Templated insertions at VD and DJ junctions create unique B-cell receptors in the healthy B-cell repertoire.

RAG complexes recognise (cryptic) RSS sites both in and outside immunoglobulin sites. Excision circles may be reinserted into V(D)J rearrangements as long templated insertions to diversify the adaptive immune repertoire. We show that such VDJ with templated insertions are incidentally found in the repertoire of healthy donors.

Expression and purification of swine RAG2 in E. coli for production of porcine RAG2 polyclonal antibodies.

Recombination activating gene 2 (RAG2) is necessary for immature B cell differentiation. Antibodies to human and rabbit RAG2 are currently commercially available, but antibodies to swine RAG remain unavailable to date. In this study, the swine RAG2 genes sequence was synthesized and then cloned into a pET-28a vector. The recombinant fusion protein was successfully expressed in E. coli, purified through nickel column chromatography, and further digested with Tobacco Etch Virus protease. The cleaved protein was purified by molecular-exclusion chromatography and named pRAG2. We used pRAG2 to immunize rabbits, collected the serum and purified rabbit anti-pRAG2 polyclonal antibodies. The rabbit anti-pRAG2 polyclonal antibodies were tested via immunofluorescence on eukaryotic cells overexpressing pRAG2 and also able to recognize pig natural RAG2 and human RAG2 protein in western blotting. These results indicated that the prepared rabbit anti-pRAG2 polyclonal antibodies may serve as a tool to detect immature B cell differentiation of swine.

The Ties that Bind (the Igh Locus).

Immunoglobulin heavy-chain locus V(D)J recombination requires a 3D chromatin organization which permits widely distributed variable (V) gene segments to contact distant diversity (D) and joining (J) gene segments. A recent study has identified key nodes in the locus interactome, paving the way for new molecular insights into how the locus is configured for recombination.

Novel molecular mechanism for generating NK-cell fitness and memory.

The mammalian immune system has been traditionally subdivided into two compartments known as the innate and the adaptive. T cells and B cells, which rearrange their antigen-receptor genes using the RAG recombinase, comprise the adaptive arm of immunity. Meanwhile, every other white blood cell has been grouped together under the broad umbrella of innate immunity, including NK cells. NK cells are considered innate lymphocytes because of their rapid responses to stressed cells and their ability to develop without receptor gene rearrangement (i.e. in RAG-deficient mice). However, new findings implicate a critical function for RAG proteins during NK-cell ontogeny, and suggest a novel mechanism by which controlled DNA breaks during NK-cell development dictate the fitness, function, and longevity of these cells. This review highlights recent work describing how DNA break events can impact cellular differentiation and fitness in a variety of cell types and settings.

Accumulation of B1-like B cells in transgenic mice over-expressing catalytically inactive RAG1 in the periphery.

During their development, B lymphocytes undergo V(D)J recombination events and selection processes that, if successfully completed, produce mature B cells expressing a non-self-reactive B-cell receptor (BCR). Primary V(D)J rearrangements yield self-reactive B cells at high frequency, triggering attempts to remove, silence, or reprogramme them through deletion, anergy induction, or secondary V(D)J recombination (receptor editing), respectively. In principle, expressing a catalytically inactive V(D)J recombinase during a developmental stage in which V(D)J rearrangement is initiated may impair this process. To test this idea, we generated transgenic mice expressing a RAG1 active site mutant (dnRAG1 mice); RAG1 transcript was elevated in splenic, but not bone marrow, B cells in dnRAG1 mice relative to wild-type mice. The dnRAG1 mice accumulate splenic B cells with a B1-like phenotype that exhibit defects in B-cell activation, and are clonally diverse, yet repertoire restricted with a bias toward Jκ1 gene segment usage. The dnRAG1 mice show evidence of impaired B-cell development at the immature-to-mature transition, immunoglobulin deficiency, and poorer immune responses to thymus-independent antigens. Interestingly, dnRAG1 mice expressing the anti-dsDNA 3H9H56R heavy chain fail to accumulate splenic B1-like cells, yet retain peritoneal B1 cells. Instead, these mice show an expanded marginal zone compartment, but no difference is detected in the frequency of heavy chain gene replacement. Taken together, these data suggest a model in which dnRAG1 expression impairs secondary V(D)J recombination. As a result, selection and/or differentiation processes are altered in a way that promotes expansion of B1-like B cells in the spleen.

The RAG1 V(D)J recombinase/ubiquitin ligase promotes ubiquitylation of acetylated, phosphorylated histone 3.3.

