V-D-J rearrangements at the T cell receptor delta locus in mouse thymocytes of the alpha beta lineage

Trav15-dv6 family Tcrd rearrangements diversify the Tcra repertoire

The Tcra repertoire is generated by multiple rounds of V_α-J_α rearrangement. However, Tcrd recombination precedes Tcra recombination within the complex Tcra-Tcrd locus. Here, by ablating Tcrd recombination, we report that Tcrd rearrangement broadens primary V_α use to diversify the Tcra repertoire in mice. We reveal that use of Trav15-dv6 family V gene segments in Tcrd recombination imparts diversity in the Tcra repertoire by instigating use of central and distal V_α segments. Moreover, disruption of the regions containing these genes and their cis-regulatory elements identifies the Trav15-dv6 family as being responsible for driving central and distal V_α recombinations beyond their roles as substrates for Tcrd recombination. Our study demonstrates an indispensable role for Tcrd recombination in general, and the Trav15-dv6 family in particular, in the generation of a combinatorially diverse Tcra repertoire.

Tcrd Rearrangement Redirects a Processive Tcra Recombination Program to Expand the Tcra Repertoire

Adaptive immunity depends on diverse T cell receptor repertoires generated by variable, diversity, and joining (V[D]J) recombination. Here, we define the principles by which combinatorial diversity is generated in the murine Tcra repertoire. Tcra and Tcrd gene segments share the Tcra-Tcrd locus, with interspersed V_α and V_δ segments undergoing V_δ-D_δ-J_δ rearrangement in CD4^-CD8^- thymocytes and then multiple rounds of V_α-J_α rearrangement in CD4⁺CD8⁺ thymocytes. We document stepwise, highly coordinated proximal-to-distal progressions of V_α and J_α use on individual Tcra alleles, limiting combinatorial diversity. This behavior is supported by an extended chromatin conformation in CD4⁺CD8⁺ thymocytes, with only nearby V_α and J_α segments contacting each other. Tcrd rearrangements can use distal V_δ segments due to a contracted Tcra-Tcrd conformation in CD4^-CD8^- thymocytes. These rearrangements expand the Tcra repertoire by truncating the V_α array to permit otherwise disfavored V_α-J_α combinations. Therefore, recombination events at two developmental stages with distinct chromatin conformations synergize to promote Tcra repertoire diversity.

Visualization and quantification of monoallelic TCRα gene rearrangement in αβ T cells

T-cell receptor α (TCRα) chain rearrangement is not constrained by allelic exclusion and thus αβ T cells frequently have rearranged both alleles of this locus. Thereby, stepwise secondary rearrangements of both TCRα loci further increase the odds for generation of an α-chain that can be positively selected in combination with a pre-existing TCRβ chain. Previous studies estimated that approximately 2-12% of murine and human αβ T cells still carry one TCRα locus in germline configuration, which must comprise a partially or even fully rearranged TCRδ locus. However, these estimates are based on a relatively small amount of individual αβ T-cell clones and αβ T-cell hybridomas analyzed to date. To address this issue more accurately, we made use of a mouse model, in which a fluorescent reporter protein is introduced into the constant region of the TCRδ locus. In this TcrdH2BeGFP system, fluorescence emanating from retained TCRδ loci enabled us to quantify monoallelically rearranged αβ T cells on a single-cell basis. Via fluorescence-activated cell sorting analysis, we determined the frequency of monoallelic TCRα rearrangements to be 1.7% in both peripheral CD4(+) and CD8(+) αβ T cells. Furthermore, we found a skewed 5' Jα gene utilization of the rearranged TCRα allele in T cells with monoallelic TCRα rearrangements. This is in line with previous descriptions of a tight interallelic positional coincidence of Jα gene segments used on both TCRα alleles. Finally, analysis of T cells from transgenic mice harboring only one functional TCRα locus implied the existence of very rare unusual translocation or episomal reintegration events of formerly excised TCRδ loci.

Direct reduction of antigen receptor expression in polyclonal B cell populations developing in vivo results in light chain receptor editing

Secondary Ab V region gene segment rearrangement, termed receptor editing, is a major mechanism contributing to B lymphocyte self-tolerance. However, the parameters that determine whether a B cell undergoes editing are a current subject of debate. We tested the role that the level of BCR expression plays in the regulation of receptor editing in a polyclonal population of B cells differentiating in vivo. Expression of a short hairpin RNA for κ L chain RNA in B cells resulted in reduction in levels of this RNA and surface BCRs. Strikingly, fully mature and functional B cells that developed in vivo and efficiently expressed the short hairpin RNA predominantly expressed BCRs containing λ light chains. This shift in L chain repertoire was accompanied by inhibition of development, increased Rag gene expression, and increased λ V gene segment-cleavage events at the immature B cell stage. These data demonstrated that reducing the translation of BCRs that are members of the natural repertoire at the immature B cell stage is sufficient to promote editing.

