Brca1 required for T cell lineage development but not TCR loci rearrangement

Brca1 (breast cancerl, early onset) deficiency results in early embryonic lethality. As Brca1 is highly expressed in the T cell lineage, a T cell-specific disruption of Brca1 was generated to assess the role of Brca1 in relation to T lymphocyte development. We found that thymocyte development in Brca1-/- mice was impaired not as a result of V(D)J T cell receptor (TCR) recombination but because thymocytes had increased expression of tumor protein p53. Chromosomal damage accumulation and abnormal cell death were observed in mutant cells. We found that cell death inhibitor Bcl-2 overexpression, or p53-/- backgrounds, completely restored survival and development of Brca1-/- thymocytes; peripheral T cell numbers were not totally restored in Brcal-/- p53-/- mice; and that a mutant background for p21 (cyclin-dependent kinase inhibitor 1A) did not restore Brca1-/- thymocyte development, but partially restored peripheral T cell development. Thus, the outcome of Brca1 deficiency was dependent on cellular context, with the major defects being increased apoptosis in thymocytes, and defective proliferation in peripheral T cells.     

A new gene involved in DNA double-strand break repair and V(D)J recombination is located on human chromosome 10p

V(D)J recombination, accountable for the diversity of T cell receptor- and immunoglobulin-encoding genes, is initiated by a lymphoid-specific DNA double-strand break. The general DNA repair machinery is responsible for the resolution of this break. Any defect in one of the known components of the DNA repair/V(D)J recombination machinery (Ku70, Ku80, DNA-PKcs, XRCC4 and DNA ligase IV) leads to abortion of the V(D)J rearrangement process, early block in both T and B cell maturation, and ultimately to severe combined immune deficiency (SCID) in several animal models. A human SCID condition is also characterized by an absence of mature T and B lymphocytes, and is associated with an increase in sensitivity to DNA-damaging agents (RS-SCID). None of the above-mentioned genes are defective in these patients, arguing for the likelihood of the existence of yet another unknown component of the V(D)J recombination/DNA repair apparatus. Athabascan-speaking (SCIDA) Navajo and Apache Native Americans have a very high incidence of T(-)B(-)SCID. The SCIDA locus is highly linked with markers on chromosome 10p, although the exact molecular defect has not been recognized in these patients. We show here that cells with the SCIDA defect are impaired in the DNA repair phase of V(D)J recombination similarly to RS-SCID, precisely an absence of V(D)J coding joint formation. Moreover, genotyping analysis in several RS-SCID families corroborates a linkage of the RS-SCID locus to the SCIDA region on chromosome 10p. These results demonstrate the presence of a new essential DNA repair/V(D)J recombination gene in this region, the mutation of which causes RS-SCID in humans.     

Onset of T-cell receptor Vbeta8.1 and Dbeta2.1 V(D)J recombination during thymus development of inbred mouse strains.

The assembling of T-cell receptor (TCR alpha/beta and gamma/delta) genes depends on the V(D)J recombination occurring in early thymocytes during thymus ontogeny. The V(D)J recombination reaction is directed by a recombinase complex from the RAG-1 and RAG-2 genes, and is modulated by several other gene products. Due to the essential role of the TCRbeta in thymocyte differentiation, it is important to define with precision the temporal emergence of the TCRbeta recombination in normal non-manipulated mouse strains. We analysed the onset of V(D)J recombination between TCRVbeta8.1 and Jbeta2.1 gene segments during fetal development of the thymus in three non-manipulated inbred strains of mice; BALB-c, C57BL/6 and CBA. We show that the emergence of the V(D)J recombination at the TCRbeta locus differs among strains, suggesting an in vivo role of the different genetic backgrounds in driving gene rearrangements.     

Distinct roles of c-Abl and Atm in oxidative stress response are mediated by protein kinase C delta

c-Abl and Atm have been implicated in cell responses to DNA damage and oxidative stress. However, the molecular mechanisms by which they regulate oxidative stress response remain unclear. In this report, we show that deficiency of c-Abl and deficiency of ATM differentially altered cell responses to oxidative stress by induction of antioxidant protein peroxiredoxin I (Prx I) via Nrf2 and cell death, both of which required protein kinase C (PKC) delta activation and were mediated by reactive oxygen species. c-abl-/- osteoblasts displayed enhanced Prx I induction, elevated Nrf2 levels, and hypersusceptibility to arsenate, which were reinstated by reconstitution of c-Abl; Atm-/- osteoblasts showed the opposite. These phenotypes correlated with increased PKC delta expression in c-abl-/- osteoblasts and decreased PKC delta expression in Atm-/- cells, respectively. The enhanced responses of c-abl-/- osteoblasts could be mimicked by overexpression of PKC delta in normal cells and impeded by inhibition of PKC delta, and diminished responses of Atm-/- cells could be rescued by PKC delta overexpression, indicating that PKC delta mediated the effects of c-Abl and ATM in oxidative stress response. Hence, our results unveiled a previously unrecognized mechanism by which c-Abl and Atm participate in oxidative stress response.     

