An enhancer-blocking element between alpha and delta gene segments within the human T cell receptor alpha/delta locus

T cell receptor (TCR) alpha and delta gene segments are organized within a single genetic locus but are differentially regulated during T cell development. An enhancer-blocking element (BEAD-1, for blocking element alpha/delta 1) was localized to a 2.0-kb region 3' of TCR delta gene segments and 5' of TCR alpha joining gene segments within this locus. BEAD-1 blocked the ability of the TCR delta enhancer (Edelta) to activate a promoter when located between the two in a chromatin-integrated construct. We propose that BEAD-1 functions as a boundary that separates the TCR alpha/delta locus into distinct regulatory domains controlled by Edelta and the TCR alpha enhancer, and that it prevents Edelta from opening the chromatin of the TCR alpha joining gene segments for VDJ recombination at an early stage of T cell development.

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.

Changes in locus-specific V(D)J recombinase activity induced by immunoglobulin gene products during B cell development

The process of V(D)J recombination is crucial for regulating the development of B cells and for determining their eventual antigen specificity. Here we assess the developmental regulation of the V(D)J recombinase directly, by monitoring the double-stranded DNA breaks produced in the process of V(D)J recombination. This analysis provides a measure of recombinase activity at immunoglobulin heavy and light chain loci across defined developmental stages spanning the process of B cell development. We find that expression of a complete immunoglobulin heavy chain protein is accompanied by a drastic change in the targeting of V(D)J recombinase activity, from being predominantly active at the heavy chain locus in pro-B cells to being exclusively restricted to the light chain loci in pre-B cells. This switch in locus-specific recombinase activity results in allelic exclusion at the immunoglobulin heavy chain locus. Allelic exclusion is maintained by a different mechanism at the light chain locus. We find that immature, but not mature, B cells that already express a functional light chain protein can undergo continued light chain gene rearrangement, by replacement of the original rearrangement on the same allele. Finally, we find that the developmentally regulated targeting of V(D)J recombination is unaffected by enforced rapid transit through the cell cycle induced by an E mu-myc transgene.

Essential functions of Pax5 (BSAP) in pro-B cell development: difference between fetal and adult B lymphopoiesis and reduced V-to-DJ recombination at the IgH locus

The Pax5 gene coding for the transcription factor BSAP has an essential role in B lymphopoiesis and midbrain development. Here we present a detailed analysis of the B-cell phenotype of Pax5 mutant mice that revealed a differential dependency of fetal and adult B lymphopoiesis on this transcriptional regulator. B-cell development is arrested in the bone marrow at the early pro-B (pre-BI) cell stage, which is characterized by expression of the early markers c-kit, CD43, lambda5, VpreB, and HSA and the absence of the later markers CD25 and BP-1. These pre-BI cells fail to express the BSAP target gene CD19 and are capable of long-term proliferation in vitro in the presence of stromal cells and IL-7. B-lymphoid progenitors could not be detected in the fetal liver of Pax5 mutant embryos. However, Pax5-deficient fetal liver cells gave rise to the development of pre-BI cells in bone marrow on transplantation into lethally irradiated mice. These data indicate different functions of Pax5 in the distinctive microenvironments of fetal liver and adult bone marrow. As shown by PCR analyses, the pre-BI cells in Pax5-deficient bone marrow have undergone D(H)-to-J(H) rearrangement of the immunoglobulin heavy-chain locus at normal frequency. In contrast, V(H)-to-D(H)J(H) rearrangements were reduced approximately 50-fold in Pax5-deficient pre-BI cells, suggesting a role for Pax5 in the developmental pathway controlling V-to-DJ recombination.

An ionizing radiation-sensitive CHO mutant cell line: irs-20. IV. Genetic complementation, V(D)J recombination and the scid phenotype

The genetic defect responsible for hypersensitivity of Chinese hamster ovary (CHO) irs-20 cells to ionizing radiation was found to be recessive in nature and could be complemented to produce wild-type radiosensitivity in irs-20/human hybrids. The radiosensitivities of six hybrid clones were determined based on their colony-forming ability under continuous irradiation at 6 cGy/h. A parallel cytogenetic analysis revealed a concordance between the presence or absence of human chromosome 8 and the resistant or sensitive phenotype. Confirming evidence was obtained using human chromosome 8-specific PCR primers. Positive amplification was obtained in hybrids with wild-type radiosensitivity, while no amplification was obtained in sensitive hybrids. Complementation analysis between radiosensitive CHO irs-20 and murine scid cell lines was carried out to determine whether the defects leading to their ionizing radiation hypersensitivity could be corrected by genetic complementation in the hybrids. Complementation did not occur. A transient V(D)J recombination assay after the introduction of the RAG1 and RAG2 genes indicated that the V(D)J recombination ability of the CHO irs-20 cells was about 10% of that for the CHO wild-type cells for signal join formation with an 80% joining fidelity and only 3% of the parental level for coding join formation. These data show that murine scid and irs-20 mutant hamster cells fall into the same complementation group and show similar defects in V(D)J recombination.

Rearrangement and reactivation of the myelin basic protein locus in myelin-deficient (mld) mouse brain

Myelin-deficient (mld) is a complex mutation affecting the myelin basic protein (MBP) locus of the mouse. It consists of duplication and partial inversion of the MBP gene and results in a dysfunctional MBP locus. The mutant phenotype is reversed, both in vivo and in vitro, in approximately 5% of mld oligodendrocytes. One possible mechanism for the somatic reversion is recombination between homologous sequences of the duplicated gene copies to reconstitute a functional MBP locus. There are several possible recombination events that could reconstitute a functional MBP locus by DNA rearrangement. Two of these would result in reinversion and circularization of specific MBP gene sequences, respectively. In this work polymerase chain reaction analysis was used to detect both reinverted and circularized MBP gene sequences in mld mouse tissues, indicating that DNA rearrangement at the MBP locus does occur. Analysis of individually harvested cells showed that in revertant MBP-positive mld oligodendrocytes DNA rearrangement at the MBP locus was correlated with reactivation of the MBP gene. Fluctuation analysis showed that reactivation of the MBP locus is a stochastic event occurring with a frequency of approximately 1.4 x 10(-6) per cell per cell cycle during oligodendrocyte development. The frequency of rearrangement and reactivation of the MBP locus was comparable in double mutant (mld/mld, scid/scid) and single mutant (mld/mld, +scld/+scld) mice, indicating that the scid factor is not required for MBP gene reactivation in mld. The significance of DNA rearrangement in mammalian development is discussed.