Histone variant H3.3 is associated with transcriptionally active chromatin and accumulates at loci undergoing preparation for V(D)J recombination, a DNA rearrangement required for the assembly of antigen receptors and development of B and T lymphocytes. Here we demonstrate that the RAG1 V(D)J recombinase protein promotes ubiquitylation of H3.3 that has been heavily acetylated and phosphorylated on serine 31 (acetyl-H3.3 S31p). A fragment of RAG1 promoted formation of a mono-ubiquitylated H3 product that was identified using mass spectrometry as ubiquitylated acetyl-H3.3 S31p. H3 was ubiquitylated at multiple lysine residues, and correspondingly, di-, tri- and higher-order ubiquitylated products were detected at low levels. Ubiquitylation was dependent on an intact RAG1 RING finger/ubiquitin ligase domain and required additional regions of the RAG1 amino terminus that are likely to interact with H3. Acetylated residues within the H3 amino terminal tail were also required. Purified, recombinant H3.1 and H3.3 were not good substrates, suggesting that post-translational modifications enhance recognition by RAG1. A complex including damage-DNA binding protein has also been shown to ubiquitylate H3 in response to UV treatment, suggesting the H3 ubiquitylation may be a common step in multiple DNA repair pathways.

The origins of the Rag genes--from transposition to V(D)J recombination.

The recombination activating genes 1 and 2 (Rag1 and Rag2) encode the key enzyme that is required for the generation of the highly diversified antigen receptor repertoire central to adaptive immunity. The longstanding model proposed that this gene pair was acquired by horizontal gene transfer to explain its abrupt appearance in the vertebrate lineage. The analyses of the enormous amount of sequence data created by many genome sequencing projects now provide the basis for a more refined model as to how this unique gene pair evolved from a selfish DNA transposon into a sophisticated DNA recombinase essential for immunity.

Molecular analysis of T-B-NK+ severe combined immunodeficiency and Omenn syndrome cases in Saudi Arabia.

BACKGROUND: Children with Severe Combined Immunodeficiency (SCID) lack autologous T lymphocytes and present with multiple infections early in infancy. Omenn syndrome is characterized by the sole emergence of oligoclonal auto-reactive T lymphocytes, resulting in erythroderma and enteropathy. Omenn syndrome (OS) shares the genetic aetiology of T-B-NK+ SCID, with mutations in RAG1, RAG2, or DCLRE1C. METHODS: Patients diagnosed with T-B-NK+ SCID or phenotypes suggestive of Omenn syndrome were investigated by molecular genetic studies using gene tightly linked microsatellite markers followed by direct sequencing of the coding regions and splice sites of the respective candidate genes. RESULTS: We report the molecular genetic basis of T-B-NK+ SCID in 22 patients and of OS in seven patients all of Arab descent from Saudi Arabia. Among the SCID patients, six (from four families) displayed four homozygous missense mutations in RAG1 including V433M, R624H, R394W, and R559S. Another four patients (from three familes) showed 3 novel homozygous RAG2 mutations including K127X, S18X, and Q4X; all of which predict unique premature truncations of RAG2 protein. Among Omenn patients, four (from two families) have S401P and R396H mutations in RAG1, and a fifth patient has a novel I444M mutation in RAG2. Seven other patients (six SCID and one OS) showed a gross deletion in exons 1-3 in DCLRE1C. Altogether, mutations in RAG1/2 and DCLRE1C account for around 50% and 25%, respectively, in our study cohort, a proportion much higher than in previous reported series. Seven (24%) patients lack a known genetic aetiology, strongly suggesting that they carry mutations in novel genes associated with SCID and Omenn disorders that are yet to be discovered in the Saudi population. CONCLUSION: Mutation-free patients who lack a known genetic aetiology are likely to carry mutations in the regulatory elements in the SCID-causing genes or in novel genes that are yet to be discovered. Our efforts are underway to investigate this possibility by applying the whole genome scans on these cases via the use of Affymetrix high density DNA SNP chips in addition to homozygosity mapping.

RAG: a recombinase diversified.

During B cell and T cell development, the lymphoid-specific proteins RAG-1 and RAG-2 act together to initiate the assembly of antigen receptor genes through a series of site-specific somatic DNA rearrangements that are collectively called variable-diversity-joining (V(D)J) recombination. In the past 20 years, a great deal has been learned about the enzymatic activities of the RAG-1-RAG-2 complex. Recent studies have identified several new and exciting regulatory functions of the RAG-1-RAG-2 complex. Here we discuss some of these functions and suggest that the RAG-1-RAG-2 complex nucleates a specialized subnuclear compartment that we call the 'V(D)J recombination factory'.