Late degeneration of nigro-striatal neurons in ATM-/- mice

The generation of an Atm -/- mouse model of the human ataxia-telangiectasia (AT) opened new avenues toward a better understanding of the molecular and cellular basis of AT. We have recently reported that 5-month-old Atm-/- mice exhibit severe loss of tyrosine hydroxylase-positive, dopaminergic nigro-striatal neurons, down to 26% of age-matched controls. In the present study we analyzed development of the dopaminergic cell loss in the context of the nigro-striatal system. We found that dopaminergic neurons are formed normally in the Atm-/- mouse, and degenerate during the first few months of life; there was no difference between 1-month-old Atm-/- and control mice in the number of dopaminergic cells that were retrogradely labeled by an injection of fluorescent tracer into the striatum. On the other hand, a dramatic reduction in the number of labeled cells was found in 5-month-old Atm-/- mice. This cell loss was significant in areas A9 and A10 but not in area A9-I. These findings indicate that midbrain dopaminergic neurons in Atm-/- mice initially send normal axons to the striatum, only to degenerate later in life. In addition, an age-dependent as well as topographic, medial-to-lateral loss of GAD, met-enkephaline and substance-P immunopositive cells was found in the striatum of the Atm-/- mice. This phenomenon was significant only in the 5-month-old Atm-/- mice (3 months after the beginning of detectable dopaminergic cell loss). In both the striatum and the substantia nigra, the apparent cell loss was accompanied by gliosis. In addition, alpha-synuclein immunopositive bodies were observed in the cortex, striatum and substantia nigra of these mice. The present data indicate that Atm-/- mice exhibit a progressive, age-dependent, reduction in dopaminergic cells of the substantia nigra, followed by a reduction in projection neurons of the striatum. Thus, the Atm-/- mouse may model the extrapyramidal motor deficits seen in AT patients.     

DNA sequence analysis of interlocus recombination between the human T-cell receptor gamma variable (GV) and beta diversity-joining (BD/BJ) sequences on chromosome 7 (inversion 7)

V(D)J recombinase-mediated recombination between the T-cell receptor (TCR) gamma variable (GV) genes at chromosome 7p15 and the TCR beta joining (BJ) genes at 7q35 leads to the formation of a hybrid TCR gene. These TCR gamma/beta interlocus rearrangements occur at classic V(D)J recombination signal sequences (RSS) and, because the loci are in an inverted orientation, result in inversion events that are detectable in the chromosome structure as inv(7)(p15;q35). Similar rearrangements involving oncogenes and either TCR or immunoglobulin genes mediated by the V(D)J recombinase are found in lymphoid malignancies. Oligonucleotide primers that allow polymerase chain reaction (PCR) amplification across the inv(7) genomic recombination junction sequence have been described. Southern blot analysis has been primarily used to confirm the GV/BJ hybrid nature of the product, with limited information on the DNA sequence of these recombinations. We have modified this PCR method using total genomic DNA from the mononuclear cells in peripheral blood samples to increase specificity and to allow direct sequencing of the translocation junction that results from the recombination between the GV1 and BJ1 families of TCR genes in 25 examples from 11 individuals (three adults, one child, six newborns, and one ataxia telangiectasia (AT) patient). We focused on samples from newborns based on previous studies indicating that the predominant hypoxanthine-guanine phosphoribosyl transferase (HPRT) mutations in newborns are V(D)J recombinase-mediated deletion events and that the frequency of these mutations decreases with increasing age. Although the dilution series-based PCR assay utilized does not yield sharply defined quantitative endpoints, results of this study strongly suggest that inv(7) recombinations in newborns occur at equal or lower frequencies than those seen in adults. Consistent with the PCR primer pairs, all sequenced products contain a GV1 and a BJ1 segment and most also contain a BD1 segment. GV1s2 and 1s4 were the most frequently found GV1 genes (8 and 9 examples, respectively) and BJ1s5 and 1s6 were the most frequently found BJ1 genes (9 and 10 examples, respectively). These results demonstrate the effectiveness of this methodology for assessing GV/BJ interlocus rearrangements mediated by V(D)J recombinase.     