Assessing the pathogenic potential of the V(D)J recombinase by interlocus immunoglobulin light-chain gene rearrangement

Chromosomal translocations involving antigen receptor genes and oncogenes have been observed in several forms of lymphoid malignancy. Observations of their lymphocyte-restricted occurrence and a molecular analysis of some translocation breakpoints have suggested that some of these rearrangements are generated by V(D)J recombinase activity. However, a direct correlation between this activity and the generation of such rearrangements has never been established. In addition, because these aberrant rearrangements are usually detected only after a tumor has been formed, the frequency with which the recombinase machinery generates translocations has never been assessed directly. To approach these issues, immunoglobulin light-chain gene rearrangements were induced in pre-B cells transformed by temperature-sensitive mutants of Abelson murine leukemia virus and PCR was used to identify interlocus recombinants. Vlambda Jkappa and Vkappa Jlambda rearrangements as well as signal joints resulting from the recombination of Vlambda and Jkappa coding elements were recovered and were found to be similar in structure to conventional intrachromosomal joints. Because these products were detected only when the cells were undergoing active intralocus rearrangement, they provide direct evidence that translocations can be generated by the V(D)J recombinase machinery. Dilution analyses revealed that interlocus rearrangements occur about 1,000 times less frequently than conventional intralocus rearrangements. Considering the large numbers of lymphocytes generated throughout life, aberrant rearrangements generated by the V(D)J recombinase may be relatively common.

Regulation of DNA metabolic enzymes upon induction of preB cell development and V(D)J recombination: up-regulation of DNA polymerase delta

Withdrawal of interleukin-7 from cultured murine preB lymphocytes induces cell differentiation including V(D)J immunoglobulin gene rearrangements and cell cycle arrest. Advanced steps of the V(D)J recombination reaction involve processing of coding ends by several largely unidentified DNA metabolic enzymes. We have analyzed expression and activity of DNA polymerases alpha, beta, delta and epsilon, proliferating cell nuclear antigen (PCNA), topoisomerases I and II, terminal deoxynucleotidyl transferase (TdT) and DNA ligases I, III and IV upon induction of preB cell differentiation. Despite the immediate arrest of cell proliferation, DNA polymerase delta protein levels remained unchanged for approximately 2 days and its activity was up-regulated several-fold, while PCNA was continuously present. Activity of DNA polymerases alpha,beta and epsilon decreased. Expression and activity of DNA ligase I were drastically reduced, while those of DNA ligases III and IV remained virtually constant. No changes in DNA topoisomerases I or II expression and activity occurred and TdT expression was moderately increased early after induction. Our results render DNA polymerase delta a likely candidate acting in DNA synthesis related to V(D)J recombination in lymphocytes.

Developmental regulation of VDJ recombination by the core fragment of the T cell receptor alpha enhancer

The role of T cell receptor alpha enhancer (E alpha) cis-acting elements in the developmental regulation of VDJ recombination at the TCR alpha/delta locus was examined in transgenic mice containing variants of a minilocus VDJ recombination substrate. We demonstrate that the 116-bp T alpha 1,2 core enhancer fragment of the 1.4-kb E alpha is sufficient to activate the enhancer-dependent step of minilocus rearrangement, and that within T alpha 1,2, intact binding sites for TCF/LEF and Ets family transcription factors are essential. Although minilocus rearrangement under the control of the 1.4-kb E alpha initiates at fetal day 16.5 and is strictly limited to alpha beta T cells, we find that rearrangement under the control of T alpha 1,2 initiates slightly earlier during ontogeny and occurs in both gamma delta and alpha beta T cells. We conclude that the core fragment of E alpha can establish accessibility to the recombinase in developing thymocytes in vivo in a fashion that is dependent on the binding of TCF/LEF and Ets family transcription factors, but that these and other factors that bind to the E alpha core cannot account for the precise developmental onset of accessibility that is provided by the intact E alpha. Rather, our data suggests a critical role for factors that bind E alpha outside of the core T alpha 1,2 region in establishing the precise developmental onset of TCR alpha rearrangement in vivo.

Quantification of hprt gene deletions mediated by illegitimate V(D)J recombination in peripheral blood cells of humans

V(D)J recombinase is normally involved in the highly regulated rearrangement of immunoglobulin and T-cell-receptor gene segments (in B and T cells, respectively) to form functional antibody genes and T-cell-receptor genes. Occasionally, this tightly controlled process acts on inappropriate places in the genome and results in deletions and translocations. Some of these illegitimate V(D)J recombinase-mediated events have been implicated in the genetic changes associated with several forms of leukemia and lymphoid malignancy. We have developed a sensitive, specific polymerase chain reaction (PCR)-based assay to quantify such events in the peripheral blood cells of humans. This assay detects a V(D)J recombinase-mediated deletion in the hprt gene, which codes for a housekeeping enzyme and is not implicated in cancer development. Alterations in this gene serve as a surrogate indicator for these illegitimate events, which may be occurring throughout the genome. The assay involves a hemi-nested PCR with two sets of primers. Multiple replicates of genomic DNA (each representing 4 x 10(5) cells) are amplified with specific primers under conditions in which a single copy will give a detectable PCR product. Poisson statistics are then used to estimate the deletion mutant frequency. The frequency of cells with the hprt deletion among 20 healthy young adults ranged from <1.3 x 10(-7) to 4.1 x 10(-7) and was compared with the frequency of t(14;18) previously determined in these same individuals. No correlation was found between the frequencies of these two measures of genomic rearrangement. The DNA sequences at the deletion junctions were determined and provided evidence for multiple independent mutations in some individuals. This assay may serve as a biomarker for the level of illegitimate V(D)J recombination occurring in peripheral blood cells of humans.

