secondary rearrangements using V(H)4 genes in AICDA-deficient human B cells. The data suggest that V(H)4 replacement in preimmune human B cells is mediated by an AICDA-independent mechanism resulting from inefficient but selective RAG activity.

The beyond 12/23 restriction is imposed at the nicking and pairing steps of DNA cleavage during V(D)J recombination

The beyond 12/23 (B12/23) rule ensures inclusion of a Dbeta gene segment in the assembled T-cell receptor (TCR) beta variable region exon and is manifest by a failure of direct Vbeta-to-Jbeta gene segment joining. The restriction is enforced during the DNA cleavage step of V(D)J recombination by the recombination-activating gene 1 and 2 (RAG1/2) proteins and the recombination signal sequences (RSSs) flanking the TCRbeta gene segments. Nothing is known about the step(s) at which DNA cleavage is defective or how TCRbeta locus sequences contribute to these defects. To address this, we examined the steps of DNA cleavage by the RAG proteins using TCRbeta locus V, D, and J RSS oligonucleotide substrates. The results demonstrate that the B12/23 rule is enforced through slow nicking of Jbeta substrates and to some extent through poor synapsis of Vbeta and Jbeta substrates. Nicking is controlled largely by the coding flank and, unexpectedly, the RSS spacer, while synapsis is controlled primarily by the RSS nonamer. The results demonstrate that different Jbeta substrates are crippled at different steps of cleavage by distinct combinations of defects in the various DNA elements and strongly suggest that the DNA nicking step of V(D)J recombination can be rate limiting in vivo.

Ancestry influences the fate of duplicated genes millions of years after polyploidization of clawed frogs (Xenopus)

Allopolyploid species form through the fusion of two differentiated genomes and, in the earliest stages of their evolution, essentially all genes in the nucleus are duplicated. Because unique mutations occur in each ancestor prior to allopolyploidization, duplicate genes in these species potentially are not interchangeable, and this could influence their genetic fates. This study explores evolution and expression of a simple duplicated complex--a heterodimer between RAG1 and RAG2 proteins in clawed frogs (Xenopus). Results demonstrate that copies of RAG1 degenerated in different polyploid species in a phylogenetically biased fashion, predominately in only one lineage of closely related paralogs. Surprisingly, as a result of an early deletion of one RAG2 paralog, it appears that in many species RAG1/RAG2 heterodimers are composed of proteins that were encoded by unlinked paralogs. If the tetraploid ancestor of extant species of Xenopus arose through allopolyploidization and if recombination between paralogs was rare, then the genes that encode functional RAG1 and RAG2 proteins in many polyploid species were each ultimately inherited from different diploid progenitors. These observations are consistent with the notion that ancestry can influence the fate of duplicate genes millions of years after duplication, and they uncover a dimension of natural selection in allopolyploid genomes that is distinct from other genetic phenomena associated with polyploidization or segmental duplication.

Use of IGHJ and IGHD gene mutations in analysis of immunoglobulin sequences for the prognosis of chronic lymphocytic leukemia

The level of somatic point mutation in immunoglobulin genes is an important prognostic indicator for patients with chronic lymphocytic leukemia (CLL). Mutation analysis presently focuses solely upon the heavy chain IGHV gene, however mutation is a stochastic process that also targets IGHD and IGHJ genes. Here, we evaluate the completeness and reliability of the reported IGHJ gene repertoire, and demonstrate the likely consequences of the inclusion of IGHD and IGHJ mutations in CLL analysis, using a dataset of 607 sequences. Inclusion of these mutations would lead to the re-classification of many sequences, which should significantly improve the prognostic value of mutation analysis.

Hypothesis: a biological role for germline transcription in the mechanism of V(D)J recombination--implications for initiation of allelic exclusion

The sequences that encode the antigen-binding sites of IgH and IgL chains - variable (V), diversity (D, H chain loci only) and joining (J) sequences - are configured as separate DNA segments at the germline level. Expression of an Ig molecule requires V(D)J assembly. Productive V(D)J recombination is monoallelic. How rearrangement is initiated differentially at maternal and paternal alleles is unclear. The products of recombination activating gene (RAG)1 and RAG2 mediate rearrangement by cleaving the DNA between an unrearranged gene segment and adjacent recombination signal sequences (RSS). It is proposed that supercoiling generated during germline transcription at Ig loci (which occurs concomitantly with rearrangement) is required at RSS for RAG1/2 recognition. Rearrangement might hence initiate sequentially at maternal and paternal alleles where deregulated germline transcription causes RAG1/2 recognition of RSS to become stochastic.

Biochemistry of V(D)J recombination

The genes that encode immunoglobulin and T cell receptor proteins are assembled from component gene segments in a reaction known as V(D)J recombination. The reaction, and its crucial mediators RAG1 and RAG2, are essential for lymphocyte development and hence for adaptive immunity. Here we consider the biochemistry of this reaction, focusing on the DNA transactions and the proteins involved. We discuss how the RAG proteins interact with DNA and how coordinate cleavage of the DNA at two sites might be achieved. Finally, we consider the RAG proteins and V(D)J recombination from an evolutionary point of view.

Genomic organization of the sheep TRG1@ locus and comparative analyses of Bovidae and human variable genes

gammadelta T cells commonly account for 0.5%-5% of human (gammadelta low species) circulating T cells, whereas they are very common in chickens, and they may account for >70% of peripheral cells in ruminants (gammadelta high species). We have previously reported the ovine TRG2@ locus structure, the first complete physical map of any ruminant animal TCR locus. Here we determined the TRG1@ locus organization in sheep, reported all variable (V) gamma gene segments in their germline configuration and included human and cattle sequences in a three species comparison. The TRG1@ locus spans about 140 kb and consists of three clusters named TRG5, TRG3, and TRG1 according to the constant (C) genes. The predicted tertiary structure of cattle and sheep V proteins showed a remarkably high degree of conservation between the experimentally determined human Vgamma9 and the proteins belonging to TRG5 Vgamma subgroup. However systematic comparison of primary and tertiary structure highligthed that in Bovidae the overall conformation of the gammadelta TCR, is more similar to the Fab fragment of an antibody than any TCR heterodimer. Phylogenetic analysis showed that the evolution of cattle and sheep V genes is related to the rearrangement process of V segments with the relevant C, and consequentely to the appartenence of the V genes to a given cluster. The TRG cluster evolution in cattle and sheep pointed out the existence of a TRG5 ancient cluster and the occurrence of duplications of its minimal structural scheme of one V, two joining (J), and one C.