In vivo ligation of CD3 on neonatal scid thymocytes blocks gamma-irradiation-induced TCRbeta rearrangements and thymic lymphomagenesis

Several studies have shown that the developmental arrest of severe combined immune deficiency (scid) thymocytes during the CD4(-)CD8(-) double negative (DN) to CD4(+)CD8(+) double positive (DP) transition can be overcome by a sub-lethal dose of ionizing radiation (IR). Concurrent with this developmental progression, IR also induces variable (diversity) joining (V(D)J) recombination at T cell receptor (TCR), delta, beta, and gamma, but not alpha loci. In addition, all irradiated scid mice succumb to thymic lymphoma. In this study, we demonstrate that scid neonates treated with anti-CD3 epsilon antibody become more resistant to the development of thymoma upon exposure to IR. It is known that the anti-CD3 epsilon antibody treatment induces T cell progression to the DP stage bypassing TCRbeta rearrangement. We show here that the resistance to tumor development is correlated with a reduction of TCRbeta rearrangements that are induced by IR. However, TCRgamma rearrangements were not altered by the antibody treatment. The particular effect of anti-CD3 epsilon antibody on TCRbeta rearrangements is likely attributed to a decline of the double negative thymocyte subset (DN3), in which TCRbeta rearrangements predominantly occur. These results suggest that the developmental stage of scid thymocytes can influence the effect of IR on TCR rearrangements as well as lymphomagenesis.     

T cell receptor DJ but not VDJ rearrangement within a recombination substrate introduced into a pre-B cell line

To elucidate mechanisms that regulate ordered and tissue-specific assembly of Ig and TCR variable region gene segments, we have introduced a recombination substrate comprised of germline TCR beta V, D, and J gene segments into an Abelson murine leukemia virus-transformed pre-B cell line that actively rearranges endogenous Ig H chain variable region gene segments but does not rearrange endogenous light chain or TCR variable region gene segments. We find that these cells efficiently join D beta segments to J beta segments within the mini-locus, but that they do not make any detectable site-specific rearrangements of the introduced V beta segment even though it is closely linked in the same construct to the D beta. These findings suggest that factors necessary for V beta to (D beta)J beta joining may be absent in these pre-B cells and also imply that the order in which TCR V beta, D beta, and J beta segments are rearranged can be influenced by factors other than the 12/23 recombination rule. Furthermore, in agreement with the an accessibility model of VDJ recombinase control, the D beta region of the construct was found to be relatively more sensitive to DNAase I digestion in isolated nuclei when compared to the unrearranged V beta region.     

Comparative analysis of invertebrate Tc6 sequences that resemble the vertebrate V(D)J recombination signal sequences (RSS).

Invertebrate cells lack the p53 recombination checkpoint but contain mobile DNA sequences that transpose by a mechanism in part shared with excision of the V(D)J recombination signal sequences (RSS). In this work, inversion, deletion, and duplication of sequences associated with an invertebrate C. elegans Tc6 element is described. The structure of this C. elegans sequence and other dispersed Tc6 elements suggests that covalently closed 'hairpin' structures are not unique to excision of the V(D)J RSS by the RAG proteins, but rather can be generated by transposases at transposon termini leading to characteristic inversion and duplication events. Comparative analysis of recombination events at invertebrate sequences resembling the vertebrate V(D)J RSS may be useful in understanding V(D)J recombination-mediated recombination events in malignant vertebrate cells or genetic diseases such as ataxia telangectasia, in which the p53 recombination checkpoint is defective.     

Thymocyte differentiation in γ-irradiated severe-combined immunodeficient mice: characterization of intermediates and products of V(D)J recombination at the T cell receptor α locus