Neoteny in lymphocytes: Rag1 and Rag2 expression in germinal center B cells

The products of the Rag1 and Rag2 genes drive genomic V(D)J rearrangements that assemble functional immunoglobulin and T cell antigen receptor genes. Expression of the Rag genes has been thought to be limited to developmentally immature lymphocyte populations that in normal adult animals are primarily restricted to the bone marrow and thymus. Abundant RAG1 and RAG2 protein and messenger RNA was detected in the activated B cells that populate murine splenic and Peyer's patch germinal centers. Germinal center B cells thus share fundamental characteristics of immature lymphocytes, raising the possibility that antigen-dependent secondary V(D)J rearrangements modify the peripheral antibody repertoire.

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

The first step of V(D)J recombination, specific cleavage at the recombination signal sequence (RSS), can be carried out by the recombination activating proteins RAG1 and RAG2. In vivo, the cleaved coding and signal ends must be rejoined to generate functional antigen receptors and maintain chromosomal integrity. We have investigated signal joint formation using deletion and inversion substrates in a cell free system. RAG1 and RAG2 alone or in combination were unable to generate signal joints. However, RAG1 and RAG2 complemented with nuclear extracts were able to recombine an extrachromosomal substrate and form precise signal joints. The in vitro reaction resembled authentic V(D)J recombination in being Ku-antigen-dependent.

Immunoglobulin D(H) recombination signal sequence targeting: effect of D(H) coding and flanking regions and recombination partner

V(D)J recombination is targeted by recombination signal sequences (RSS) located immediately adjacent to immune receptor gene segments. While the RSS flanking D(H) segments appear to be equivalent, they are not randomly utilized. During D(H) to J(H) rearrangement, the 3' D(H) RSS is virtually exclusively utilized, suggesting that the 3' D(H) RSS could simply be a better target for the recombinase. However, when we examined V(H) to D(H) (without J(H)) rearrangements, we found that the preference for D(H) RSS use changes, so that the 5' D(H) RSS are preferred. This suggests that the 3' D(H) RSS are not simply superior targets for the V(D)J recombinase, but instead that certain 12/23-bp spacer RSS combinations work better together to target recombination than do others. We have analyzed a series of artificial recombination substrates to delineate cis sequences that affect D(H) RSS selection. Our data suggest that coding sequences adjacent to the D(H) RSS, flanking sequences outside the D(H) gene segment itself, and recombination partner all affect D(H) RSS targeting.

DNA sequence and structure requirements for cleavage of V(D)J recombination signal sequences

Purified RAG1 and RAG2 proteins can cleave DNA at V(D)J recombination signals. In dissecting the DNA sequence and structural requirements for cleavage, we find that the heptamer and nonamer motifs of the recombination signal sequence can independently direct both steps of the cleavage reaction. Proper helical spacing between these two elements greatly enhances the efficiency of cleavage, whereas improper spacing can lead to interference between the two elements. The signal sequences are surprisingly tolerant of structural variation and function efficiently when nicks, gaps, and mismatched bases are introduced or even when the signal sequence is completely single stranded. Sequence alterations that facilitate unpairing of the bases at the signal/coding border activate the cleavage reaction, suggesting that DNA distortion is critical for V(D)J recombination.

Developmental regulation of V(D)J recombination and lymphocyte differentiation

Recent insights into the mechanism of V(D)J recombination have clarified the direct role of the products of the recombination-activating genes Rag-1 and Rag-2 in site-specific DNA cleavage at recombination signal sequences and have identified components of the general DNA double-strand break repair pathway that participate in the rejoining of the Rag-1 and Rag-2-cut receptor gene segments. The V(D)J reaction is restricted to particular antigen receptor loci in a lineage-specific and stage-specific manner. This specificity appears to involve cis-regulatory elements, some of which also regulate transcription of the germline antigen receptor loci. Early developmental steps in the T and B lineages - including phenotypic differentiation, expansion of precursors, and selection processes - are effected in a stepwise fashion by signals generated, at least in part, by the products of the functionally rearranged antigen receptor genes themselves.

Etoposide causes illegitimate V(D)J recombination in human lymphoid leukemic cells

Etoposide is one of the most widely used antineoplastics. Unfortunately, the same treatment schedules associated with impressive efficacy are associated with an increased risk of secondary acute myeloid leukemia (AML), which has prompted its withdrawal from some treatment regimens, thereby potentially compromising efficacy against the original tumor. Because etoposide-associated AML is characterized by site-specific illegitimate DNA recombination, we studied whether etoposide could directly cause site-specific deletions of exons 2 and 3 in the hprt gene. Human lymphoid CCRF-CEM cells were treated with etoposide for 4 hours, and DNA was isolated after subculturing. The deletion of exons 2 and 3 from hprt was assayed by a quantitative polymerase chain reaction (PCR) method. In the absence of etoposide treatment, the frequency of deletions of exons 2 and 3 was very low (5.05 x 10(-8)). After exposure to 10 mumol/ L etoposide, the frequency of the exon 2 + 3 deletion was increased immediately after and at 24 hours after etoposide treatment (65 to 89 x 10(-8)) and increased to higher levels (128 to 173 x 10(-8)) after 2 and 6 days of subculture (P < .001 overall). The frequency of the exon 2 + 3 deletion assessed at 6 days of subculture after 4 hours of 0, 0.25, 1, 2.5, 5, and 10 mumol/L etoposide treatment increased with etoposide concentration, ie, 5.05 x 10(-8), 89.2 x 10(-8), 108 x 10(-8), 142 x 10(-8), 163 x 10(-8), and 173 x 10(-8), respectively (P < .0001). Sequencing of a subset of amplified products confirmed the presence of DNA sequences at the breakpoints consistent with V(D)J recombination. By contrast, exon 2 + 3 deletions after etoposide treatment in the myeloid cell lines KG-1A and K562 showed no evidence of V(D)J recombinase in their genesis. We conclude that etoposide can induce the illegitimate site-specific action of V(D)J recombinase on an unnatural DNA substrate after a single treatment in human lymphoid cells.