Comparative analyses of sheep and human TRG joining regions: evolution of J genes in Bovidae is driven by sequence conservation in their promoters for germline transcription

The availability of genomic clones representative of the T cell receptor gamma (TRG1@ and TRG2@) ovine loci enabled us to compare the germline genomic organization and nucleotide diversity of joining (J) segments and reconstruct their evolutionary history by phylogenetic analysis of cattle, sheep and human expressed sequences. Expression profiling (RT-PCR data) in fetus and adult indicated that only the ovine J genes in which two or more of the key sequence features, such as recombination signal sequences (RSS), 3' splice sites, and core sequences, are missing or severely altered fail to be transcribed. Comparative genomic examination of the two human with the six sheep germline transcription promoters located at 5' of the relevant constant (C)-distal J segments showed a strong conservation of the redundant STAT consensus motifs, indicating that TRG1@ and TRG2@ loci are under the influence of IL-7 and STAT signalling. These findings support the phylogenetic analysis of human and Bovidae (cattle and sheep) that revealed a different grouping pattern of C-distal compared to C-proximal J segments. Likewise, the phylogenetic behaviour of either C-distal and C-proximal J segments is in accordance with the Bovidae TRG clusters evolution. Comparison of sheep and human structures of recombination signal sequences (RSS) has highlighted a greater conservation in sheep 12 RSS rather than 23 RSS thus suggesting that the initial recruitment of recombination activating genes (RAG) products requires at least one relatively high-affinity RSS per recombination event.

The recombination difference between mouse kappa and lambda segments is mediated by a pair-wise regulation mechanism

In mice, kappa light chains dominate over lambda in the immunoglobulin repertoire by as much as 20-fold. Although a major contributor to this difference is the recombination signal sequences (RSS), the mechanism by which RSS cause differential representation has not been determined. To elucidate the mechanism, we tested kappa and lambda RSS flanked by their natural 5' and 3' flanks in three systems that monitor V(D)J recombination. Using extra-chromosomal recombination substrates, we established that a kappa RSS and its flanks support six- to nine-fold higher levels of recombination than a lambda counterpart. In vitro cleavage assays with these same sequences demonstrated that single cleavage at individual kappa or lambda RSS (plus flanks) occurs with comparable frequencies, but that a pair of kappa RSS (plus flanks) support significantly higher levels of double cleavage than a pair of lambda RSS (plus flanks). Using EMSA with double stranded oligonucleotides containing the same kappa or lambda RSS and their respective flanks, we examined RAG/DNA complex formation. We report that, surprisingly, RAG-1/2 form only modestly higher levels of complexes on individual 12 and 23 kappa RSS (plus natural flanks) as compared to their lambda counterparts. We conclude that the overuse of kappa compared to lambda segments cannot be accounted for by differences in RAG-1/2 binding nor by cleavage at individual RSS but rather could be accounted for by enhanced pair-wise cleavage of kappa RSS by RAG-1/2. Based on the data presented, we suggest that the biased usage of light chain segments is imposed at the level of synaptic RSS pairs.

RAG1 core and V(D)J recombination signal sequences were derived from Transib transposons

The V(D)J recombination reaction in jawed vertebrates is catalyzed by the RAG1 and RAG2 proteins, which are believed to have emerged approximately 500 million years ago from transposon-encoded proteins. Yet no transposase sequence similar to RAG1 or RAG2 has been found. Here we show that the approximately 600-amino acid “core” region of RAG1 required for its catalytic activity is significantly similar to the transposase encoded by DNA transposons that belong to the Transib superfamily. This superfamily was discovered recently based on computational analysis of the fruit fly and African malaria mosquito genomes. Transib transposons also are present in the genomes of sea urchin, yellow fever mosquito, silkworm, dog hookworm, hydra, and soybean rust. We demonstrate that recombination signal sequences (RSSs) were derived from terminal inverted repeats of an ancient Transib transposon. Furthermore, the critical DDE catalytic triad of RAG1 is shared with the Transib transposase as part of conserved motifs. We also studied several divergent proteins encoded by the sea urchin and lancelet genomes that are 25%−30% identical to the RAG1 N-terminal domain and the RAG1 core. Our results provide the first direct evidence linking RAG1 and RSSs to a specific superfamily of DNA transposons and indicate that the V(D)J machinery evolved from transposons. We propose that only the RAG1 core was derived from the Transib transposase, whereas the N-terminal domain was assembled from separate proteins of unknown function that may still be active in sea urchin, lancelet, hydra, and starlet sea anemone. We also suggest that the RAG2 protein was not encoded by ancient Transib transposons but emerged in jawed vertebrates as a counterpart of RAG1 necessary for the V(D)J recombination reaction.

RAG1 and RAG2 activity is central to adaptive immunity, but the precise evolutionary origins of these proteins were unknown; the authors argue that RAG1 evolved from the Transib family of transposons.

V(D)J recombination of chromosomally integrated, wild-type deletional and inversional substrates occur at similar frequencies with no preference for orientation

Efficient and correct recombination of V(D)J substrates results in the generation of antibodies. The RSS substrates are oriented in two directions with respect to each other: deletional and inversional. Deletional recombination results in the formation of the coding joint and excision of the intervening sequences. Inversional recombination retains all the genomic sequences and forms both a coding joint and a signal joint. A bias for deletional recombination has been characterized with specific loci in vivo and recapitulated in experiments using extrachromosomal substrates. We constructed retroviral substrates of RSS in the deletional and inversional orientation. We introduced the substrates into wild-type and scid pre-B cells and measured the frequency of functional recombination in addition to open/shut recombination. We also mutated the RSSs to determine whether mutated sequences influenced orientation bias. We show that pre-B cells recombine the wild-type substrates at a 1.6 ratio of deletion:inversion. Nonamer mutated substrates recombined with a deletional bias whereas heptamer mutated substrates recombined with an inversional bias. A spacer length mutation and drastic mutations in the RSS abolish all recombination. These results suggest that there is no orientation bias with wild-type RSSs but that orientation bias occurs when RSSs are mutated.

