In vitro V(D)J recombination: signal joint formation

Measuring protein stoichiometry with single-molecule imaging in Xenopus egg extracts

In human cells, DNA double-strand breaks are rapidly bound by the highly abundant non-homologous end joining (NHEJ) factor Ku70/Ku80 (Ku). Cellular imaging and structural data revealed a single Ku molecule is bound to a free DNA end and yet the mechanism regulating Ku remains unclear. Here, we describe how to utilize the cell-free Xenopus laevis egg extract system in conjunction with single-molecule microscopy to investigate regulation of Ku stoichiometry during non-homologous end joining. Egg extract is an excellent model system to study DNA repair as it contains the soluble proteome including core and accessory NHEJ factors, and efficiently repairs double-strand breaks in an NHEJ-dependent manner. To examine the Ku stoichiometry in the extract system, we developed a single-molecule photobleaching assay, which reports on the number of stable associated Ku molecules by monitoring the intensity of fluorescently labeled Ku molecules bound to double-stranded DNA over time. Photobleaching is distinguishable as step decreases in fluorescence intensity and the number of photobleaching events indicate fluorophore stoichiometry. In this paper we describe sample preparation, experimental methodology, and data analysis to discern Ku stoichiometry and the regulatory mechanism controlling its loading. These approaches can be readily adopted to determine stoichiometry of molecular factors within other macromolecular complexes.

Znc2 module of RAG1 contributes towards structure-specific nuclease activity of RAGs

Recombination activating genes (RAGs), consisting of RAG1 and RAG2 have ability to perform spatially and temporally regulated DNA recombination in a sequence specific manner. Besides, RAGs also cleave at non-B DNA structures and are thought to contribute towards genomic rearrangements and cancer. The nonamer binding domain of RAG1 binds to the nonamer sequence of the signal sequence during V(D)J recombination. However, deletion of NBD did not affect RAG cleavage on non-B DNA structures. In the present study, we investigated the involvement of other RAG domains when RAGs act as a structure-specific nuclease. Studies using purified central domain (CD) and C-terminal domain (CTD) of the RAG1 showed that CD of RAG1 exhibited high affinity and specific binding to heteroduplex DNA, which was irrespective of the sequence of single-stranded DNA, unlike CTD which showed minimal binding. Furthermore, we show that ZnC2 of RAG1 is crucial for its binding to DNA structures as deletion and point mutations abrogated the binding of CD to heteroduplex DNA. Our results also provide evidence that unlike RAG cleavage on RSS, central domain of RAG1 is sufficient to cleave heteroduplex DNA harbouring pyrimidines, but not purines. Finally, we show that a point mutation in the DDE catalytic motif is sufficient to block the cleavage of CD on heteroduplex DNA. Therefore, in the present study we demonstrate that the while ZnC2 module in central domain of RAG1 is required for binding to non-B DNA structures, active site amino acids are important for RAGs to function as a structure-specific nuclease.

Ensemble and Single-Molecule Analysis of Non-Homologous End Joining in Frog Egg Extracts

Non-homologous end joining (NHEJ) repairs the majority of DNA double-strand breaks in human cells, yet the detailed order of events in this process has remained obscure. Here, we describe how to employ Xenopus laevis egg extract for the study of NHEJ. The egg extract is easy to prepare in large quantities, and it performs efficient end joining that requires the core end joining proteins Ku, DNA-PKcs, XLF, XRCC4, and DNA ligase IV. These factors, along with the rest of the soluble proteome, are present at endogenous concentrations, allowing mechanistic analysis in a system that begins to approximate the complexity of cellular end joining. We describe an ensemble assay that monitors covalent joining of DNA ends and fluorescence assays that detect joining of single pairs of DNA ends. The latter assay discerns at least two discrete intermediates in the bridging of DNA ends.

Identification of a novel lymphoid population in the murine epidermis

T cell progenitors are known to arise from the foetal liver in embryos and the bone marrow in adults; however different studies have shown that a pool of T cell progenitors may also exist in the periphery. Here, we identified a lymphoid population resembling peripheral T cell progenitors which transiently seed the epidermis during late embryogenesis in both wild-type and T cell-deficient mice. We named these cells ELCs (Epidermal Lymphoid Cells). ELCs expressed Thy1 and CD2, but lacked CD3 and TCRαβ/γδ at their surface, reminiscent of the phenotype of extra- or intra- thymic T cell progenitors. Similarly to Dendritic Epidermal T Cells (DETCs), ELCs were radioresistant and capable of self-renewal. However, despite their progenitor-like phenotype and expression of T cell lineage markers within the population, ELCs did not differentiate into conventional T cells or DETCs in in vitro, ex vivo or in vivo differentiation assays. Finally, we show that ELC expressed NK markers and secreted IFN-γ upon stimulation. Therefore we report the discovery of a unique population of lymphoid cells within the murine epidermis that appears related to NK cells with as-yet-unidentified functions.