Primordial emergence of the recombination activating gene 1 (RAG1): sequence of the complete shark gene indicates homology to microbial integrases

The rearrangement of antibody and T-cell receptor gene segments is indispensable to the vertebrate immune response. All extant jawed vertebrates can rearrange these gene segments. This ability is conferred by the recombination activating genes I and II (RAG I and RAG II). To elucidate their origin and function, the cDNA encoding RAG I from a member of the most ancient class of extant gnathostomes, the Carcharhine sharks, was characterized. Homology domains identified within shark RAG I prompted sequence comparison analyses that suggested similarity of the RAG I and II genes, respectively, to the integrase family genes and integration host factor genes of the bacterial site-specific recombination system. Thus, the apparent explosive evolution (or "big bang") of the ancestral immune system may have been initiated by a transfer of microbial site-specific recombinases.

The V(D)J recombination defect in the xrs-6 cell line results from a point mutation in the Ku80 gene

Defective expression of the Ku80 gene has been implicated as underlying the V(D)J recombination and DNA double-strand break repair defects in the xrs-6 Chinese hamster ovary cell line. We now show that the mutation in the Ku80 gene involves a G to A transition 15 bp upstream of exon 2. This mutation creates a new splice acceptor site which results in the generation of Ku80 transcript that cannot encode a functional product due a 13 nucleotide insertion and a resulting frameshift.

Gene-targeted deletion and replacement mutations of the T-cell receptor beta-chain enhancer: the role of enhancer elements in controlling V(D)J recombination accessibility

To assess the role of transcriptional enhancers in regulating accessibility of the T-cell receptor beta-chain (TCRbeta) locus, we generated embryonic stem cell lines in which a single allelic copy of the endogenous TCRbeta enhancer (Ebeta) was either deleted or replaced with the immunoglobulin heavy-chain intronic enhancer. We assayed the effects of these mutations on activation of the TCRbeta locus in normal T- and B-lineage cells by RAG-2 (recombination-activating gene 2)-deficient blastocyst complementation. We found that Ebeta is required for rearrangement and germ-line transcription of the TCRbeta locus in T-lineage cells. In the absence of Ebeta, the heavy-chain intronic enhancer partially supported joining region beta-chain rearrangement in T- but not in B-lineage cells. However, ability of the heavy-chain intronic enhancer to induce rearrangements was blocked by linkage to an expressed neomycin-resistance gene (neo(r)). These results demonstrate a critical role for Ebeta in promoting accessibility of the TCRbeta locus and suggest that additional negative elements may cooperate to further modulate this process.

Dysregulation of cyclin D1 by translocation into an IgH gamma switch region in two multiple myeloma cell lines

Translocations involving the IgH locus at chromosomal locus 14q32.3 are a common event in many B-cell malignancies. The translocations, which generally occur into JH and switch regions, are mediated by errors in the two developmentally regulated, lymphocyte-specific pathways: VDJ-and switch-mediated recombination. Dysregulation of cyclin D1 by a t(11;14)(q13;q32) translocation occurs in most cases of mantle-cell lymphoma and in approximately 30% of multiple myeloma (MM) tumors in which a 14q32 translocation can be detected. We show here that in two of three myeloma lines that overexpress cyclin D1, there is an 11;14 translocation into a gamma switch region, suggesting an error in switch recombination. By contrast, 11;14 translocations in mantlecell lymphoma are invariably into or near a JH segment, suggesting an error in VDJ recombination. This is consistent with the fact that myeloma cells have undergone lgH switch recombination, whereas mantle-cell lymphoma cells generally have not.

Lymphocytic progenitor cell origin and clonal evolution of human B-lineage acute lymphoblastic leukemia

At presentation, bone marrow specimens from over 25% of B-lineage acute lymphoblastic leukemias (ALL) display more than two clonal rearrangements of immunoglobulin heavy chain (IgH) genes in Southern blot analyses. Nucleotide sequence analysis has shown predominantly different V(H)DJ(H) junctions among these genes, leading to the frequent description of such cases as oligoclonal leukemias. In the present study, we have analyzed the lgH genes from four patients whose leukemic cells contained different patterns of lgH gene rearrangements between presentation and relapse. Nucleotide sequence analysis of the lgH genes showed that three mechanisms could account for these differences: de novo V(H)DJ(H) rearrangement, V(H) to DJ(H) recombination, and V(H) replacement. In all cases, more than two totally different V(H)DJ(H) rearrangements appeared during evolution of the disease, formally consistent with the conclusion that these tumors were composed of apparently unrelated clones. However, the retention of some of the antigen receptor gene rearrangements, as well as the persistence of a chromosomal marker in two cases, indicated that these leukemias had a monoclonal origin. These findings support the hypothesis that some ALLs arise from a lymphoid progenitor cell at a stage of lymphocyte development before the onset of IgH gene rearrangement. These leukemic lymphocyte progenitors generate malignant daughter cells capable of an in vivo maturation that involves the completion of multiple different lgH rearrangements as well as the modification of preexisting rearrangements by V(H) to DJ(H) recombination or by a V(H) replacement.

Cell type-specific chromatin structure determines the targeting of V(D)J recombinase activity in vitro

A common V(D)J recombinase that recognizes a conserved recombination signal sequence (RSS) mediates the assembly of immunoglobulin (Ig) and T cell receptor (TCR) genes in B and T cell precursors. The rearrangement of particular Ig and TCR gene segments, however, is tightly regulated with respect to cell lineage and developmental stage. Using an in vitro system, we analyzed recombinase cleavage of RSSs flanking Ig and TCR gene segments in nuclei. We found that both the lineage-specificity and temporal ordering of gene rearrangement is reflected in the accessibility of RSSs within chromatin to in vitro cleavage.