The bounty of RAGs: recombination signal complexes and reaction outcomes

V(D)J recombination is a form of site-specific DNA rearrangement through which antigen receptor genes are assembled. This process involves the breakage and reunion of DNA mediated by two lymphoid cell-specific proteins, recombination activating genes RAG-1 and RAG-2, and ubiquitously expressed architectural DNA-binding proteins and DNA-repair factors. Here I review the progress toward understanding the composition, assembly, organization, and activity of the protein-DNA complexes that support the initiation of V(D)J recombination, as well as the molecular basis for the sequence-specific recognition of recombination signal sequences (RSSs) that are the targets of the RAG proteins. Parallels are drawn between V(D)J recombination and Tn5/Tn10 transposition with respect to the reactions, the proteins, and the protein-DNA complexes involved in these processes. I also consider the relative roles of the different sequence elements within the RSS in recognition, cleavage, and post-cleavage events. Finally, I discuss alternative DNA transactions mediated by the V(D)J recombinase, the protein-DNA complexes that support them, and factors and forces that control them.

How to keep V(D)J recombination under control

Breaking apart chromosomes is not a matter to be taken lightly. The possible negative outcomes are obvious: loss of information, unstable chromosomes, chromosomal translocations, tumorigenesis, or cell death. Utilizing DNA rearrangement to generate the desired diversity in the antigen receptor loci is a risky business, and it must be carefully controlled. In general, the regulation is so precise that the negative consequences are minimal or not apparent. They are visible only when the process of V(D)J recombination goes awry, as for example in some chromosomal translocations associated with lymphoid tumors. Regulation is imposed not only to prevent the generation of random breaks in the DNA, but also to direct rearrangement to the appropriate locus or subregion of a locus in the appropriate cell at the appropriate time. Antigen receptor rearrangement is regulated essentially at four different levels: expression of the RAG1/2 recombinase, intrinsic biochemical properties of the recombinase and the cleavage reaction, the post-cleavage /DNA repair stage of the process, and accessibility of the substrate to the recombinase. Within each of these broad categories, multiple mechanisms are used to achieve the desired aims. The major focus of this review is on accessibility control and the role of chromatin and nuclear architecture in achieving this regulation, although other issues are touched upon.

Analysis of recombination signal sequences in zebrafish

Recombination signal sequences (RSS) from immunoglobulin and TCRalpha genes of zebrafish were analyzed in comparison with RSS from human and species-specific features were revealed. In contrast to human RSS, in zebrafish RSS from both V(H) and TCRalpha genes the last nonamer position is not conserved. On the contrary, the fourth nonamer position, which is not conserved in human or mouse is conserved in zebrafish. The 12 bp spacers from human and zebrafish RSS contain 9 bp motif resembling nonamer sequence. Spacers in zebrafish 23 bp RSS from both immunoglobulins and TCRalpha contain 7 bp motif also resembling nonamer sequence while corresponding human sequences do not contain analogous motif. RSS are recognized by RAG1 protein, which also has specific features in teleost suggesting co-evolution of RAG1 with corresponding RSS.

Synapsis of recombination signal sequences located in cis and DNA underwinding in V(D)J recombination

V(D)J recombination requires binding and synapsis of a complementary (12/23) pair of recombination signal sequences (RSSs) by the RAG1 and RAG2 proteins, aided by a high-mobility group protein, HMG1 or HMG2. Double-strand DNA cleavage within this synaptic, or paired, complex is thought to involve DNA distortion or melting near the site of cleavage. Although V(D)J recombination normally occurs between RSSs located on the same DNA molecule (in cis), all previous studies that directly assessed RSS synapsis were performed with the two DNA substrates in trans. To overcome this limitation, we have developed a facilitated circularization assay using DNA substrates of reduced length to assess synapsis of RSSs in cis. We show that a 12/23 pair of RSSs is the preferred substrate for synapsis of cis RSSs and that the efficiency of pairing is dependent upon RAG1-RAG2 stoichiometry. Synapsis in cis occurs rapidly and is kinetically favored over synapsis of RSSs located in trans. This experimental system also allowed the generation of underwound DNA substrates containing pairs of RSSs in cis. Importantly, we found that the RAG proteins cleave such substrates substantially more efficiently than relaxed substrates and that underwinding may enhance RSS synapsis as well as RAG1/2-mediated catalysis. The energy stored in such underwound substrates may be used in the generation of DNA distortion and/or protein conformational changes needed for synapsis and cleavage. We propose that this unwinding is uniquely sensed during synapsis of an appropriate 12/23 pair of RSSs.

Evolution of the variable gene segments and recombination signal sequences of the human T-cell receptor alpha/delta locus

The T-cell receptor (TCR) alpha and delta loci are particularly interesting because of their unique genomic structure, in that the gene segments for each locus are interspersed. The origin of this remarkable gene segment arrangement is obscure. In this report, we investigated the evolution of the TCRalpha and delta variable loci and their respective recombination signal sequences (RSSs). Our phylogenetic analyses divided the alpha and delta variable gene segments into two major groups each with distinguishing motifs in both the framework and complementarity determining regions (CDRs). Sequence analyses revealed that TCRdelta variable segments share similar CDR2 sequences with immunoglobulin light chain variable segments, possibly revealing similar evolutionary histories. Maximum likelihood analysis of the region on Chromosome 14q11.2 containing the loci revealed two possible ancestral TCR alpha/delta variable segments, TRDV2 and TRAV1-1/ 1-2, respectively. Maximum parsimony revealed different evolutionary patterns between the variable segment and RSS of the same variable gene arguing for dissimilar evolutionary origins. Two models could account for this difference: a V(D)J recombination activity involving embedded heptamer-like motifs in the germline genome, or, more plausibly, an unequal sister chromatid crossing-over. Either mechanism would have resulted in increased diversity for the adaptive immune system.

Many levels of control of V gene rearrangement frequency

V, D, and J gene segments rearrange at very different frequencies. As with most biological systems, there are multiple levels of control of V gene recombination frequency, and here we review some of the work from our laboratory that addresses these various control mechanisms. One of the important factors that affect non-random V gene rearrangement frequency is the natural heterogeneity in recombination signal sequences (RSSs). Not only does variation in the heptamer and nonamer affect rearrangement, but variation in the spacer can also dramatically affect recombination. However, there are clearly other factors which control V gene rearrangement, as revealed by the fact that genes with identical RSSs can rearrange at different frequencies in vivo. Some of these other influences most likely affect the earliest stages of control--the change from an inaccessible state to an accessible state. Transcription factors can play a role in inducing these changes. Rearrangement of many VkappaI genes can be induced in a non-lymphoid cell line after ectopic expression of E2A, while neighboring VkappaII and VkappaIII genes do not rearrange, demonstrating that at least one level of control of induction of accessibility occurs at the level of the individual gene. Also, changes in chromatin structure can affect accessibility and might influence individual V gene rearrangement frequency.