The roles of the RAG1 and RAG2 "non-core" regions in V(D)J recombination and lymphocyte development.

The enormous repertoire of the vertebrate specific immune system relies on the rearrangement of discrete gene segments into intact antigen receptor genes during the early stages of B-and T-cell development. This V(D)J recombination is initiated by a lymphoid-specific recombinase comprising the RAG1 and RAG2 proteins, which introduces double-strand breaks in the DNA adjacent to the coding segments. Much of the biochemical research into V(D)J recombination has focused on truncated or "core" fragments of RAG1 and RAG2, which lack approximately one third of the amino acids from each. However, genetic analyses of SCID and Omenn syndrome patients indicate that residues outside the cores are essential to normal immune development. This is in agreement with the striking degree of conservation across all vertebrate classes in certain non-core domains. Work from multiple laboratories has shed light on activities resident within these domains, including ubiquitin ligase activity and KPNA1 binding by the RING finger domain of RAG1 and the recognition of specific chromatin modifications as well as phosphoinositide binding by the PHD module of RAG2. In addition, elements outside of the cores are necessary for regulated protein expression and turnover. Here the current state of knowledge is reviewed regarding the non-core regions of RAG1 and RAG2 and how these findings contribute to our broader understanding of recombination.

Resolution of unique Sca-1highc-Kit- lymphoid-biased progenitors in adult bone marrow.

We have identified a distinctive lymphoid-restricted progenitor population in adult mouse bone marrow based on a unique c-Kit(-)Sca-1(high)Flt3(+) AA4(+) surface phenotype. These cells are highly lymphoid biased and rapidly generate B and T cells after adoptive transfer. However, whereas previously described lymphoid progenitors such as common lymphoid progenitors express TdT and relatively high levels of RAG2, and are enriched for cells with an active V(D)J recombinase, Flt3(+) AA4(+) cells within the c-Kit(-)Sca-1(high) bone marrow fraction are TdT(-), are RAG2(low), and do not display evidence for ongoing or past recombinase activity. Furthermore, unlike common lymphoid progenitors that readily generate B cells upon stimulation with IL-7, c-Kit(-)Sca-1(high)Flt3(+) precursors do not express abundant levels of the IL-7R, and require costimulation with Flt3 ligand and IL-7 to generate B cells in vitro. Moreover, these findings suggest that hematopoietic stem cells in adults generate an array of lymphoid-biased progenitor populations characterized by distinct gene expression and cytokine response profiles.

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.

Cis-regulatory elements and epigenetic changes control genomic rearrangements of the IgH locus.

Immunoglobulin variable region exons are assembled from discontinuous variable (V), diversity (D), and joining (J) segments by the process of V(D)J recombination. V(D)J rearrangements of the immunoglobulin heavy chain (IgH) locus are tightly controlled in a tissue-specific, ordered and allele-specific manner by regulating accessibility of V, D, and J segments to the recombination activating gene proteins which are the specific components of the V(D)J recombinase. In this review we discuss recent advances and established models brought forward to explain the mechanisms underlying accessibility control of V(D)J recombination, including research on germline transcripts, spatial organization, and chromatin modifications of the immunoglobulin heavy chain (IgH) locus. Furthermore, we review the functions of well-described and potential new cis-regulatory elements with regard to processes such as V(D)J recombination, allelic exclusion, and IgH class switch recombination.

The evolutionary history of lymphoid organs.

Lymphoid organs are important regulators of lymphocyte development and immune responses. During vertebrate evolution, primary lymphoid organs appeared earlier than secondary lymphoid organs. Among the sites of primary lymphopoiesis during evolution and ontogeny, those for B cell differentiation have differed considerably, although they often have had myelolymphatic characteristics. In contrast, only a single site for T cell differentiation has occurred, exclusively the thymus. Based on those observations and the known features of variable-diversity-joining gene recombination, we propose a model for the successive specification of different lymphocyte lineages during vertebrate evolution. According to our model, T cells were the first lymphocytes to acquire variable-diversity-joining-type receptors, and the thymus was the first lymphoid organ to evolve in vertebrates to deal with potentially autoreactive, somatically diversified T cell receptors.

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.

Regulation of V(D)J recombination.