Ku80-deficient cells exhibit excess degradation of extrachromosomal DNA

Mammalian cells possess a protein complex, termed DNA-PK, which binds to DNA double strand breaks in vitro. The complex consists of the heterodimeric Ku autoantigen and a DNA-dependent protein kinase, DNA-PKcs. Cell lines that are deficient for components of this complex are sensitive to ionizing radiation and have impaired V(D)J recombination, a site-specific recombination process. We have tested these cell lines for their ability to repair double strand breaks in transfected DNA. The xrs-6 cell line, which is deficient for the 80-kDa subunit of the Ku autoantigen, exhibited reduced stability of transfected DNA. Prior to obvious reductions in DNA stability, the levels of homologous recombination and DNA end joining were unaffected. However, the recovery of end joining products with precisely joined ends was reduced, with a concomitant increase in products containing deletions. Unlike the Ku80-deficient cells, no reduction in DNA stability was detected in DNA-PKcs-deficient scid cells. Scid cells also exhibited normal levels of homologous recombination and DNA end joining. These experiments implicate the Ku autoantigen, but not DNA-PKcs, in a direct role in protecting DNA ends from degradation.

Cutting apart V(D)J recombination

The past year has seen major advances in our understanding of the recombination mechanism by which antibody and T cell receptor genes are assembled during lymphoid development. The initial cleavage events can be carried out in vitro by purified RAG1 and RAG/ protein. In addition, a number of genes involved in later steps of the reaction have been cloned, opening the way for an in-depth biochemical analysis of this critical developmental process.

Regions of RAG1 protein critical for V(D)J recombination

The products of the recombination activating genes RAG1 and RAG2 are essential for activating V(D)J recombination, and thus are indispensable for the production of functional and diverse antigen receptors. To investigate the function of RAG1, we have tested a series of insertion and substitution mutation for their ability to induce V(D)J rearrangement on both deletional and inversional plasmid substrates. With these substrates we were also able to assess the effects of these mutations on both coding and signal joint formation, and to show that any one mutant affected all these reactions similarly. As defined previously, the core active regions of RAG1 and RAG2 permit the deletion of 40% and 25%, respectively, of well-conversed sequence. We show here that this "dispensable" region of RAG1 is not necessary for coding joint formation or recombination of an integrated substrate, and this portion is not functionally redundant with the "dispensable" region of RAG2. Recombination with these core regions is also still subject to the 12/23 joining rule. Further, the minimal essential core region of RAG1 can be located within an even smaller portion of the gene.

Translatable immunoglobulin germ-line transcript

During B cell differentiation, the functional genes encoding immunoglobulin (Ig) heavy (H) and light (L) chains are generated by two rearrangement processes--VDJ rearrangement generates the exon encoding the Ig variable (V) regions, and the class switch reconstructs a rearranged IgH gene by exchanging the segment encoding the constant (C) region, which determines the Ig class. Both types of rearrangement are preceded by transcripts originating from a transcriptional start site 5' of the I exon, which is then spliced to the C exons. These germ-line transcripts, which are thought to be necessary for the initiation of both types of rearrangement, are said to be sterile. We demonstrate here that the mu germ-line transcript is translatable into a polypeptide chain, to which we assign the symbol psi. Thus, protein products of these transcripts might be part of or signal to the recombinases that catalyze Ig gene rearrangement.

Ku86 defines the genetic defect and restores X-ray resistance and V(D)J recombination to complementation group 5 hamster cell mutants

X-ray-sensitive hamster cells in complementation groups 4, 5, 6, and 7 are impaired for both double-strand break repair and V(D)J recombination. Here we show that in two mutant cell lines (XR-V15B and XR-V9B) from group 5, the genetic defects are in the gene encoding the 86-kDa subunit of the Ku autoantigen, a nuclear protein that binds to the double-stranded DNA ends. These mutants express Ku86 mRNA containing deletions of 138 and 252 bp, respectively, and the encoded proteins contain internal, in-frame deletions of 46 and 84 amino acids. Two X-ray-resistant revertants of XR-V15B expressed two Ku86 transcripts, one with and one without the deletion, suggesting that reversion occurred by activation of a silent wild-type allele. Transfection of full-length cDNA encoding hamster Ku86 into XR-V15B cells resulted in a complete rescue of DNA-end-binding (DEB) activity and Ku70 levels, suggesting that Ku86 stabilizes the Ku70 polypeptide. In addition, cells expressing wild-type levels of DEB activity were fully rescued for X-ray resistance and V(D)J recombination, whereas cells expressing lower levels of DEB activity were only partially rescued. Thus, Ku is an essential component of the pathway(s) utilized for the resolution of DNA double-strand breaks induced by either X rays or V(D)J recombination, and mutations in the Ku86 gene are responsible for the phenotype of group 5 cells.

Clonal evolution in B-lineage acute lymphoblastic leukemia by contemporaneous VH-VH gene replacements and VH-DJH gene rearrangements

B-cell acute lymphoblastic leukemia (B-ALL), more frequently than any other B-lineage neoplasm, exhibits oligoclonal Ig heavy chain (IgH) gene rearrangement in 15% to 43% of all cases studied. To study the molecular processes that promote multiple IgH rearrangements, a comprehensive sequence analysis of a B-ALL case was performed in which seven clonal IgH gene rearrangements were identified. The genetic profiles suggested that a single leukemic progenitor clone evolved into several subclones through dual processes of variable (VH) to preexisting diversity-joining (DJH) gene segment rearrangement and VH to VH gene replacement. Predominant IgH-V usage and the uniquely rearranged clonotype-specific VHDJH region gene sequences were identified using a novel DNA-based gene amplification strategy. Polymerase chain reaction (PCR) was directed by an IgH-J generic primer and a complement of family-specific IgH-V primers that defined the major B-cell IgH-V gene usage. Clonality of rearranged VHDJH bands was substantiated by high resolution denaturant gel electrophoretic analysis. Sequence patterns of the amplified VHDJH fragments segregated into two groups defined by common DJH sequences. Partial N region homology at the VHD junction as well as shared DJH sequences firmly established VH to VHDJH gene replacement as a mechanism generating clonal evolution in one group. In the second subset, oligoclonality was propagated by independent VH gene rearrangements to a common DJH precursor. The contributions of all clonal Ig-VHDJH repertoires for each group was approximately 50% and reflected a symmetric distribution of leukemic subclones generated by either process. Thus, oligoclonal rearrangements evolved by two independent, yet seemingly contemporaneous molecular genetic mechanisms. All seven clones displayed nonfunctional Ig-VHDJH recombinations. These observations may have relevance to the recombinatorial opportunities available during normal B-cell maturation.

