Increased frequency of aberrant V(D)J recombination products in core RAG-expressing mice

RAG1 and RAG2 play a central role in V(D)J recombination, a process for antigen receptor gene assembly. The truncated ‘core’ regions of RAGs are sufficient to catalyze the recombination reaction, although with lower joining efficiency than full-length proteins. To investigate the role of the non-core regions of RAGs in the end-joining phase of antigen receptor rearrangement, we analyzed recombination products isolated from core RAG1 and core RAG2 knock-in mice. Here, we report that the truncation of RAGs increases the frequency of aberrant recombination in vivo. Signal joints (SJs) associated with V-to-D recombination of core RAG1 knock-in mice were normal, whereas those of core RAG2 knock-in mice were highly imprecise, containing large deletions and additions, and in some cases coding sequences. In contrast, we found an elevated level of imprecise D-to-J associated SJs for both core RAG1- and RAG2-expressing mice. Likewise, sequences of coding joints (CJs) were also affected by the expression of core RAGs. Finally, sequences found at the junctions of rearranged T-cell receptor loci were highly influenced by differences in rearranging recombination signal sequence pairs. We provide the first evidence that the non-core regions of RAGs have critical functions in the proper assembly and resolution of recombination intermediates in endogenous antigen receptor loci.     

Recombination centres and the orchestration of V(D)J recombination

The initiation of V(D)J recombination by the recombination activating gene 1 (RAG1) and RAG2 proteins is carefully orchestrated to ensure that antigen receptor gene assembly occurs in the appropriate cell lineage and in the proper developmental order. Here we review recent advances in our understanding of how DNA binding and cleavage by the RAG proteins are regulated by the chromatin structure and architecture of antigen receptor genes. These advances suggest novel mechanisms for both the targeting and the mistargeting of V(D)J recombination, and have implications for how these events contribute to genome instability and lymphoid malignancy.     

DNA cleavage of a cryptic recombination signal sequence by RAG1 and RAG2. Implications for partial V(H) gene replacement

Antibody and T cell receptor genes are assembled from gene segments by V(D)J recombination to produce an almost infinitely diverse repertoire of antigen specificities. Recombination is initiated by cleavage of conserved recombination signal sequences (RSS) by RAG1 and RAG2 during lymphocyte development. Recent evidence demonstrates that recombination can occur at noncanonical RSS sites within Ig genes or at other loci, outside the context of normal lymphocyte receptor gene rearrangement. We have characterized the ability of the RAG proteins to bind and cleave a cryptic RSS (cRSS) located within an Ig V(H) gene segment. The RAG proteins bound with sequence specificity to either the consensus RSS or the cRSS. The RAG proteins nick the cRSS on both the top and bottom strands, thereby bypassing the formation of the DNA hairpin intermediate observed in RAG cleavage of canonical RSS substrates. We propose that the RAG proteins may utilize an alternative mechanism for double-stranded DNA cleavage, depending on the substrate sequence. These results have implications for further diversification of the antigen receptor repertoire as well as the role of the RAG proteins in genomic instability.     

Activation of V(D)J recombination induces the formation of interlocus joints and hybrid joints in scid pre-B-cell lines

V(D)J recombination is the mechanism by which antigen receptor genes are assembled. The site-specific cleavage mediated by RAG1 and RAG2 proteins generates two types of double-strand DNA breaks: blunt signal ends and covalently sealed hairpin coding ends. Although these DNA breaks are mainly resolved into coding joints and signal joints, they can participate in a nonstandard joining process, forming hybrid and open/shut joints that link coding ends to signal ends. In addition, the broken DNA molecules excised from different receptor gene loci could potentially be joined to generate interlocus joints. The interlocus recombination process may contribute to the translocation between antigen receptor genes and oncogenes, leading to malignant transformation of lymphocytes. To investigate the underlying mechanisms of these nonstandard recombination events, we took advantage of recombination-inducible cell lines derived from scid homozygous (s/s) and scid heterozygous (s/+) mice by transforming B-cell precursors with a temperature-sensitive Abelson murine leukemia virus mutant (ts-Ab-MLV). We can manipulate the level of recombination cleavage and end resolution by altering the cell culture temperature. By analyzing various recombination products in scid and s/+ ts-Ab-MLV transformants, we report in this study that scid cells make higher levels of interlocus and hybrid joints than their normal counterparts. These joints arise concurrently with the formation of intralocus joints, as well as with the appearance of opened coding ends. The junctions of these joining products exhibit excessive nucleotide deletions, a characteristic of scid coding joints. These data suggest that an inability of scid cells to promptly resolve their recombination ends exposes the ends to a random joining process, which can conceivably lead to chromosomal translocations.     