Adaptive immunity is intimately linked to the expression of antigen-specific immunoglobulin and T cell receptor genes and their recombination assembly from germline V, D and J gene segments. This developmentally regulated process relies on the activity of the Rag1-Rag2 recombinase, on accessibility of target gene segments and on monoallelic gene activation. Recent studies have revealed new mechanisms that, along with recombinase activity and locus accessibility, are likely to contribute to the control of V(D)J recombination, including target-site bias by the recombinase, RNA processing and chromosome positioning.

The phylogenetic origins of the antigen-binding receptors and somatic diversification mechanisms.

The adaptive immune system arose in ancestors of the jawed vertebrates approximately 500 million years ago. Homologs of immunoglobulins (Igs), T-cell antigen receptors (TCRs), major histocompatibility complex I (MHC I) and MHC II, and the recombination-activating genes (RAGs) have been identified in all extant classes of jawed vertebrates; however, no definitive homolog of any of these genes has been identified in jawless vertebrates or invertebrates. RAG-mediated recombination and associated junctional diversification of both Ig and TCR genes occurs in all jawed vertebrates. In the case of Igs, somatic variation is expanded further through class switching, gene conversion, and somatic hypermutation. Although the identity of the 'primordial' receptor that was interrupted by the recombination mechanism in jawed vertebrates may never be established, many different families of genes that exhibit predicted characteristics of such a receptor have been described both within and outside the jawed vertebrates. Recent data from various model systems point toward a continuum of immune receptor diversity, encompassing many different families of recognition molecules whose functions are integrated in an organism's response to pathogenic invasion. Various approaches, including both genomic and protein-functional analyses, currently are being applied in jawless vertebrates, protochordates, and other invertebrate deuterostome systems and may yield definitive evidence regarding the presence or absence of adaptive immune homologs in species lacking adaptive immune systems. Such studies have the potential for uncovering previously unknown mechanisms of generating receptor diversity.

V(D)J recombination: how to tame a transposase.

Since the discovery that the recombination-activating gene (RAG) proteins were capable of transposition in vitro, investigators have been trying to uncover instances of transposition in vivo and understand how this transposase has been harnessed to do useful work while being inhibited from causing deleterious chromosome rearrangements. How to preserve the capacity of the recombinase to promote a certain class of rearrangements while curtailing its ability to catalyze others is an interesting problem. In this review, we examine the progress that has been made toward understanding the regulatory mechanisms that prohibit transposition in order to formulate a model that takes into account the diverse observations that have been made over the last 15 years. First, we touch on the striking mechanistic similarities between transposition and V(D)J recombination and review evidence suggesting that the RAG proteins may be members of the retroviral integrase superfamily. We then dispense with an old theory that certain standard products of V(D)J recombination called signal joints protect against deleterious transposition events. Finally, we discuss the evidence that target capture could serve a regulatory role and close with an analysis of hairpins as preferred targets for RAG-mediated transposition. These novel strategies for harnessing the RAG transposase not only shed light on V(D)J recombination but also may provide insight into the regulation of other transposases.

New concepts in the regulation of an ancient reaction: transposition by RAG1/RAG2.

The lymphoid-specific factors, recombination-activating gene 1 (RAG1) and RAG2, initiate V(D)J recombination by introducing DNA double-stand breaks at specific sites in the genome. In addition to this critical endonuclease activity, the RAG proteins catalyze other chemical reactions that can affect the outcome of V(D)J recombination, one of which is transposition. While the transposition activity of the RAG proteins is thought to have been critical for the evolution of modern antigen-receptor loci, it has also been proposed to contribute to chromosomal translocations and lymphoid malignancy. A major challenge has been to determine how the transposition activity of the RAG proteins is regulated in vivo. Although a variety of mechanisms have been suggested by recent studies, a clear resolution of this issue remains elusive.

Ligand-independent tonic signaling in B-cell receptor function.

The random and inherently imprecise process of V(D)J recombination is the foundation for generation of the B-cell receptor (BCR). Signals must be generated to trigger selective processes that retain cells expressing a functional BCR, and these signals must be antigen-independent to insure an unbiased and diverse pool of newly formed B cells. Moreover, BCR expression, and presumably signaling, is essential for the continued survival of the B cell. Although BCR signaling is generally thought to depend upon ligand-induced aggregation, recent studies argue that some aspects of BCR signaling occur independently of antigen, and, furthermore, these non-induced or 'tonic' signals are linked to specific cellular processes operating at multiple stages of B-cell development. The potential co-existence of tonic and induced signaling suggests a unique aspect of BCR complexes, or at least an aspect of receptors that has previously been under-appreciated.