V(D)J recombinase-mediated HPRT mutations in peripheral blood lymphocytes of normal children

Somatic mutations in the hypoxanthine-guanine phosphoribosyltransferase (hprt) gene are rare occurrences in T-lymphocytes of normal individuals. Lacking pathogenic significance, these events can serve as reporters for assessing environmental genotoxicity. The present molecular analyses of hprt mutations arising spontaneously in normal children show that 30-35% of the genomic hprt changes in children under 5 years of age have approximately 20 Kb deletions encompassing exons 2 and 3. The frequency of these specific changes are dramatically decreased in older children. Sequence analysis of these deletion breakpoint and joining regions reveal the molecular hallmarks of V(D)J recombinase-mediated recombination events. This early childhood hprt mutational spectrum is quite distinct from the adult background spectrum but similar to that reported previously for newborns, as determined in lymphocytes from placental cord blood. The present study also demonstrates that definition of sequences in the hprt deletion joining regions that are analogous to the N-nucleotide insertion hypervariable regions of rearranged T-cell receptor genes allows the same identification of in vivo clonality of mutants as does analysis of the T-cell receptor gene rearrangements themselves. These methods reveal an in vivo clonal amplification of a V(D)J recombinase-mediated hprt mutant clone in one child in the present study. This newly found age-frequency distribution of V(D)J recombinase-mediated hprt mutations correlates with the age-frequency distribution of childhood acute lymphocytic leukemia. A significant number of these malignancies, including acute T-cell leukemia, are also characterized by V(D)J recombinase-mediated recombinations but in critical regions of the genome. hprt, therefore, captures a pathogenic mutagenic mechanism as a harmless mistake which, when it occurs in other genetic regions, may result in malignancy.

Similarities between initiation of V(D)J recombination and retroviral integration

In the first step of V(D)J recombination, the RAG1 and RAG2 proteins cleave DNA between a signal sequence and the adjacent coding sequence, generating a blunt signal end and a coding end with a closed hairpin structure. These hairpins are intermediates leading to the formation of assembled antigen receptor genes. It is shown here that the hairpins are formed by a chemical mechanism of direct trans-esterification, very similar to the early steps of transpositional recombination and retroviral integration. A minor variation in the reaction is sufficient to divert the process from transposition to hairpin formation.

DNA-dependent protein kinase defects are linked to deficiencies in DNA repair and V(D)J recombination

DNA-dependent protein kinase is a nuclear serine/threonine kinase whose catalytic properties are expressed only when the enzyme is bound to DNA ends or other discontinuities in the DNA. DNA-PK comprises two components: one mediates binding to DNA and corresponds to the heterodimeric human autoimmune antigen Ku; the other, DNA-PK catalytic subunit (DNA-PKcs), is a polypeptide of approximately 450 kDa. DNA-PK deficiencies are associated with certain mutant rodent cell lines that display defects in DNA double strand break repair and V(D)J recombination. Specifically, hamster xrs-6 cells lack Ku function, whereas murine scid and hamster V3 cells lack functional DNA-PKcs. Furthermore, the phenotypes of xrs-6 and V3 cells can be corrected by the expression of the genes encoding the 80 kDa component of Ku or DNA-PKcs, respectively. These results imply that DNA-PK is an important component of the DNA double strand break repair/recombination apparatus. Possible roles for DNA-PK in these processes are discussed.

B cells are generated throughout life in humans

This analysis of B cell development as a function of age reveals a relatively widespread distribution of progenitor B (pro-B), pre-B, and B cells in fetal tissues, and thus supports the idea of a multifocal origin of B lineage cells during embryonic development. From mid-gestation onward, the bone marrow is the major site of B cell generation in humans. A relatively constant ratio of bone marrow precursors to B cells of immature phenotype (CD24highCD10+CD20lowIgD-) is maintained from mid-gestation through the eighth decade of life. The persistence of recombinase gene activity in pro-B cells further attests the sustained production of B cells in bone marrow. Interestingly, a subpopulation of B cells with mature phenotype (CD24lowCD10-CD20highIgD+) accumulates in the bone marrow during childhood, and this becomes the predominant B cell subpopulation in adult bone marrow. This mature population of bone marrow B cells may represent a subpopulation of recirculating B cells that have undergone selection in the periphery.

Induction and repair of chromosome aberrations in scid cells measured by premature chromosome condensation

Severe combined immunodeficient (scid) murine cells, which are defective in both repair of DNA double-strand breaks and V(D)J recombination, are deficient in DNA-dependent protein kinase (DNA-PK), a protein which forms an activated complex with the DNA end-binding Ku proteins (p80 and p70) upon association with damaged DNA. Xrs 5 cells are deficient in the Ku p80 protein and also fail to form an active DNA-PK repair complex. Since both scid and xrs cells are defective in the same protein complex, we compared the kinetics of chromosome repair in scid cells to results published previously for xrs 5 cells. C.B-17 cells, scid cells and scid cells complemented with a single human chromosome 8 were irradiated with 6 Gy and allowed to repair from 0-24 h before fusion to HeLa cells for chromosome condensation. Breaks and dicentrics were visualized by fluorescence in situ hybridization. All cells had the same initial amount of chromosome damage, but scid cells had a slower rate of rejoining, more unrejoined breaks and more dicentrics than C.B-17 and scid cells with human chromosome 8. The scid cells appear to respond differently than xrs 5 cells, despite both cells lacking an essential component of the same DNA repair complex.

Equine severe combined immunodeficiency: a defect in V(D)J recombination and DNA-dependent protein kinase activity

V(D)J rearrangement is the molecular mechanism by which an almost infinite array of specific immune receptors are generated. Defects in this process result in profound immunodeficiency as is the case in the C.B-17 SCID mouse or in RAG-1 (recombination-activating gene 1) or RAG-2 deficient mice. It has recently become clear that the V(D)J recombinase most likely consists of both lymphoid-specific factors and ubiquitously expressed components of the DNA double-strand break repair pathway. The deficit in SCID mice is in a factor that is required for both of these pathways. In this report, we show that the factor defective in the autosomal recessive severe combined immunodeficiency of Arabian foals is required for (i) V(D)J recombination, (ii) resistance to ionizing radiation, and (iii) DNA-dependent protein kinase activity.