Receptor editing in lymphocyte development and central tolerance

The specificities of lymphocytes for antigen are generated by a quasi-random process of gene rearrangement that often results in non-functional or autoreactive antigen receptors. Regulation of lymphocyte specificities involves not only the elimination of cells that display 'unsuitable' receptors for antigen but also the active genetic correction of these receptors by secondary recombination of the DNA. As I discuss here, an important mechanism for the genetic correction of antigen receptors is ongoing recombination, which leads to receptor editing. Receptor editing is probably an adaptation that is necessitated by the high probability of receptor autoreactivity. In both B cells and T cells, the genes that encode the two chains of the antigen receptor seem to be specialized to promote, on the one hand, the generation of diverse specificities and, on the other hand, the regulation of these specificities through efficient editing.     

The defect in murine severe combined immune deficiency: joining of signal sequences but not coding segments in V(D)J recombination

Pre-B and pre-T cell lines from mutant mice with severe combined immune deficiency (scid mice) were transfected with plasmids that contained recombination signal sequences of antigen receptor gene elements (V, D, and J). Recovered plasmids were tested for possible recombination of signal sequences and/or the adjacent (coding) sequences. Signal ends were joined, but recombination was abnormal in that half of the recombinants had lost nucleotides from one or both signals. Coding ends were not joined at all in either deletional or inversional V(D)J recombination reactions. However, coding ends were able to participate in alternative reactions. The failure of coding joint formation in scid pre-B and pre-T cells appears sufficient to explain the absence of immunoglobulin or T cell receptor production in scid mice.     

An updated definition of V(D)J recombination signal sequences revealed by high-throughput recombination assays

In the adaptive immune system, V(D)J recombination initiates the production of a diverse antigen receptor repertoire in developing B and T cells. Recombination activating proteins, RAG1 and RAG2 (RAG1/2), catalyze V(D)J recombination by cleaving adjacent to recombination signal sequences (RSSs) that flank antigen receptor gene segments. Previous studies defined the consensus RSS as containing conserved heptamer and nonamer sequences separated by a less conserved 12 or 23 base-pair spacer sequence. However, many RSSs deviate from the consensus sequence. Here, we developed a cell-based, massively parallel assay to evaluate V(D)J recombination activity on thousands of RSSs where the 12-RSS heptamer and adjoining spacer region contained randomized sequences. While the consensus heptamer sequence (CACAGTG) was marginally preferred, V(D)J recombination was highly active on a wide range of non-consensus sequences. Select purine/pyrimidine motifs that may accommodate heptamer unwinding in the RAG1/2 active site were generally preferred. In addition, while different coding flanks and nonamer sequences affected recombination efficiency, the relative dependency on the purine/pyrimidine motifs in the RSS heptamer remained unchanged. Our results suggest RAG1/2 specificity for RSS heptamers is primarily dictated by DNA structural features dependent on purine/pyrimidine pattern, and to a lesser extent, RAG:RSS base-specific interactions.     

Unique and redundant functions of ATM and DNA-PKcs during V(D)J recombination

Lymphocyte antigen receptor genes are assembled through the process of V(D)J recombination, during which pairwise DNA cleavage of gene segments results in the formation of four DNA ends that are resolved into a coding joint and a signal joint. The joining of these DNA ends occurs in G₁-phase lymphocytes and is mediated by the non-homologous end-joining (NHEJ) pathway of DNA double-strand break (DSB) repair. The ataxia telangiectasia mutated (ATM) and the DNA-dependent protein kinase catalytic subunit (DNA-PKcs), two related kinases, both function in the repair of DNA breaks generated during antigen receptor gene assembly. Although these proteins have unique functions during coding joint formation, their activities in signal joint formation, if any, have been less clear. However, two recent studies demonstrated that ATM and DNA-PKcs have overlapping activities important for signal joint formation. Here, we discuss the unique and shared activities of the ATM and DNA-PKcs kinases during V(D)J recombination, a process that is essential for lymphocyte development and the diversification of antigen receptors.Key words: ATM, V(D)J recombination, DNA-PKcs, Lymphocyte, DNA repair, RAG     

Developmental neurobiology: Alternative ends for a familiar story?