Computational tools for understanding sequence variability in recombination signals

The recombination signals (RSs) that guide V(D)J rearrangement are remarkably diverse. In mice, fewer than 16% of RSs carry consensus heptamers and nonamers and none also contain a consensus spacer sequence. It is increasingly clear that this variability regulates recombination: genetic variability in RSs may help enforce allelic exclusion, determine the general nature of antigen receptor repertoires, and mitigate autoreactivity in B lymphocytes. The great diversity of RSs has largely precluded, however, empiric determinations of how RS sequence affects recombination. For example, 4(39) unique 23-RSs are possible or approximately 3 x 10(23) sequences; some 7 x 10(13) unique 23-RSs can be produced just by changes in the spacer. In contrast, the recombination activities of only 100 or so RSs have been measured, and it is unlikely that the activities of even a tiny fraction of extant RSs can be determined. We have addressed the problem of how sequence determines the efficiency of RS templates by generating computational models that describe the correlation structure of mouse RSs. These models successfully predict RS activity and identify functional, cryptic RSs (cRSs). These models permit studies to identify RSs and cRSs for empiric study and constitute a tool useful for understanding RS structure and function.

The B12/23 restriction is critically dependent on recombination signal nonamer and spacer sequences

Ag receptor variable region gene assembly is initiated through the formation of a synaptic complex which minimally includes the recombination-activating gene (RAG) 1/2 proteins and a pair of recombination signals (RSs) flanking the recombining gene segments. RSs are composed of conserved heptamer and nonamer sequences flanking relatively nonconserved spacers of 12 or 23 bp. RSs regulate variable region gene assembly within the context of the 12/23 rule which mandates that recombination only occurs between RSs of dissimilar spacer length. RSs can exert additional constraints on variable region gene assembly beyond imposing spacer length requirements. At a minimum this restriction, termed B12/23, is imposed on the Vbeta to DJbeta rearrangement step by the 5' Dbeta RS and is enforced at or before the DNA cleavage step of the V(D)J recombination reaction. In this study, the components of the 5' Dbeta RS required for enforcing the B12/23 rule are assessed on chromosomal substrates in vivo in the context of normal murine thymocyte development and on extrachromosomal substrates induced to undergo recombination in nonlymphoid cell lines. These analyses reveal that the integrity of the nonamer sequence as well as the highly conserved spacer nucleotides of the 5' Dbeta1 RS are critical for enforcing the B12/23 restriction. These findings have important implications for understanding the B12/23 restriction and the manner in which RS synaptic complexes are assembled in vivo.

V(D)J Recombination Frequencies Can Be Profoundly Affected by Changes in the Spacer Sequence

Each V, D, and J gene segment is flanked by a recombination signal sequence (RSS), composed of a conserved heptamer and nonamer separated by a 12- or 23-bp spacer. Variations from consensus in the heptamer or nonamer at specific positions can dramatically affect recombination frequency, but until recently, it had been generally held that only the length of the spacer, but not its sequence, affects the efficacy of V(D)J recombination. In this study, we show several examples in which the spacer sequence can significantly affect recombination frequencies. We show that the difference in spacer sequence alone of two V(H)S107 genes affects recombination frequency in recombination substrates to a similar extent as the bias observed in vivo. We show that individual positions in the spacer can affect recombination frequency, and those positions can often be predicted by their frequency in a database of RSS. Importantly, we further show that a spacer sequence that has an infrequently observed nucleotide at each position is essentially unable to support recombination in an extrachromosmal substrate assay, despite being flanked by a consensus heptamer and nonamer. This infrequent spacer sequence RSS shows only a 2-fold reduction of binding of RAG proteins, but the in vitro cleavage of this RSS is approximately 9-fold reduced compared with a good RSS. These data demonstrate that the spacer sequence should be considered to play an important role in the recombination efficacy of an RSS, and that the effect of the spacer occurs primarily subsequent to RAG binding.

Immunoglobulin gene rearrangement, repertoire diversity, and the allergic response

The immunoglobulin repertoire arises as a consequence of combinatorial diversity, junctional diversity, and the process of somatic point mutation. Each of these processes involves biases that limit and shape the available immunoglobulin repertoire. The expressed repertoire is further shaped by selection, to the extent that biased gene usage can become apparent in many disease states. The study of rearranged immunoglobulin genes therefore may not only provide insights into the molecular processes involved in the generation of antibody diversity but also inform us of pathogenic processes and perhaps identify particular lymphocyte clones as therapeutic targets. Partly as a consequence of the low numbers of circulating IgE-committed B-cells, studies of rearranged IgE genes in allergic individuals have commenced relatively recently. In this review, recent advances in our understanding of the processes of immunoglobulin gene rearrangement and somatic point mutation are described, and biases inherent to these processes are discussed. The evidence that some diseases may be associated with particular gene rearrangements is then considered, with a particular focus on allergic disease. Reviewed data suggest that an important contribution to the IgE response may come from cells that use relatively rare heavy chain V (V(H)) segment genes, which display little somatic point mutation. Some IgE antibodies also seem to display polyreactive binding. In other contexts, these 3 characteristics have been associated with antibodies of the B-1 B-cell subset, and the possibility that B-1 B-cells contribute to the allergic response is therefore considered.

A functional analysis of the spacer of V(D)J recombination signal sequences

During lymphocyte development, V(D)J recombination assembles antigen receptor genes from component V, D, and J gene segments. These gene segments are flanked by a recombination signal sequence (RSS), which serves as the binding site for the recombination machinery. The murine Jbeta2.6 gene segment is a recombinationally inactive pseudogene, but examination of its RSS reveals no obvious reason for its failure to recombine. Mutagenesis of the Jbeta2.6 RSS demonstrates that the sequences of the heptamer, nonamer, and spacer are all important. Strikingly, changes solely in the spacer sequence can result in dramatic differences in the level of recombination. The subsequent analysis of a library of more than 4,000 spacer variants revealed that spacer residues of particular functional importance are correlated with their degree of conservation. Biochemical assays indicate distinct cooperation between the spacer and heptamer/nonamer along each step of the reaction pathway. The results suggest that the spacer serves not only to ensure the appropriate distance between the heptamer and nonamer but also regulates RSS activity by providing additional RAG:RSS interaction surfaces. We conclude that while RSSs are defined by a "digital" requirement for absolutely conserved nucleotides, the quality of RSS function is determined in an "analog" manner by numerous complex interactions between the RAG proteins and the less-well conserved nucleotides in the heptamer, the nonamer, and, importantly, the spacer. Those modulatory effects are accurately predicted by a new computational algorithm for "RSS information content." The interplay between such binary and multiplicative modes of interactions provides a general model for analyzing protein-DNA interactions in various biological systems.