SARS-CoV envelope protein palmitoylation or nucleocapid association is not required for promoting virus-like particle production

BACKGROUND

Coronavirus membrane (M) proteins are capable of interacting with nucleocapsid (N) and envelope (E) proteins. Severe acute respiratory syndrome coronavirus (SARS-CoV) M co-expression with either N or E is sufficient for producing virus-like particles (VLPs), although at a lower level compared to M, N and E co-expression. Whether E can release from cells or E/N interaction exists so as to contribute to enhanced VLP production is unknown. It also remains to be determined whether E palmitoylation or disulfide bond formation plays a role in SARS-CoV virus assembly.

RESULTS

SARS-CoV N is released from cells through an association with E protein-containing vesicles. Further analysis suggests that domains involved in E/N interaction are largely located in both carboxyl-terminal regions. Changing all three E cysteine residues to alanines did not exert negative effects on E release, E association with N, or E enhancement of VLP production, suggesting that E palmitoylation modification or disulfide bond formation is not required for SARS-CoV virus assembly. We found that removal of the last E carboxyl-terminal residue markedly affected E release, N association, and VLP incorporation, but did not significantly compromise the contribution of E to efficient VLP production.

CONCLUSIONS

The independence of the SARS-CoV E enhancement effect on VLP production from its viral packaging capacity suggests a distinct SARS-CoV E role in virus assembly.

Metabolic sensor AMPK directly phosphorylates RAG1 protein and regulates V(D)J recombination

The ability to sense metabolic stress is critical for successful cellular adaptation. In eukaryotes, the AMP-activated protein kinase (AMPK), a highly conserved serine/threonine kinase, functions as a critical metabolic sensor. AMPK is activated by the rising ADP/ATP and AMP/ATP ratios during conditions of energy depletion and also by increasing intracellular Ca(2+). In response to metabolic stress, AMPK maintains energy homeostasis by phosphorylating and regulating proteins that are involved in many physiological processes including glucose and fatty acid metabolism, transcription, cell growth, mitochondrial biogenesis, and autophagy. Evidence is mounting that AMPK also plays a role in a number of pathways unrelated to energy metabolism. Here, we identify the recombination-activating gene 1 protein (RAG1) as a substrate of AMPK. The RAG1/RAG2 complex is a lymphoid-specific endonuclease that catalyzes specific DNA cleavage during V(D)J recombination, which is required for the assembly of the Ig and T-cell receptor genes of the immune system. AMPK directly phosphorylates RAG1 at serine 528, and the phosphorylation enhances the catalytic activity of the RAG complex, resulting in increased cleavage of oligonucleotide substrates in vitro, or increased recombination of an extrachromosomal substrate in a cellular assay. Our results suggest that V(D)J recombination can be regulated by AMPK activation, providing a potential new link between metabolic stress and development of B and T lymphocytes.

APOBEC3G cytidine deaminase association with coronavirus nucleocapsid protein

We previously reported that replacing HIV-1 nucleocapsid (NC) domain with SARS-CoV nucleocapsid (N) residues 2–213, 215–421, or 234–421 results in efficient virus-like particle (VLP) production at a level comparable to that of wild-type HIV-1. In this study we demonstrate that these chimeras are capable of packaging large amounts of human APOBEC3G (hA3G), and that an HIV-1 Gag chimera containing the carboxyl-terminal half of human coronavirus 229E (HCoV-229E) N as a substitute for NC is capable of directing VLP assembly and efficiently packaging hA3G. When co-expressed with SARS-CoV N and M (membrane) proteins, hA3G was efficiently incorporated into SARS-CoV VLPs. Data from GST pull-down assays suggest that the N sequence involved in N–hA3G interactions is located between residues 86 and 302. Like HIV-1 NC, the SARS-CoV or HCoV-229E N-associated with hA3G depends on the presence of RNA, with the first linker region essential for hA3G packaging into both HIV-1 and SARS-CoV VLPs. The results raise the possibility that hA3G is capable of associating with different species of viral structural proteins through a potentially common, RNA-mediated mechanism.