Treatment with DNA-damaging agents promotes rescue of V(D)J recombination, limited thymocyte differentiation, and development of thymic lymphomas in severe-combined immunodeficient (SCID) mice. One intriguing aspect of this system is that irradiation rescues rearrangements at the T cell receptor (TCR) β, γ and δ loci, but not at the TCR α locus. Current models posit that only those loci that are recombinationally active at the time of irradiation can be rescued. Here, we employ sensitive, semiquantitative ligation-mediated polymerase chain reaction assays to detect a specific class of recombination intermediates, hairpin coding ends, at the TCR α locus. We found that Jα-coding ends are undetectable in unirradiated SCID thymocytes, but accumulate after irradiation at times coincident with the emergence of a CD4⁺CD8⁺ thymocyte population. Coding joints produced by joining of these ends, however, are extremely rare. To test whether the presence of hairpin coding ends at TCR α is sufficient for irradiation-mediated rescue of coding joint formation, we administered a second dose of γ-irradiation after abundant CD4⁺ CD8⁺ thymocytes and hairpin TCR α coding ends had accumulated. This treatment failed to stimulate rescue of TCR α coding joints. Thus, the presence of hairpin coding ends at the time of irradiation, while perhaps necessary, is not sufficient for rescue of V(D)J rearrangements. These results support a refined model for irradiation-mediated rescue of TCR rearrangements in SCID mice.     

Coupling of V(D)J recombination to the cell cycle suppresses genomic instability and lymphoid tumorigenesis

V(D)J gene segment recombination is linked to the cell cycle by the periodic phosphorylation and destruction of the RAG-2 protein at the G1-to-S cell cycle transition. To examine the function of this coupling, we constructed mice in which the phosphorylation site at threonine 490 of RAG-2 was mutated to alanine. The RAG-2(T490A) mutation uncoupled DNA cleavage from cell cycle and promoted aberrant recombination. Similar aberrant recombination products were observed in mice deficient in the Skp2 ubiquitin ligase subunit, which is required for periodic destruction of RAG-2. On a p53-deficient background, the RAG-2(T490A) mutation induced lymphoid malignancies characterized by clonal chromosomal translocations involving antigen receptor genes. Taken together, these observations provide a direct link between the periodic destruction of RAG-2 and lymphoid tumorigenesis. We infer that cell cycle control of the V(D)J recombinase limits the potential genomic damage that could otherwise result from RAG-mediated DNA cleavage.     

Excision products of TCR V{alpha} recombination contain in-frame rearrangements: evidence for continued V(D)J recombination in TCR+ thymocytes

Cortical thymocytes that express a TCR on their surface continueto express mRNA for the recombination activating genes RAG-1and RAG-2. As the expression of these genes appears to be necessaryand sufficient for V(D)J recombination to occur, this findingsuggests that productive TCR gene rearrangement may not by itselfterminate TCR recombination. To further study this question,we have utilized a polymerase chain reaction-based strategyto isolate and sequence excision products of secondary TCR generearrangement events. Our data shows that TCR excision productsfrom TCR⁺ thymocytes contain in-frame V–J joints and thussupport the concept that V(D)J recombinatorial activity maycontinue even in thymocytes which have undergone productiveTCR gene rearrangement.     

Epigenetic control of Tcrb gene rearrangement

V(D)J recombination assembles antigen receptor genes from germline V, D and J segments during lymphocyte development. In αβT-cells, this leads to the subsequent expression of T-cell receptor (TCR) β and α chains. Generally, V(D)J recombination is closely controlled at various levels, including cell-type and cell-stage specificities, order of locus/gene segment recombination, and allele usage to mediate allelic exclusion. Many of these controls rely on the modulation of gene accessibility to the recombination machinery, involving not only biochemical changes in chromatin arrangement and structural modifications of chromosomal organization and positioning, but also the refined composition of the recombinase targets, the so-called recombination signal sequences. Here, we summarize current knowledge regarding the regulation of V(D)J recombination at the Tcrb gene locus, certainly one for which these various levels of control and regulatory components have been most extensively investigated.     

Increased frequency of RAG-expressing, CD4(+)CD3(low) peripheral T lymphocytes in patients with defective responses to DNA damage

Accumulating evidence indicates that peripheral lymphocyte variants with altered antigen receptor expression may be capable of expressing recombination-activating genes (RAG). We and others recently observed functional RAG gene products in mature T cells with defective TCR expression (MacMahan and Fink, Immunity 1998. 9: 637 - 647; Lantelme et al., J. Immunol., 2000. 164: 3455 - 3459). Here, the association between TCR expression and RAG activity was assessed further in lymphocytes from patients with defective responses to DNA damage. We show that T cells with altered TCR surface expression are present in increased numbers in these patients and that they express RAG genes. The finding of RAG gene expression by TCR variants suggests the possibility that secondary V(D)J rearrangements could be induced in these cells to rescue their defective phenotype and cellular function. Moreover, as V(D)J recombination has been implicated in chromosome translocations involving antigen receptor genes, we discuss a possible relationship between altered TCR expression, RAG activity and the frequent lymphoma-specific translocations observed in these patients.