Effect of CpG methylation on RAG1/RAG2 reactivity: implications of direct and indirect mechanisms for controlling V(D)J cleavage

It has been suggested that DNA methylation/demethylation is involved in regulating V(D)J rearrangement. Although methylated DNA is thought to induce an inaccessible chromatin structure, it is unclear whether DNA methylation can directly control V(D)J recombination independently of chromatin structure. In this study, we tested whether DNA methylation directly affects the reactivity of the RAG1/RAG2 complex. Specific methylation within the heptamer of the recombination signal sequences (RSS) markedly reduced V(D)J cleavage without inhibiting RAG1/RAG2-DNA complex formation. By contrast, methylation at other positions around the RSS did not affect the reactivity of the RAG proteins. The presence of a methyl-CpG binding-domain protein inhibited the binding of the RAG1/RAG2 complex to all the methylated CpG sites that were tested. Our findings suggest that DNA methylation around the RSS may have a previously unexpected function in regulating V(D)J recombination by directly inhibiting V(D)J cleavage, in addition to its general function of inducing an inaccessible chromatin configuration.

Evolutionarily conserved pattern of gene segment usage within the mammalian TCRbeta locus

Antigen receptor gene rearrangement is mediated by interactions between the VDJ recombinase and the recombination signal sequences that flank the antigen receptor gene segments. In this report I present phylogenetic analyses that suggest a remarkable evolutionary conservation of the recombination signal sequences flanking some of the orthologous T-cell receptor-beta locus gene segments between human and mouse. Comparison of published data on the usage of the same gene segments between human and mouse indicates similar conservation in the shape of the primary T-cell receptor-beta repertoire. I propose that interactions between the recombinase and its cognate recognition sequences play a hitherto underestimated role in the formation of the specific pattern of the primary, combinatorial antigen receptor repertoire and that this pattern appears to be conserved in diverse mammalian species. Generation of a conserved pattern of the primary T-cell receptor repertoire may be critical for efficient selection of immature T lymphocytes.

Evolution of TRG clusters in cattle and sheep genomes as drawn from the structural analysis of the ovine TRG2@ locus

The availability of genomic clones representative of the T-cell receptor constant gamma (TRGC) ovine genes enabled us to demonstrate, by fluorescent in situ hybridization (FISH) on cattle and sheep metaphases, the presence of two T-cell receptor gamma (TRG1@ and TRG2@) paralogous loci separated by at least five chromosomal bands on chromosome 4. Only TRG1@ is included within a region of homology with human TRG locus on chromosome 7, thus TRG2@ locus appears to be peculiar to ruminants. The structure of the entire TRG2@ locus, the first complete physical map of any ruminant animal TCR gamma locus, is reported here. The TRG2@ spans about 90 kb and consists of three clusters that we named TRG6, TRG2, and TRG4, according to the constant genes name. Phylogenetic analysis has highlighted the correlation between the grouping pattern of cattle and sheep variable gamma (TRGV) genes and the relevant TRGC; variable (V), joining (J), and constant (C) rearrange to be found together in mature transcripts. The simultaneous results on the TRG2@ locus molecular organization in sheep and on the phylogenetic analysis of cattle and sheep V expressed sequences indicate that at least six TRG clusters distributed in the two loci are present in these ruminant animals. The inferred evolution of TRG clusters in cattle and sheep genomes is consistent with a scenario where a minimal ancient cluster, containing the basic structural scheme of one V, one J, and one C gene, has undergone a process of duplication and intrachromosomal transposition.

The central domain of core RAG1 preferentially recognizes single-stranded recombination signal sequence heptamer

RAG1 and RAG2 initiate V(D)J recombination by introducing DNA double strand breaks between each selected gene segment and its bordering recombination signal sequence (RSS) in a two-step mechanism in which the DNA is first nicked, followed by hairpin formation. The RSS consists of a conserved nonamer and heptamer sequence, in which the latter borders the site of DNA cleavage. A region within RAG1, referred to as the central domain (residues 528-760 of 1040 in the full-length protein), has been shown previously to bind specifically to the double-stranded (ds) RSS heptamer, but with both weak specificity and affinity. However, additional investigations into the RAG1-RSS heptamer interaction are required because the DNA substrate forms intermediate conformations during the V(D)J recombination reaction. These include the nicked and hairpin products, as well as likely base unpairing to produce single-stranded (ss) DNA near the cleavage site. Here, it was determined that although the central domain showed substantially higher binding affinity for ss and nicked versus ds substrate, the interaction with ss RSS was particularly robust. In addition, the central domain bound with greater sequence specificity to the ss RSS heptamer than to the ds form. This study provides important insight into the V(D)J recombination reaction, specifically that significant interaction of the RSS heptamer with RAG1 occurs only after the induction of conformational changes at the RSS heptamer.

The T cell receptor beta locus of the channel catfish, Ictalurus punctatus, reveals unique features

Previously, a series of clonal alloantigen-dependent T cell lines established from the channel catfish revealed distinctly different TCR beta rearrangements. Here, a follow-up study of the junctional diversity of these TCR gene rearrangements focuses on characterization of the genomic organization of the TCRB locus. Surprisingly, a total of 29 JB genes and two substantially different CB genes were identified downstream of a single DB gene. This is in contrast to the situation in mammals, where two clusters of a DB gene, six or seven JB genes, and a CB gene are found in tandem. The catfish CB genes are approximately 36% identical at the amino acid level. All 29 catfish JB gene segments appear functional. Thirteen were used in the 19 cDNAs analyzed, of these eight were used by the 11 catfish clonal alloantigen-dependent T cell lines. As might be expected, CDR3 diversity is enhanced by N-nucleotide additions as well as nucleotide deletions at the V-D and D-J junctions. Taken together, compared with that in mammals, genomic sequencing of the catfish TCR DB-JB-CB region reveals a unique locus containing a greater number of JB genes and two distinct CB genes.