Severe acute respiratory syndrome coronavirus nucleocapsid protein confers ability to efficiently produce virus-like particles when substituted for the human immunodeficiency virus nucleocapsid domain

We replaced the HIV-1 nucleocapsid (NC) domain with different N-coding sequences to test SARS-CoV nucleocapsid (N) self-interaction capacity, and determined the capabilities of each chimera to direct virus-like particle (VLP) assembly. Analysis results indicate that the replacement of NC with the carboxyl-terminal half of the SARS-CoV N resulted in the production of wild type (wt)-level virus-like particles (VLPs) with the density of a wt HIV-1 particle. When co-expressed with SARS-CoV N, chimeras containing the N carboxyl-terminal half sequence efficiently packaged N. However, the same was not true for the chimera bearing the N amino-terminal half sequence, despite its production of substantial amounts of VLPs. According to further analysis, HIV-1 NC replacement with N residues 2–213, 215–421, or 234–421 resulted in efficient VLP production at levels comparable to that of wt HIV-1, but replacement with residues 215–359, 302–421, 2–168, or 2–86 failed to restore VLP production to wild-type levels. The results suggest that the domain conferring the ability to direct VLP assembly and release in SARS-CoV N is largely contained between residues 168 and 421.

Evidence for Ku70/Ku80 association with full-length RAG1

Antigen receptor genes are assembled by a site-specific DNA rearrangement process called V(D)J recombination. This process proceeds through two distinct phases: a cleavage phase in which the RAG1 and RAG2 proteins introduce DNA double-strand breaks at antigen receptor gene segments, and a joining phase in which the resulting DNA breaks are processed and repaired via the non-homologous end-joining (NHEJ) repair pathway. Genetic and biochemical evidence suggest that the RAG proteins play an active role in guiding the repair of DNA breaks introduced during V(D)J recombination to the NHEJ pathway. However, evidence for specific association between the RAG proteins and any of the factors involved in NHEJ remains elusive. Here we present evidence that two components of the NHEJ pathway, Ku70 and Ku80, interact with full-length RAG1, providing a biochemical link between the two phases of V(D)J recombination.

Coding joint diversity in mature and immature B-cell lines

Antigen receptor gene rearrangement is regulated by many factors in B and T lymphocytes. The sequences of the gene segments themselves, their associated recombination signal sequences (RSS), expression of the RAG genes and the chromatin accessibility of the particular gene segments to be rearranged all influence the outcome of recombination and thus antigen receptor diversity. In the present study, we have evaluated the effect of variations in RAG activity level on the junctional diversity of coding joint sequences. Using the pre-B-like 204-1-8 and the mature B DR3 cell lines under different transfection conditions, we were able to investigate recombination activity levels that varied 100-fold. We evaluated the sequences of the coding joints for junctional diversity resulting from nucleotide addition or deletion. Surprisingly, we found that the sequence of coding joints of these recombinants did not exhibit significant variation despite the large difference in recombination frequency. Our results indicate that the fidelity of the joining phase of V(D)J recombination is not jeopardized by varying RAG activity.

In vitro and in vivo studies on the generation of the primary T-cell receptor repertoire

The primary T-cell receptor repertoire is generated by somatic rearrangement of discontinuous gene segments. The shape of the combinatorial repertoire is stereotypical and, in part, evolutionarily conserved among mammals. Rearrangement is initiated by specific interactions between the recombinase and the recombination signals (RSs) that flank the gene segments. Conserved sequence variations in the RS, which modulate its interactions with the recombinase, appear to be a major factor in shaping the primary repertoire. In vitro, biochemical studies have revealed distinct steps in these complex recombinase-RS interactions that may determine the final frequency of gene segment rearrangement. These studies offer a plausible model to explain gene segment selection, but new, more physiological approaches will have to be developed to verify and refine the mechanism by which the recombinase targets the RS in its endogenous chromosomal context in vivo.

Ku70/Ku80 and DNA-dependent Protein Kinase Catalytic Subunit Modulate RAG-mediated Cleavage

The 12/23 rule is a critical step for regulation of V(D)J recombination. To date, only the RAG proteins and high mobility group protein 1 or 2 have been implicated in 12/23 regulation. Through protein fractionation and biochemical experiments, we find that Ku70/Ku80 and DNA-dependent protein kinase catalytic subunit (DNA-PKcs) modulate RAG-mediated cleavage. Modulation of cleavage by Ku70/80 and DNA-PKcs results in preferential inhibition of 12/12 and 23/23 DNA cleavage, thus increasing 12/23 rule specificity. This observation indicates that DNA repair factors, Ku70/80 and DNA-PKcs, might be present upstream of the DNA cleavage events and not recruited downstream as is currently thought, assigning new nonrepair functions to the DNA-dependent protein kinase.