Epstein-Barr virus induction of recombinase-activating genes RAG1 and RAG2

In experimental B-cell infections, Epstein-Barr virus induced sustained expression of V(D)J recombinase-activating genes RAG1 and RAG2, whose aberrant activity has been implicated in chromosomal translocations in B-cell neoplasms. In cell lines in which RAG1 and RAG2 were detected, virus integrated into cellular DNA rather than assumed the configuration of extrachromosomal episomes. Expression of the Epstein-Barr virus nuclear antigen 1 in transient transfection assays was sufficient to induce both recombinase-activating genes.

Promotion of V(D)J recombinational accessibility by the intronic E kappa element: role of the kappa B motif

The accessibility of a chromosomally integrated TCR beta minilocus recombination substrate in a V(D)J recombinase-inducible cell line (HDR37) depends on incorporation of transcriptional enhancer elements such as the Ig kappa light chain intronic enhancer (E kappa). The E kappa element contains several functional motifs including the kappa B motif, which binds the NF-kappa B transcription factor. To assess molecular mechanisms by which E kappa promotes V(D)J recombinational accessibility, we compared the abilities of the wild-type E kappa, a corresponding E kappa sequence with a mutant kappa B motif (E kappa-kappa B-) and a kappa B motif dimer (kappa B2) to function in the context of the TCR beta minilocus/HDR37 system. The E kappa-containing minilocus underwent demethylation, transcription and V(D)J recombination, independently of copy number of integration site. Transfectants containing low copy numbers (one or two) of the E kappa-kappa B(-)-containing minilocus, like enhancerless or kappa B2-containing miniloci at any copy number, were inactive with respect to all three processes. In contrast, high-copy-number integrants of the E kappa-kappa B- substrates showed an integration-site dependent activation of all three processes. Together these data show that the kappa B motif plays a critical role in the ability of E kappa to confer V(D)J recombinational accessibility, but that it is not sufficient to mediate this process by itself.

Induction of sterile transcription from the kappa L chain gene locus in V(D)J recombinase-deficient progenitor B cells

B cell development in RAG-2-deficient (RAG-2T) mice is impeded at an early stage, due to the inability of these animals to rearrange their endogenous ig gene loci. Expression of an E mu-bcl-2 transgene in these mice did not change this phenotype. However, stromal cell/IL-7-reactive B cell progenitors (pro-B cells) were found in fetal live and bone marrow of RAG-2T and RAG-2T/E mu-bcl-2 transgenic mice in numbers comparable to normal mice. Like cells from normal mice they are c-kit+, surrogate L chain+ and CD25-, and can proliferate in vitro for long periods of time. Upon IL-7 deprivation, they can be induced to differentiate into c-kit-, surrogate L chain- and CD25+ cells that are no longer clonable on stromal cells and IL-7. Furthermore, sterile transcription from the kappa L chain gene loci is induced. The latter was also observed with pro-B cells directly isolated ex vivo from the bone marrow of RAG-2-deficient animals. The results suggest that progenitor B cell differentiation can occur in cells from V(D)J recombinase-deficient mice to the stage where kL chain gene rearrangements would normally be initiated. It further indicates that some molecular programs of early B cell differentiation can take place in the absence of Ig gene rearrangements.

Multiple myeloma: new evidence and insights from the immunoglobulin heavy chain gene and phenotypes

DNA analysis of the Ig genes has been utilized to delineate the stages of differentiation of normal and malignant B-lineage cells, since the mechanisms involved in V(D)J recombination, somatic hypermutations, and class switch are developmentally regulated. Somatic mutations which result in amino acid substitutions are observed frequently in the Ig variable region genes in multiple myeloma (MM), but there is no intraclonal variation. This fact suggests that the target cell of malignant transformation in MM is a B-lineage cell which already has undergone antigenic selection. This B-lineage cell probably corresponds to a pre-plasma cell or a plasma cell rather than a memory B cell. Tumour cells which share an identical third-complementarity-determining-region (CDR3) sequence with the myeloma cells can be detected from the various fractions representing different stages of B-cell differentiation, such as CD34+, CD20+CD10+, CD20+CD21+, CD20+CD19- cells from the peripheral blood. Thus, the tumour cells in MM are composed of immunophenotypically heterogeneous subpopulations at various stages of differentiation, similar to normal B-lineage cells. These results imply that there is an analogous developmental pathway between the normal B-lineage cells and the tumour cells of MM. Dedifferentiation to the stem cell level may be essential to the malignant transformation in MM.

Formation and resolution of double-strand break intermediates in V(D)J rearrangement

A recently described pre-B cell line can be induced at high temperature to actively rearrange its immunoglobulin light-chain loci. We used this cell line to determine the fate of double-strand breaks generated by V(D)J rearrangement. After induction, 30%-40% of K loci had broken JK1 signal ends. JK1-coding ends were detectable, but 10- to 100-fold less frequent. Both covalently closed (hairpin) and open, blunt, processed coding ends were observed. Coding junctions involving JK1 accumulated with similar kinetics as JK1 signal ends, arguing that coding ends can be resolved quickly and efficiently to coding junctions, whereas signal ends remain mostly unjoined. Signal ends are then joined rapidly when cells are returned to the low temperature. These results support the model that broken signal ends and hairpin coding ends are authentic intermediates in V(D)J recombination. It appears that hairpin coding ends are rapidly opened, processed, and resolved to coding junctions, whereas joining of signal ends is clearly uncoupled from the joining of coding ends and can be much slower. Efficient formation of signal junctions may require cell cycle progression, or down-regulation of the recombination machinery.