Mechanics of T cell receptor gene rearrangement

The four T cell receptor genes (Tcra, Tcrb, Tcrg, Tcrd) are assembled by V(D)J recombination according to distinct programs during intrathymic T cell development. These programs depend on genetic factors, including gene segment order and recombination signal sequences. They also depend on epigenetic factors. Regulated changes in chromatin structure, directed by enhancers and promoter, can modify the availability of recombination signal sequences to the RAG recombinase. Regulated changes in locus conformation may control the synapsis of distant recombination signal sequences, and regulated changes in subnuclear positioning may influence locus recombination events by unknown mechanisms. Together these influences may explain the ordered activation and inactivation of T cell receptor locus recombination events and the phenomenon of Tcrb allelic exclusion.

The magnitude of thymic output is genetically determined through controlled intrathymic precursor T cell proliferation

The thymus plays a crucial role in providing the immune system with naive T cells showing a diverse TCR repertoire. Whereas the diversity of thymic production is mainly ensured by TCR rearrangement at both the TRA and TRB loci, the number of cells reaching the double-positive differentiation stage defines the extent of thymic output. A quantitative analysis of TCR excision circles (TREC; signal-joint TRECs and DJbetaTRECs) produced at different stages of thymopoiesis was performed in nine laboratory mouse strains. The results clearly demonstrate that the magnitude of thymic output is directly proportional to the extent of proliferation in the double-negative 4 thymocyte subset. Strikingly, intrathymic precursor T cell proliferation was found to be strain dependent, thus suggesting a genetic regulation of thymic output. The inherited character of thymic output was further confirmed by the transmission of the phenotype in a recessive fashion in F(1) progeny of the different parental strains. Our results provide the first demonstration of the genetic regulation of thymic output.

Antigen receptor editing in anti-DNA transitional B cells deficient for surface IgM

In response to encounter with self-Ag, autoreactive B cells may undergo secondary L chain gene rearrangement (receptor editing) and change the specificity of their Ag receptor. Knowing at what differentiative stage(s) developing B cells undergo receptor editing is important for understanding how self-reactive B cells are regulated. In this study, in mice with Ig transgenes coding for anti-self (DNA) Ab, we report dsDNA breaks indicative of ongoing secondary L chain rearrangement not only in bone marrow cells with a pre-B/B cell phenotype but also in immature/transitional splenic B cells with little or no surface IgM (sIgM(-/low)). L chain-edited transgenic B cells were detectable in spleen but not bone marrow and were still found to produce Ab specific for DNA (and apoptotic cells), albeit with lower affinity for DNA than the unedited transgenic Ab. We conclude that L chain editing in anti-DNA-transgenic B cells is not only ongoing in bone marrow but also in spleen. Indeed, transfer of sIgM(-/low) anti-DNA splenic B cells into SCID mice resulted in the appearance of a L chain editor (Vlambdax) in the serum of engrafted recipients. Finally, we also report evidence for ongoing L chain editing in sIgM(low) transitional splenic B cells of wild-type mice.

The TCRalpha locus control region specifies thymic, but not peripheral, patterns of TCRalpha gene expression

The molecular mechanisms ensuring the ordered expression of TCR genes are critical for proper T cell development. The mouse TCR alpha-chain gene locus contains a cis-acting locus control region (LCR) that has been shown to direct integration site-independent, lymphoid organ-specific expression of transgenes in vivo. However, the fine cell type specificity and developmental timing of TCRalpha LCR activity are both still unknown. To address these questions, we established a transgenic reporter model of TCRalpha LCR function that allows for analysis of LCR activity in individual cells by the use of flow cytometry. In this study we report the activation of TCRalpha LCR activity at the CD4-CD8-CD25-CD44- stage of thymocyte development that coincides with the onset of endogenous TCRalpha gene rearrangement and expression. Surprisingly, TCRalpha LCR activity appears to decrease in peripheral T cells where TCRalpha mRNA is normally up-regulated. Furthermore, LCR-linked transgene activity is evident in gammadelta T cells and B cells. These data show that the LCR has all the elements required to reliably reproduce a developmentally correct TCRalpha-like expression pattern during thymic development and unexpectedly indicate that separate gene regulatory mechanisms are acting on the TCRalpha gene in peripheral T cells to ensure its high level and fine cell type-specific expression.

Real-time PCR method for the quantitative analysis of human T-cell receptor gamma and beta gene rearrangements

Analyzing the status of T-cell receptor (TCR) gene rearrangements has been an essential part of deciphering the stages of thymocyte development, understanding the alphabeta vs. gammadelta lineage decision, and characterizing T-cell leukemias. Methods such as PCR and quantitative Southern blotting provide useful information, but also have significant shortcomings such as lack of quantitation in the case of PCR and technical challenges in the case of Southern blotting. Here we describe a real-time PCR method that overcomes many of these shortcomings. This new method shows comparable results for the fraction of unrearranged TCRgamma and TCRbeta genes in human thymocytes and peripheral blood T cells as Southern blotting, and has the advantages of being simple to perform, highly quantitative, and requiring nanogram quantities of DNA. We also describe a real-time PCR method to quantitate T-cell receptor excision circles formed during TCRbeta rearrangements.