DNA-Rag Protein Interactions in the Control of Selective D Gene Utilization in the TCRβ Locus

Ordered assembly of Ag receptor genes by VDJ recombination is a key determinant of successful lymphocyte differentiation and function. Control of gene rearrangement has been traditionally viewed as a result of complex reorganization of the nucleochromatin mediated by several nuclear factors. Selective recombination of the variable (V) genes to the diversity (D), but not joining (J), gene segments within the TCRbeta locus has been shown to be controlled by recombination signal (RS) sequences that flank the gene segments. Through ex vivo and in vitro recombination assays, we demonstrate that the Rag proteins can discriminate between the RS of the D and J genes and enforce selective D gene incorporation into the TCRbeta variable domain in the absence of other nuclear factors or chromatin structure. DNA binding studies indicate that discrimination is not simply caused by higher affinity binding of the Rag proteins to the isolated 12RS of the D as opposed to the J genes. Furthermore, we also demonstrate that the 12RS within the TCRbeta locus is functionally inferior to the consensus 12RS. We propose that selective gene segment usage is controlled at the level of differential assembly and/or stability of synaptic RS complexes, and that evolutionary "deterioration" of the RS motifs may have been important to allow the VDJ recombinase to exert autonomous control over gene segment use during gene rearrangement.

Biochemical evidence for Ku-independent backup pathways of NHEJ

Cells of higher eukaryotes process within minutes double strand breaks (DSBs) in their genome using a non-homologous end joining (NHEJ) apparatus that engages DNA-PKcs, Ku, DNA ligase IV, XRCC4 and other as of yet unidentified factors. Although chemical inhibition, or mutation, in any of these factors delays processing, cells ultimately remove the majority of DNA DSBs using an alternative pathway operating with an order of magnitude slower kinetics. This alternative pathway is active in mutants deficient in genes of the RAD52 epistasis group and frequently joins incorrect ends. We proposed, therefore, that it reflects an alternative form of NHEJ that operates as a backup (B-NHEJ) to the DNA-PK-dependent (D-NHEJ) pathway, rather than homology directed repair of DSBs. The present study investigates the role of Ku in the coordination of these pathways using as a model end joining of restriction endonuclease linearized plasmid DNA in whole cell extracts. Efficient, error-free, end joining observed in such in vitro reactions is strongly inhibited by anti-Ku antibodies. The inhibition requires DNA-PKcs, despite the fact that Ku efficiently binds DNA ends in the presence of antibodies, or in the absence of DNA-PKcs. Strong inhibition of DNA end joining is also mediated by wortmannin, an inhibitor of DNA-PKcs, in the presence but not in the absence of Ku, and this inhibition can be rescued by pre-incubating the reaction with double stranded oligonucleotides. The results are compatible with a role of Ku in directing end joining to a DNA-PK dependent pathway, mediated by efficient end binding and productive interactions with DNA-PKcs. On the other hand, efficient end joining is observed in extracts of cells lacking DNA-PKcs, as well as in Ku-depleted extracts in line with the operation of alternative pathways. Extracts depleted of Ku and DNA-PKcs rejoin blunt ends, as well as homologous ends with 3' or 5' protruding single strands with similar efficiency, but addition of Ku suppresses joining of blunt ends and homologous ends with 3' overhangs. We propose that the affinity of Ku for DNA ends, particularly when cooperating with DNA-PKcs, suppresses B-NHEJ by quickly and efficiently binding DNA ends and directing them to D-NHEJ for rapid joining. A chromatin-based model of DNA DSB rejoining accommodating biochemical and genetic results is presented and deviations between in vitro and in vivo results discussed.

RAG1 and RAG2 in V(D)J recombination and transposition

RAG1 and RAG2 are the key components of the V(D)J recombinase machinery that catalyses the somatic gene rearrangements of antigen receptor genes during lymphocyte development. In the first step of V(D)J recombination--DNA cleavage--the RAG proteins act together as an endonuclease to excise the DNA between two individual gene segments. They are also thought to be involved in the subsequent DNA joining step. In vitro, the RAG proteins catalyze the integration of the excised DNA element into target DNA completing a process similar to bacterial transposition. In vivo, this reaction is suppressed by an unknown mechanism. The individual roles of RAG1 and RAG2 in V(D)J recombination and transposition reactions are discussed based on mutation analyses and structure predictions.