Immunoglobulin recombinase gene activity is modulated reciprocally by interleukin 7 and CD19 in B cell progenitors

Bone marrow stromal cells promote B cell development involving recombinase gene-directed rearrangement of the immunoglobulin genes. We observed that the stromal cell-derived cytokine interleukin 7 (IL-7) enhances the expression of CD19 molecules on progenitor B-lineage cells in human bone marrow samples and downregulates the expression of terminal deoxynucleotidyl transferase (TdT) and the recombinase-activating genes RAG-1 and RAG-2. Initiation of the TdT downregulation on the first day of treatment, CD19 upregulation during the second day, and RAG-1 and RAG-2 downmodulation during the third day implied a cascade of IL-7 effects. While CD19 ligation by divalent antibodies had no direct effect on TdT or RAG gene expression, CD19 cross-linkage complete blocked the IL-7 downregulation of RAG expression without affecting the earlier TdT response. These results suggest that signals generated through CD19 and the IL-7 receptor could modulate immunoglobulin gene rearrangement and repertoire diversification during the early stages of B cell differentiation.

Clonal VDJ recombination of the immunoglobulin heavy chain gene by PCR in classical Hodgkin's disease

Although Hodgkin's disease (HD) has been a subject of much investigation, fundamental questions remain unanswered regarding its lineage and clonality. The authors used a polymerase chain reaction (PCR) technique to investigate whether clonal Variable-Diversity-Joining recombination of the immunoglobulin heavy (IgH) chain gene, a phenomenon that characterizes clonal B-cell proliferations, exists in nodular sclerosing (NSHD) and mixed cellularity (MCHD) Hodgkin's disease (so-called "classical" Hodgkin's disease). The isolation of DNA from paraffin-embedded tissue sections allowed for direct correlation of PCR results with the cell populations that were analyzed. Thirty-two cases were studied. These included 12 cases in which the Reed-Sternberg (RS) cells expressed the B-cell antigen, CD20, and 10 cases that were classified as syncytial variant of NSHD (3 CD20+, 7 B-cell antigen negative). Overall, clonal patterns of VDJ PCR products were found in 14 of 32 (44%) cases. These clonal patterns were identified in 7 of 12 (58%) cases of CD20+ classical HD and in 7 of 20 (35%) cases of B-antigen-negative classical HD. Clonal patterns were found in 3 of 10 cases of syncytial variant of NSHD, including 2 of 3 (67%) CD20+ cases and 1 of 7 (14%) B-cell antigen-negative cases. The results of this study provide support that a subset of HD represents a clonal B-cell neoplasm, and indicate that clonal IgH VDJ sequences are more frequently found in CD20+ HD.

Cloning of the murine cDNA encoding VDJP, a protein homologous to the large subunit of replication factor C and bacterial DNA ligases

A putative full-length 1.7-kb cDNA, encoding a murine protein that specifically binds to the nonamer portion of the V(D)J recombinational signal sequence (RSS) element, has been cloned. By its sequence analysis, this cDNA is identical to a portion of the 4.5-kb murine replication factor C large-subunit-encoding cDNA. By Northern blot analysis, the 1.7-kb mRNA species is observed in murine immature B cells but not in non-lymphoid cells and tissues, while the 4.5-kb replication factor C-encoding cDNA is expressed in all cell types. The deduced VDJP amino-acid sequence includes a region of homology with bacterial DNA ligases at the C terminus of each of the proteins. VDJP has been synthesized as a fusion protein in bacteria, and the purified protein has been previously shown to mediate the joining of DNA fragments in a V(D)J RSS-dependent fashion (Guilliams et al., Biochem. Biophys. Res. Commun. 202 (1994) 1134-1141).

V(D)J recombination and allelic exclusion of a TCR beta-chain minilocus occurs in the absence of a functional promoter

Transcriptional activation of rearranging Ag receptor gene segments has been hypothesized to regulate their accessibility to V(D)J recombination. We analyzed the role of a functional promoter in the rearrangement of the murine TCR beta-chain locus using two transgenic minilocus constructs. These miniloci each contain an unrearranged V beta 8.3 gene. One has a wild-type V beta 8.3 gene, but the other has a V beta 8.3 gene with a promoter mutation that was previously shown to abrogate transcription in tissue culture. FACS analysis of thymus and lymph node cells from transgenic mouse lines showed that only the lines with the wild-type V beta 8.3 gene promoter express an 8.3 TCR beta-chain. Consistent with the protein expression data, V beta 8.3 gene transcripts were found only in the transgenic lines with the wild-type promoter. Using a quantitative PCR-based assay, it was shown that both types of transgenic lines recombine the V beta 8.3 gene at similar levels. Rearrangement of the transgenes was normal with respect to thymic development and junctional reading frame. Interestingly, both types of miniloci also underwent allelic exclusion in that recombination was blocked by the expression of a rearranged TCR beta-chain transgene. We conclude that a functional V beta gene promoter is not necessary for proper V(D)J recombination to occur.

A modified tetracycline-regulated system provides autoregulatory, inducible gene expression in cultured cells and transgenic mice

A system for tetracycline-regulated inducible gene expression was described recently which relies on constitutive expression of a tetracycline-controlled transactivator (tTA) fusion protein combining the tetracycline repressor and the transcriptional activation domain of VP16 [Gossen, M. & Bujard, H. (1992) Proc. Natl. Acad. Sci. USA 89, 5547-5551]. This system yielded only low levels of transactivator protein, probably because tTA is toxic. To avoid this difficulty, we placed the tTA gene under the control of the inducible promoter to which tTA binds, making expression of tTA itself inducible and autoregulatory. When used to drive expression of the recombination activating genes 1 and 2 (RAG-1 and RAG-2), the autoregulatory system yielded both substantially higher levels of variable (diversity) joining [V(D)J] recombination activity (70-fold on average) and inducible expression in a much larger fraction of transfected cells (autoregulatory, 90%, vs. constitutive, 18%). In addition, this system allowed the creation of transgenic mice in which expression of a luciferase transgene was inducible tens to hundreds of times the basal levels in most tissues examined. Induced levels of expression were highest in thymus and lung and appear to be substantially higher than in previously reported inducible luciferase transgenic mice created with the constitutive system. With the modified system, inducible transactivator mRNA and protein were easily detected in cell lines by RNA and Western blotting, and transactivator mRNA was detected by RNA blotting in some tissues of transgenic mice. This autoregulatory system represents an improved strategy for tetracycline-regulated gene expression both in cultured cells and in transgenic animals.