Prospective estimation of recombination signal efficiency and identification of functional cryptic signals in the genome by statistical modeling

The recombination signals (RS) that guide V(D)J recombination are phylogenetically conserved but retain a surprising degree of sequence variability, especially in the nonamer and spacer. To characterize RS variability, we computed the position-wise information, a measure correlated with sequence conservation, for each nucleotide position in an RS alignment and demonstrate that most position-wise information is present in the RS heptamers and nonamers. We have previously demonstrated significant correlations between RS positions and here show that statistical models of the correlation structure that underlies RS variability efficiently identify physiologic and cryptic RS and accurately predict the recombination efficiencies of natural and synthetic RS. In scans of mouse and human genomes, these models identify a highly conserved family of repetitive DNA as an unexpected source of frequent, cryptic RS that rearrange both in extrachromosomal substrates and in their genomic context.

Identification of a new cluster of T-cell receptor delta recombining elements

Within the human T-cell receptor delta (TCRD) gene we have identified a new cluster of seven delta recombining elements (deltaRec2.1-2.7), located 2.6-5.2 kilobases downstream of the Vdelta2 gene segment. The deltaRec2 elements are isolated recombining signal sequences (RSS), which were shown to rearrange with the Ddelta3 and Jdelta1 segments of the TCRD gene as well as with the psiJalpha of the TCRA gene. Rearrangements involving the deltaRec2 elements were found in all peripheral blood (PB) samples from 10 healthy individuals, although their frequency was about 100-fold lower than that of classical deltaRec rearrangements. The total frequency of deltaRec2 rearrangements was lower in PB T lymphocytes, as compared with thymocytes, suggesting that they are deleted during T-cell development. The decrease of the frequency of the deltaRec2-Ddelta3 rearrangements was most prominent: 11 times lower in PB T lymphocytes than in thymocytes. Since the deltaRec2-Jdelta1 rearrangements contained the Ddelta3 segment in the junctional region, we assume that they are derived from the deltaRec2-Ddelta3 rearrangements. In contrast, the majority of deltaRec2-psiJalpha rearrangements did not contain the Ddelta3 segment, indicating that they are single step rearrangements. The deltaRec2-Jdelta1 and deltaRec2-psiJalpha rearrangements seem to be T-lineage specific, but the deltaRec2-Ddelta3 rearrangements were also found at very low frequencies in B lymphocytes and natural killer cells. Our results suggest that deltaRec2 rearrangements are transient steps in the recombinatorial process of the TCRAD locus and are probably deleted by subsequent Valpha-Jalpha rearrangements. We hypothesize, that in a similar manner to the classical deltaRec rearrangements, the deltaRec2 rearrangements might also contribute to T-cell differentiation towards the TCR-alphabeta lineage.

Dramatically increased rearrangement and peripheral representation of Vbeta14 driven by the 3'Dbeta1 recombination signal sequence

V(D)J recombination is targeted by short recombination signal (RS) sequences that are relatively conserved but exhibit natural sequence variations. To evaluate the potential of RS sequence variations to determine the primary and peripheral TCRbeta repertoire, we generated mice containing specific replacement of the endogenous Vbeta14 RS with the 3'Dbeta1 RS (Vbeta14/3'DbetaRS). These mice exhibited a dramatic increase in Vbeta14(+) thymocyte numbers at the expense of thymocytes expressing other Vbetas. In addition, the percentage of peripheral Vbeta14(+) alphabeta T lymphocytes was similarly increased. Strikingly, this altered Vbeta repertoire resulted predominantly from a higher relative level of primary Vbeta14/3'DbetaRS rearrangement to DbetaJbeta complexes, despite the ability of the 3'Dbeta1 RS to break B12/23 restriction and allow direct rearrangement of Vbeta14/3'DbetaRS to Jbeta segments.

Identification and utilization of arbitrary correlations in models of recombination signal sequences

BACKGROUND

A significant challenge in bioinformatics is to develop methods for detecting and modeling patterns in variable DNA sequence sites, such as protein-binding sites in regulatory DNA. Current approaches sometimes perform poorly when positions in the site do not independently affect protein binding. We developed a statistical technique for modeling the correlation structure in variable DNA sequence sites. The method places no restrictions on the number of correlated positions or on their spatial relationship within the site. No prior empirical evidence for the correlation structure is necessary.

RESULTS

We applied our method to the recombination signal sequences (RSS) that direct assembly of B-cell and T-cell antigen-receptor genes via V(D)J recombination. The technique is based on model selection by cross-validation and produces models that allow computation of an information score for any signal-length sequence. We also modeled RSS using order zero and order one Markov chains. The scores from all models are highly correlated with measured recombination efficiencies, but the models arising from our technique are better than the Markov models at discriminating RSS from non-RSS.

CONCLUSIONS

Our model-development procedure produces models that estimate well the recombinogenic potential of RSS and are better at RSS recognition than the order zero and order one Markov models. Our models are, therefore, valuable for studying the regulation of both physiologic and aberrant V(D)J recombination. The approach could be equally powerful for the study of promoter and enhancer elements, splice sites, and other DNA regulatory sites that are highly variable at the level of individual nucleotide positions.

Access roads for RAG-ged terrains: control of T cell receptor gene rearrangement at multiple levels

Antigen-specific immune response requires the generation of a diverse antigen (Ag)-receptor repertoire. The primary repertoire is generated through somatic gene rearrangement and molded by subsequent cellular selection. Constraints during gene recombination influence the ultimate shape of the repertoire. One major control mechanism of gene rearrangement, investigated for many years, is exerted through regulated chromosomal accessibility of the recombinase to the antigen receptor loci. More recent studies began to explore the role of interactions between the recombinase and its cognate recognition DNA sequences. The emerging results suggest that formation of the primary repertoire is controlled by two, partially independent factors: chromosomal accessibility and direct recombinase-DNA interactions.