Ku autoantigen: a multifunctional DNA-binding protein

Ku is a heterodimeric protein composed of approximately 70- and approximately 80-kDa subunits (Ku70 and Ku80) originally identified as an autoantigen recognized by the sera of patients with autoimmune diseases. Ku has high binding affinity for DNA ends and that is why originally it was known as a DNA end binding protein, but now it is known to also bind the DNA structure at nicks, gaps, hairpins, as well as the ends of telomeres. It has been reported also to bind with sequence specificity to DNA and with weak affinity to RNA. Ku is an abundant nuclear protein and is present in vertebrates, insects, yeast, and worms. Ku contains ssDNA-dependent ATPase and ATP-dependent DNA helicase activities. It is the regulatory subunit of the DNA-dependent protein kinase that phosphorylates many proteins, including SV-40 large T antigen, p53, RNA-polymerase II, RP-A, topoisomerases, hsp90, and many transcription factors such as c-Jun, c-Fos, oct-1, sp-1, c-Myc, TFIID, and many more. It seems to be a multifunctional protein that has been implicated to be involved directly or indirectly in many important cellular metabolic processes such as DNA double-strand break repair, V(D)J recombination of immunoglobulins and T-cell receptor genes, immunoglobulin isotype switching, DNA replication, transcription regulation, regulation of heat shock-induced responses, regulation of the precise structure of telomeric termini, and it also plays a novel role in G2 and M phases of the cell cycle. The mechanism underlying the regulation of all the diverse functions of Ku is still obscure.

Definition of minimal domains of interaction within the recombination-activating genes 1 and 2 recombinase complex

During V(D)J recombination, recognition and cleavage of the recombination signal sequences (RSSs) requires the coordinated action of the recombination-activating genes 1 and 2 (RAG1/RAG2) recombinase complex. In this report, we use deletion mapping and site-directed mutagenesis to determine the minimal domains critical for interaction between RAG1 and RAG2. We define the active core of RAG2 required for RSS cleavage as aa 1-371 and demonstrate that the C-terminal 57 aa of this core provide a dominant surface for RAG1 interaction. This region corresponds to the last of six predicted kelch repeat motifs that have been proposed by sequence analysis to fold RAG2 into a six-bladed beta-propeller structure. Residue W317 within this sixth repeat is shown to be critical for mediating contact with RAG1 and concurrently for stabilizing binding and directing cleavage of the RSS. We also show that zinc finger B (aa 727-750) of RAG1 provides a dominant interaction domain for recruiting RAG2. In all, the data support a model of RAG2 as a multimodular protein that utilizes one of its six faces for establishing productive contacts with RAG1.

Multimerization potential of the cytoplasmic domain of the human immunodeficiency virus type 1 transmembrane glycoprotein gp41

We previously demonstrated that an envelope mutant of human immunodeficiency virus type 1 lacking the entire cytoplasmic domain interferes in trans with the production of infectious virus by inclusion of the mutant envelope into the wild-type envelope complex. We also showed that the envelope incorporation into virions is not affected when the wild-type envelope is coexpressed with the mutant envelope. These results suggest that an oligomeric structure of the cytoplasmic domain is functionally required for viral infectivity. To understand whether the cytoplasmic domain of human immunodeficiency virus type 1 transmembrane protein gp41 has the potential to self-assemble as an oligomer, in the present study we fused the coding sequence of the entire cytoplasmic domain at 3' to the Escherichia coli malE gene, which encodes a monomeric maltose-binding protein. The expressed fusion protein was examined by chemical cross-linking, sucrose gradient centrifugation, and gel filtration. The results showed that the cytoplasmic domain of gp41 assembles into a high-ordered structural complex. The intersubunit interaction of the cytoplasmic domain was also confirmed by a mammalian two-hybrid system that detects protein-protein interactions in eucaryotic cells. A cytoplasmic domain fragment expressed in eucaryotic cells was pulled down by glutathione-Sepharose 4B beads via its association with another cytoplasmic domain fragment fused to the C terminus of the glutathione S-transferase moiety. We also found that sequences encompassing the lentiviral lytic peptide-1 and lentiviral lytic peptide-2, which are located within residues 828-856 and 770-795, respectively, play a critical role in cytoplasmic domain self-assembly. Taken together, the results from the present study indicate that the cytoplasmic domain of gp41 by itself is sufficient to assemble into a multimeric structure. This finding supports the hypothesis that a multimeric form of the gp41 cytoplasmic domain plays a crucial role in virus infectivity.