Somatic DNA recombination is essential for production of functional antigen receptor genes of T and B lymphocytes, but it is thought to be unique to the immune system. Recent studies have now shown that recombination-related genes are also necessary for normal neuronal development.     

抗原受体基因重组的表观遗传学调控研究新进展

淋巴细胞是哺乳动物唯一能发生体细胞基因组变化的一类细胞,淋巴细胞在发育过程中通过V(D)J重组获得成熟的特异的抗原受体基因,实现了免疫细胞抗原识别惊人的多样性.关于V(D)J重组的调控机制一直是免疫学研究的重要问题,然而直到将表观遗传学研究引入这一领域,综合遗传学和表观遗传学的研究才真正揭示V(D)J重组精细的调控机制.综述了新近发现的V(D)J重组过程中重要的表观遗传学调控机制,如CpG甲基化,组蛋白修饰,核小体重塑及核拓扑学变化.     

Recombination Activating Genes (RAG) in Lymphoma Development

The recombination activating genes (RAG) play a central role in the generation of a diverse immune repertoire by mediating DNA recombination events at antigen receptor loci in developing B and T lymphocytes. However, inappropriate RAG activity throughout the genome has been implicated in a large variety of human and mouse lymphomas. Mechanisms by which RAG can provoke or perpetuate lymphoma include deregulation of certain genes by translocation to antigen receptor regulatory regions, the formation of chimeric oncogenes, inactivation of tumor suppressor or micro-RNA loci, or activation of oncogenes. Here we present the T cell receptor enhancer (Eb) deficient mouse as a tractable in vivo model system to study the role of RAG activity in the context of lymphoma development, and contrast our system with those of others. We posit a general hypothesis that virtually any mutation that impairs early lymphocyte development at stages when RAG is expressed can constitute a pro-carcinogenic event. Our model system provides a means to assess the roles of RAG activity in human lymphoid malignancies.     

Novel strand exchanges in V(D)J recombination

We describe novel products of V(D)J recombination in which signal sequences become joined to coding elements, in contrast to the standard reaction whose products are junctions of two signal sequences or two coding elements. In this variant reaction, the recombination machinery evidently recognizes signal sequences and introduces strand breaks at the normal positions, but then connects the elements in unusual combinations. The lack of fixed directionality indicates that recombination sites are not uniquely aligned when strand exchange occurs. The discovery of these variant junctions suggests a model for the evolution of the antigen receptor loci.     

Evolutionarily conserved pattern of gene segment usage within the mammalian<Emphasis Type="Italic"> TCRβ</Emphasis> 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- 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- 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.     

Joining mutants of RAG1 and RAG2 that demonstrate impaired interactions with the coding-end DNA

In V(D)J joining of antigen receptor genes, two recombination signal sequences (RSSs), 12- and 23-RSSs, form a complex with the protein products of recombination activating genes, RAG1 and RAG2. DNaseI footprinting demonstrates that the interaction of RAG proteins with substrate RSS DNA is not just limited to the signal region but involves the coding sequence as well. Joining mutants of RAG1 and RAG2 demonstrate impaired interactions with the coding region in both pre- and postcleavage type complexes. A possible role of this RAG coding region interaction is discussed in the context of V(D)J recombination.     

Dual role of RAG2 in V(D)J recombination: catalysis and regulation of ordered Ig gene assembly.

Immunoglobulin genes are assembled during lymphoid development by a series of site-specific rearrangements that are tightly regulated to ensure that functional antibodies are generated in B (but not T) cells and that a unique receptor is present on each cell. Because a common V(D)J recombinase comprising RAG1 and RAG2 proteins is used for both B- and T-cell antigen receptor assembly, lineage-specific rearrangement must be modulated through differential access to sites of recombination. We show here that the C-terminus of the RAG2 protein, although dispensable for the basic recombination reaction and for Ig heavy chain DH to JH joining, is essential for efficient VH to DJH rearrangement at the IgH locus. Thus, the RAG2 protein plays a dual role in V(D)J recombination, acting both in catalysis of the reaction and in governing access to particular loci.