High frequency of matrix attachment regions and cut-like protein x/CCAAT-displacement protein and B cell regulator of IgH transcription binding sites flanking Ig V region genes

A major component in controlling V(D)J recombination is differential accessibility through localized changes in chromatin structure. Attachment of DNA to the nuclear matrix via matrix attachment region (MAR) sequences, and interaction with MAR-binding proteins have been shown to alter chromatin conformation, promote histone acetylation, and influence gene transcription. In this study, the flanking regions of several human and mouse Ig V(H) and Ig Vkappa genes were analyzed extensively for the presence of MARs by in vitro matrix-binding assay, and for interaction with the MAR-binding proteins cut-like protein x/CCAAT-displacement protein (Cux/CDP), B cell regulator of IgH transcription (Bright), and special AT-rich sequence-binding protein (SATB1) by EMSA. Cux/CDP and SATB1 are associated with repression, while Bright is an activator of Ig transcription. Binding sites were identified in the vicinity of all analyzed Ig V genes, and were also found flanking TCR Vbeta genes. We also show that the binding sites of the different factors do not always occur at MAR sequences. MAR sequences were also found within the Ig V loci at a much higher frequency than throughout the rest of the genome. Overall, the frequency and location of binding sites relative to the coding regions, and the strength of DNA-protein interaction showed much heterogeneity. Thus, variations in factor binding and MAR activity could potentially influence the extent of localized accessibility to V(D)J recombination and thus could play a role in unequal rearrangement of individual V genes. These sites could also contribute to effective transcription of Ig genes in mature and/or activated B cells, bringing both the promoter as well as the enhancer regions into close proximity at the nuclear matrix.

The cleavage efficiency of the human immunoglobulin heavy chain VH elements by the RAG complex: implications for the immune repertoire

The human immunoglobulin heavy chain locus contains 39 functional human V(H) elements. All 39 V(H) elements (with their adjacent heptamer/nonamer signal) were tested for site-specific cleavage with purified human core RAG1 and RAG2, and HMG1 proteins in a 12/23-coupled cleavage reaction. Both nicking and hairpin formation were measured. The individual V(H) cleavage efficiencies vary over nearly a 30-fold range. These measurements will be useful in considering the factors affecting the generation of the immunoglobulin and T-cell receptor repertoires in the adult humans. Interestingly, when these cleavage efficiencies are summed for each of the V(H) families, the six V(H) family efficiencies correspond closely to the observed profile of unselected V(H) family usage in the peripheral B cells of normal adult humans. This correspondence raises the possibility that the dominant factor determining V(H) element utilization within the 1-megabase human genomic V(H) array is simply the individual RAG cleavage efficiencies.

Early death and severe lymphopenia caused by ubiquitous expression of the Rag1 and Rag2 genes in mice

The recombination activating proteins (RAG1 and RAG2) are essential for V(D)J recombination of immunoglobulin chains. Expression of both genes is lymphocyte-specific and RAG levels are tightly regulated throughout lymphopoiesis and cell cycle. To assess the significance of this pattern of expression, we generated transgenic mice expressing the Rag genes both continuously throughout lymphocyte development and constitutively in most non-lymphoid tissues. The transgenes partially complement an endogenous Rag2 null mutation and lead to a partial block in early B and T lymphopoiesis when introduced on a Rag2 sufficient background. The defect in thymocyte number is restricted to the alpha beta lineage leaving the gamma delta T cell pool intact, while neither IgH phenotypic allelic exclusion nor the kappa/lambda light chain ratio are altered. Finally, the ectopic expression of the Rag genes associates with growth retardation and early death of the animals, a phenotype reminiscent of those reported for mice deficient in double-strand break repair molecules.

Novel T-cell receptor delta gene rearrangement involving a recombining element located 2.6 kb 3' from the Vdelta2 gene segment

In this study, we describe a novel T-cell receptor delta (TCRdelta) gene rearrangement observed in acute myeloid leukemia with coexpression of T-lymphoid antigens (Ly+AML) and in peripheral blood leukocytes (PBL) from one out of ten healthy donors. The rearrangement was identified by Southern blot analysis using a joining region (Jdelta1) specific probe and amplified by polymerase chain reaction (PCR) with a variable region (Vdelta2) and Jdelta1 specific primers. The nucleotide sequence analysis of an atypical 3000 bp PCR product allowed localization of the breakpoint within the TCRdelta gene locus, 2.6 kb 3' from the Vdelta2 gene segment. A regular Ddelta2-Ddelta3-Jdelta1 joining was found at the 3' end of the breakpoint, indicating that the rearrangement was mediated by the VDJ recombinase, but no TCRdelta gene segment was detected at the 5' end. Analysis of the germline sequence 3' from the breakpoint revealed an isolated recombination signal sequence (RSS) capable of initiating a rearrangement. The RSS motif described by us is the second TCRdelta recombining element (deltaRec2). The deltaRec2(Ddelta)Jdelta1 recombination is a rather rare event and can be found in acute leukemia and in PBL from healthy individuals. Most likely, the nonfunctional deltaRec2(Ddelta)Jdelta1 rearrangement is a transient step during the VDJ recombination. It may potentially lead to deletion of the deltaRec2(Ddelta)Jdelta1 complex and either to direct joining of a Vdelta region to one of the downstream Jdelta regions or to a rearrangement of the TCRalpha gene.

Comparative genomics of the human and mouse T cell receptor loci

The availability of the complete genomic sequences of the human and mouse T cell receptor loci opens up new opportunities for understanding T cell receptors (TCRs) and their genes. The full complement of TCR gene segments is finally known and should prove a valuable resource for supporting functional studies. A rational nomenclature system has been implemented and is widely available through IMGT and other public databases. Systematic comparisons of the genomic sequences within each locus, between loci, and across species enable precise analyses of the various diversification mechanisms and some regulatory signals. The genomic landscape of the TCR loci provides fundamental insights into TCR evolution as highly localized and tightly regulated gene families.

Unequal VH gene rearrangement frequency within the large VH7183 gene family is not due to recombination signal sequence variation, and mapping of the genes shows a bias of rearrangement based on chromosomal location

Much of the nonrandom usage of V, D, and J genes in the Ab repertoire is due to different frequencies with which gene segments undergo V(D)J rearrangement. The recombination signal sequences flanking each segment are seldom identical with consensus sequences, and this natural variation in recombination signal sequence (RSS) accounts for some differences in rearrangement frequencies in vivo. Here, we have sequenced the RSS of 19 individual V(H)7183 genes, revealing that the majority have one of two closely related RSS. One group has a consensus heptamer, and the other has a nonconsensus heptamer. In vitro recombination substrate studies show that the RSS with the nonconsensus heptamer, which include the frequently rearranging 81X, rearrange less well than the RSS with the consensus heptamer. Although 81X differs from the other 7183-I genes at three positions in the spacer, this does not significantly increase its recombination potency in vitro. The rearrangement frequency of all members of the family was determined in microMT mice, and there was no correlation between the in vitro recombination potential and V(H) gene rearrangement frequency in vivo. Furthermore, genes with identical RSS rearrange at different frequencies in vivo. This demonstrates that other factors can override differences in RSS potency in vivo. We have also determined the gene order of all V(H)7183 genes in a bacterial artificial chromosome contig and show that most of the frequently rearranging genes are in the 3' half of the region. This suggests that chromosomal location plays an important role in nonrandom rearrangement of the V(H)7183 genes.