Nonhomologous DNA end joining in cell-free systems

Double strand DNA breaks are usually caused by ionizing radiation and radiomimetic drugs, but can also occur under normal physiological conditions during double strand break-induced recombination, such as the rearrangement of T-cell receptor and immunoglobulin genes during lymphoid development or the mating type switching in yeast. The main repair mechanism for double strand breaks in higher eukaryotes is nonhomologous DNA end joining (NHEJ), which modifies and ligates the two DNA ends without the help of extensive base-pairing interactions for alignment. Defects in double strand break repair are associated with radiosensitivity, predisposition to cancer and immunodeficiency syndromes, and the analysis of the underlying mutations has lead to the identification of several proteins involved in NHEJ. However, these genetic studies have yielded little information on the mechanism of NHEJ, and while some of the protein factors identified possess the expected enzymatic or DNA-binding activities, the precise role of others remains unclear. Systems for cell-free NHEJ have been available for over 10 years, but the biochemical analysis of NHEJ has lagged behind the genetic analysis, and not a single protein factor required for NHEJ has been identified by biochemical purification and reconstitution of NHEJ activity. Here I review the current status of in vitro systems for NHEJ, summarize the results obtained and information gained, and discuss the outlook for biochemical approaches to study NHEJ.

Hereditary stability and variation in evolution and development

Evolution and development are both lineage processes but are often conceptualized as occurring by different and mutually exclusive mechanisms. It is conventionally asserted that evolution occurs via the random generation of diversity and the subsequent survival of those that pass selection. On the other hand, development is too often presented as proceeding via the unfolding of a deterministic program encoded in the DNA sequence. In biology, universal generalizations are rare and dogmas are often wrong for particular cases. Deterministic mechanisms contribute some of the new DNA sequences that subsequently become substrates for natural selection. Conversely, stochastic and selective mechanisms are intrinsic to development, and also to maintenance of the immune, and possibly, nervous systems. Cancer appears to be another process that straddles distinctions between evolutionary and developmental modes of hereditary change and stabilization. DNA sequence changes are an essential feature of many cancers, but there are also aspects of the disease similar to developmental lineage gone awry. The literature suggests that the cellular changes that give rise to cancer occur by mechanisms commonly associated with both evolutionary and developmental lineage pathways.

Ku-dependent nonhomologous DNA end joining in Xenopus egg extracts

An extract from activated Xenopus eggs joins both matching and nonmatching ends of exogenous linear DNA substrates with high efficiency and fidelity (P. Pfeiffer and W. Vielmetter, Nucleic Acids Res. 16:907-924, 1988). In mammalian cells, such nonhomologous end joining (NHEJ) is known to require the Ku heterodimer, a component of DNA-dependent protein kinase. Here I investigated whether Ku is also required for the in vitro reaction in the egg extract. Immunological assays indicate that Ku is very abundant in the extract. I found that all NHEJ was inhibited by autoantibodies against Ku and that NHEJ between certain combinations of DNA ends was also decreased after immunodepletion of Ku from the extract. The formation of a joint between a DNA end with a 5'-protruding single strand (PSS) and an end with a 3'-PSS, between two ends with 3'-PSS, and between two blunt ends was most Ku dependent. On the other hand, NHEJ between two DNA ends bearing 5'-PSS was Ku independent. These results show that the Xenopus cell-free system will be useful to biochemically dissect the role of Ku in eukaryotic NHEJ.

Serum starvation induced secondary V lambda J lambda rearrangement in a human plasma B cell line

HB4C5 is a human antibody producing plasma B cell line that expresses the recombination activating gene-1 (RAG-1) and RAG-2 constitutively, but undergoes few secondary immunoglobulin gene rearrangements when cultured in fetal bovine serum-containing medium. Here, we found that depletion of serum from the culture media induces secondary VlambdaJlambda rearrangement in this cell line. To investigate the induction mechanism of secondary VlambdaJlambda rearrangement, we assessed the expression levels of RAG-1 and RAG-2 products, Vlambda germline transcription level and the amount of Vlambda signal broken ends (SBE) in HB4C5 cells cultured in serum-supplemented or serum-free medium. Western-blot analysis showed that the expression level for the RAG-1 and RAG-2 proteins was not affected by the serum depletion. Vlambda germline transcript was found to be constitutively expressed in HB4C5 cell line and this transcription level was not affected by the lack of serum. On the other hand, the amount of Vlambda SBE was shown to be increased in HB4C5 cells cultured in serum-free medium, suggesting that this increased formation of Vlambda SBE at least partly contributed to the enhanced occurrence of secondary VlambdaJlambda rearrangement in HB4C5 cells cultured in the serum-free condition. These results indicate that expression of RAG proteins and Vlambda germline transcription is not enough to undergo secondary VlambdaJlambda rearrangement in this cell line.

Positive and negative regulation of V(D)J recombination by the E2A proteins

A key feature of B and T lymphocyte development is the generation of antigen receptors through the rearrangement and assembly of the germline variable (V), diversity (D), and joining (J) gene segments. However, the mechanisms responsible for regulating developmentally ordered gene rearrangements are largely unknown. Here we show that the E2A gene products are essential for the proper coordinated temporal regulation of V(D)J rearrangements within the T cell receptor (TCR) gamma and delta loci. Specifically, we show that E2A is required during adult thymocyte development to inhibit rearrangements to the gamma and delta V regions that normally recombine almost exclusively during fetal thymocyte development. The continued rearrangement of the fetal Vgamma3 gene segment in E2A-deficient adult thymocytes correlates with increased levels of Vgamma3 germline transcripts and increased levels of double-stranded DNA breaks at the recombination signal sequence bordering Vgamma3. Additionally, rearrangements to a number of Vgamma and Vdelta gene segments used predominantly during adult development are significantly reduced in E2A-deficient thymocytes. Interestingly, at distinct stages of T lineage development, both the increased and decreased rearrangement of particular Vdelta gene segments is highly sensitive to the dosage of the E2A gene products, suggesting that the concentration of the E2A proteins is rate limiting for the recombination reaction involving these Vdelta regions.

Hairpin coding end opening is mediated by RAG1 and RAG2 proteins

Despite the importance of hairpin opening in antigen receptor gene assembly, the molecular machinery that mediates this reaction has not been defined. Here, we show that RAG1 plus RAG2 can open DNA hairpins. Hairpin opening by RAGs is not sequence specific, but in Mg2+, hairpin opening occurs only in the context of a regulated cleavage complex. The chemical mechanism of hairpin opening by RAGs resembles RSS cleavage and 3' end processing by HIV integrase and Mu transposase in that these reactions can proceed through alcoholysis. Mutations in either RAG1 or RAG2 that interfere with RSS cleavage also interfere with hairpin opening, suggesting that RAGs have a single active site that catalyzes several distinct DNA cleavage reactions.

Partial V(D)J recombination activity leads to Omenn syndrome

Genomic rearrangement of the antigen receptor loci is initiated by the two lymphoid-specific proteins Rag-1 and Rag-2. Null mutations in either of the two proteins abrogate initiation of V(D)J recombination and cause severe combined immunodeficiency with complete absence of mature B and T lymphocytes. We report here that patients with Omenn syndrome, a severe immunodeficiency characterized by the presence of activated, anergic, oligoclonal T cells, hypereosinophilia, and high IgE levels, bear missense mutations in either the Rag-1 or Rag-2 genes that result in partial activity of the two proteins. Two of the amino acid substitutions map within the Rag-1 homeodomain and decrease DNA binding activity, while three others lower the efficiency of Rag-1/Rag-2 interaction. These findings provide evidence to indicate that the immunodeficiency manifested in patients with Omenn syndrome arises from mutations that decrease the efficiency of V(D)J recombination.

Antigen receptor gene rearrangement

Two specialized forms of site-directed double-strand (ds) DNA breakage and rejoining are part of the physiologic program of lymphocytes. One is recombination of the V, D and J gene sequences, termed V(D)J recombination, occurring during early B- and T-cell development, and the other is class-switch recombination occurring exclusively in mature B cells. For V(D)J recombination significant progress has been made recently elucidating the biochemistry of the reaction. In particular our understanding of how DNA ds breaks are both generated and rejoined has increased. For class-switch recombination no definitive information is known about the nucleases required for making the ds breaks, but recent evidence suggests that the joining phase shares activities also required for V(D)J recombination and general DNA ds break repair.