Biased V beta usage in immature thymocytes is independent of DJ beta proximity and pT alpha pairing

During thymus development, the TCR beta locus rearranges before the TCR alpha locus. Pairing of productively rearranged TCR beta-chains with an invariant pT alpha chain leads to the formation of a pre-TCR and subsequent expansion of immature pre-T cells. Essentially nothing is known about the TCR V beta repertoire in pre-T cells before or after the expression of a pre-TCR. Using intracellular staining, we show here that the TCR V beta repertoire is significantly biased at the earliest developmental stage in which VDJ beta rearrangement has occurred. Moreover (and in contrast to the V(H) repertoire in immature B cells), V beta repertoire biases in immature T cells do not reflect proximity of V beta gene segments to the DJ beta cluster, nor do they depend upon preferential V beta pairing with the pT alpha chain. We conclude that V gene repertoires in developing T and B cells are controlled by partially distinct mechanisms.

Evolution of the recombination signal sequences in the Ig heavy-chain variable region locus of mammals

The Ig and T cell receptor (TCR) loci have an exceptionally dynamic evolutionary history, but the mechanisms responsible remain a subject of speculation. Ig and TCR genes are unique in vertebrates in that they are assembled from V, D, and J segments by site-specific recombination in developing lymphocytes. Here we examine the extent to which the V(D)J recombination in germline cells may have been responsible for remodeling Ig and TCR loci in mammals by asking whether gene segments have evolved as a unit, or whether, instead, recombination signal sequences (RSSs) and coding sequences have different phylogenies. Four distinct types of RSS have been defined in the human Ig heavy-chain variable region (Vh) locus, namely H1, H2, H3, and H5, and no other RSS type has been detected in other mammalian species. There is a well-supported discrepancy between the evolutionary history of the RSSs as compared with the Vh coding sequences: the RSS type H2 of one Vh gene segment has clearly become replaced by a RSS type H3 during mammalian evolution, between 115 and 65 million years ago. Two general models might explain the RSS swap: the first involves an unequal crossing over, and the second implicates germline activation of V(D)J recombination. The Vh-H2/RSS-H3 recombination product has likely been selected during the evolution of mammals because it provides better V(D)J recombination efficiency.

Underutilization of the V kappa 10C gene in the B cell repertoire is due to the loss of productive VJ rearrangements during B cell development

The V kappa10 family of murine light chain Ig genes is composed of three members, two of which (V kappa 10A and V kappa 10B) are well used. V kappa 10C, the third member of this family, is not detected in any expressed Abs. Our previous work showed that V kappa 10C is structurally functional and can recombine, but mRNA levels in spleen were extremely low relative to those of V kappa 10A and V kappa 10B. Furthermore, while the V kappa 10C promoter was efficient in B cells, it was shown to work inefficiently in pre-B cell lines. Here, we extend our analysis of the V kappa 10 family and examine V kappa 10 gene accessibility, their representation in V kappa cDNA phage libraries, and the frequency and nature of rearrangements during different stages of B cell development. We demonstrate that V kappa 10C is under-represented in V kappa cDNA libraries, but that the frequency of its sterile transcripts in pre-B cells surpasses both V kappa 10A and V kappa 10B, indicating that the gene is as accessible as V kappa 10A and V kappa 10B to the recombination machinery. We also demonstrate that V kappa 10C recombines at a frequency equal to that of V kappa 10A in pre-B cells and has a normal nonproductive to productive recombination ratio. As B cells develop, however, both the frequency of V kappa 10C rearrangements and the presence of productive rearrangements decline, indicating that these cells are in some fashion being eliminated.

Postcleavage sequence specificity in V(D)J recombination

Unintended DNA rearrangements in a differentiating lymphocyte can have severe, oncogenic consequences, but the mechanisms for avoiding pathogenic outcomes in V(D)J recombination are not well understood. The first level at which fidelity is instituted is in discrimination by the recombination proteins between authentic and inauthentic recombination signal sequences. Nevertheless, this discrimination is not absolute and cannot fully eliminate targeting errors. To learn more about the basis of specificity during V(D)J recombination, we have investigated whether it is possible for the recombination machinery to detect an inaccurately targeted sequence subsequent to cleavage. These studies indicate that even postcleavage steps in V(D)J recombination are sequence specific and that noncanonical sequences will not efficiently support the resolution of recombination intermediates in vivo. Accordingly, interventions after a mistargeting event conceivably occur at a late stage in the joining process and the likelihood may well be crucial to enforcing fidelity during antigen receptor gene rearrangement.

Recombination signal sequences restrict chromosomal V(D)J recombination beyond the 12/23 rule

The genes encoding the variable regions of lymphocyte antigen receptors are assembled from variable (V), diversity (D) and joining (J) gene segments. V(D)J recombination is initiated by the recombinase activating gene (RAG)-1 and -2 proteins, which introduce DNA double-strand breaks between the V, D and J segments and their flanking recombination signal sequences (RSSs). Generally expressed DNA repair proteins then carry out the joining reaction. The conserved heptamer and nonamer sequences of the RSSs are separated by non-conserved spacers of 12 or 23 base pairs (forming 12-RSSs and 23-RSSs). The 12/23 rule, which is mediated at the level of RAG-1/2 recognition and cutting, specifies that V(D)J recombination occurs only between a gene segment flanked by a 12-RSS and one flanked by a 23-RSS. Vbeta segments are appended to DJbeta rearrangements, with little or no direct Vbeta to Jbeta joining, despite 12/23 compatibility of Vbeta 23-RSSs and Jbeta12-RSSs. Here we use embryonic stem cells and mice with a modified T-cell receptor (TCR)beta locus containing only one Dbeta (Dbeta1) gene segment and one Jbeta (Jbeta1) gene cluster to show that the 5' Dbeta1 12-RSS, but not the Jbeta1 12-RSSs, targets rearrangement of a diverse Vbeta repertoire. This targeting is precise and position-independent. This additional restriction on V(D)J recombination has important implications for the regulation of variable region gene assembly and repertoire development.