V(D)J recombination: in vitro coding joint formation

Antigen receptor genes are assembled through a mechanism known as V(D)J recombination, which involves two different joining reactions: signal and coding joining. Formation of these joints is essential for antigen receptor assembly as well as maintaining chromosomal integrity. Here we report on a cell-free system for coding joint formation using deletion and inversion recombination substrates. In vitro coding joint formation requires RAG1, RAG2, and heat-labile factors present in the nuclear extract of nonlymphoid cells. Both inversion- and deletion-mediated coding joint reactions produce diverse coding joints, with deletions and P nucleotide addition. We also show that deletion-mediated coding joint formation follows the 12/23 rule and requires the catalytic subunit of DNA-dependent protein kinase.

Cell-free V(D)J recombination

V(D)J recombination generates diversity in the immune system through the lymphoid-specific assembly of multiple gene segments into functional immunoglobulin and T-cell receptor genes. The first step in V(D)J recombination is cleavage of DNA at recombination signal sequences. Cleavage produces a blunt DNA end on each signal sequence and a hairpin end on adjacent coding gene segments, and can be reproduced in vitro by using purified RAG and RAG2 proteins. The later steps involve processing and joining of the cleaved DNA ends, and until now have been studied only in cells. Here we reconstitute the complete V(D)J recombination reaction in a cell-free system. We find that the RAG proteins are not only involved in cleavage, but are also needed in the later steps for efficient joining of coding ends. Joining is largely directed by short pieces of identical sequence in the coding flanks, but addition of human DNA ligase I results in greater diversity. Coding junctions contain short deletions as well as additions complementary to a coding flank (P nucleotides). Addition of non-templated nucleotides into coding junctions is mediated by terminal deoxyribonucleotidyl transferase. The cell-free reaction can therefore reproduce the complete set of processing events that occur in cells.

Complementation of V(D)J recombination deficiency in RAG-1(-/-) B cells reveals a requirement for novel elements in the N-terminus of RAG-1

RAG-1 is an essential component of the site-specific V(D)J recombinase. A new assay system has revealed a significant contribution of the catalytically dispensible N-terminal region of RAG-1 to recombination activity. The foundation for this system is an Abelson virus-transformed cell line derived from RAG-1(-/-) mice that is dependent on the introduction of exogenous RAG-1 for rearrangement of either plasmid substrates or the endogenous immunoglobulin loci. Use of this line demonstrates that conserved and novel cysteine-containing elements in the N-terminal region are required for full RAG-1 activity when recombination activity is in a RAG-1 dose-responsive range. Our data suggest that the RAG-1 N-terminus enhances the formation of an active recombination complex that facilitates the rearrangement process.

V(D)J recombination: modulation of RAG1 and RAG2 cleavage activity on 12/23 substrates by whole cell extract and DNA-bending proteins

Antigen receptor gene rearrangement is directed by DNA motifs consisting of a conserved heptamer and nonamer separated by a nonconserved spacer of either 12 or 23 base pairs (12 or 23 recombination signal sequences [RSS]). V(D)J recombination requires that the rearranging DNA segments be flanked by RSSs of different spacer lengths, a phenomenon known as the 12/23 rule. Recent studies have shown that this restriction operates at the level of DNA cleavage, which is mediated by the products of the recombination activating genes RAG1 and RAG2. Here, we show that RAG1 and RAG2 are not sufficient for 12/23 dependent cleavage, whereas RAG1 and RAG2 complemented with whole cell extract faithfully recapitulates the 12/23 rule. In addition, HMG box containing proteins HMG1 and HMG2 enhance RAG1- and RAG2-mediated cleavage of substrates containing 23 RSS but not of substrates containing only 12 RSS. These results suggest the existence of a nucleoprotein complex at the cleavage site, consisting of architectural, catalytic, and regulatory components.

RAG1 and RAG2 form a stable postcleavage synaptic complex with DNA containing signal ends in V(D)J recombination

During V(D)J recombination, RAG1 and RAG2 cleave DNA adjacent to highly conserved recombination signals, but nothing is known about the protein-DNA complexes that exist after cleavage. Using a properly regulated in vitro V(D)J cleavage system, together with nuclease sensitivity, mobility shift, and immunoprecipitation experiments, we provide evidence that a stable complex is formed postcleavage between synapsed recombination signals. This complex includes the proteins RAG1, RAG2, HMG-1 or the closely related HMG-2 protein, and the components of the DNA-dependent protein kinase. The existence of such a stable complex explains a number of in vivo observations and suggests that remodeling of postcleavage synaptic complexes is an important step in the resolution of signal ends in V(D)J recombination.