Variable diversity joining recombination: nonhairpin coding ends in thymocytes of SCID and wild-type mice

Initiation of V(D)J recombination results in broken DNA molecules with blunt recombination signal ends and covalently sealed (hairpin) coding ends. In SCID mice, coding joint formation is severely impaired and hairpin coding ends accumulate as a result of a deficiency in the catalytic subunit of DNA-dependent protein kinase, an enzyme involved in the repair of DNA double-strand breaks. In this study, we report that not all SCID coding ends are hairpinned. We have detected open Jdelta1 and Ddelta2 coding ends at the TCRdelta locus in SCID thymocytes. Approximately 25% of 5'Ddelta2 coding ends were found to be open. Large deletions and abnormally long P nucleotide additions typical of SCID Ddelta2-Jdelta1 coding joints were not observed. Most Jdelta1 and Ddelta2 coding ends exhibited 3' overhangs, but at least 20% had unique 5' overhangs not previously detected in vivo. We suggest that the SCID DNA-dependent protein kinase deficiency not only reduces the efficiency of hairpin opening, but also may affect the specificity of hairpin nicking, as well as the efficiency of joining open coding ends.

Increased cell division but not thymic dysfunction rapidly affects the T-cell receptor excision circle content of the naive T cell population in HIV-1 infection

Recent thymic emigrants can be identified by T cell receptor excision circles (TRECs) formed during T-cell receptor rearrangement. Decreasing numbers of TRECs have been observed with aging and in human immunodeficiency virus (HIV)-1 infected individuals, suggesting thymic impairment. Here, we show that in healthy individuals, declining thymic output will affect the TREC content only when accompanied by naive T-cell division. The rapid decline in TRECs observed during HIV-1 infection and the increase following HAART are better explained not by thymic impairment, but by changes in peripheral T-cell division rates. Our data indicate that TREC content in healthy individuals is only indirectly related to thymic output, and in HIV-1 infection is mainly affected by immune activation.

Role of gut cryptopatches in early extrathymic maturation of intestinal intraepithelial T cells

Lympho-hemopoietic progenitors residing in murine gut cryptopatches (CP) have been shown to generate intestinal intraepithelial T cells (IEL). To investigate the role of CP in progenitor maturation, we analyzed IEL in male mice with a truncated mutation of common cytokine receptor gamma-chain (CRgamma-/Y) in which CP were undetectable. IEL-expressing TCR-gammadelta (gammadelta-IEL) were absent, and a drastically reduced number of Thy-1highCD4+ and Thy-1highCD8alphabeta+ alphabeta-IEL were present in CRgamma-/Y mice, whereas these alphabeta-IEL disappeared from athymic CRgamma-/Y littermate mice. Athymic CRgamma-/Y mice possessed a small TCR- and alphaEbeta7 integrin-negative IEL population, characterized by the disappearance of the extrathymic CD8alphaalpha+ subset, that expressed pre-Talpha, RAG-2, and TCR-Cbeta but not CD3epsilon transcripts. These TCR- IEL from athymic CRgamma-/Y mice did not undergo Dbeta-Jbeta and Vdelta-Jdelta joinings, despite normal rearrangements at the TCR-beta and -delta loci in thymocytes from euthymic CRgamma-/Y mice. In contrast, athymic severe combined immunodeficient mice in which CP developed normally possessed two major TCR-alphaEbeta7+ CD8alphaalpha+ and CD8- IEL populations that expressed pre-Talpha, RAG-2, TCR-Cbeta, and CD3epsilon transcripts. These findings underscore the role of gut CP in the early extrathymic maturation of CD8alphaalpha+ IEL, including cell-surface expression of alphaEbeta7 integrin, CD3epsilon gene transcription, and TCR gene rearrangements.

Early activation of TCR alpha gene rearrangement in fetal thymocytes

We have previously demonstrated that the onset of TCR alpha gene rearrangement is mainly restricted to the J alpha50 gene in fetal day 1delta thymocyte hybridomas. Now, J alpha50 rearrangements from fetal thymocyte hybridomas and from day 15.5 fetal thymus have been isolated and sequenced. We demonstrate that J alpha50 is rearranged to the rearranged Vdelta1 Ddelta2 gene segment. This indicates that the TCR alpha rearrangement process is initiated in fetal thymocytes far earlier than previously thought. These thymocytes have their delta genes still accessible for rearrangement and therefore, are controlled by the TCR delta enhancer (Edelta) (and/or another TCR delta specific cis-acting element). Our results further suggest that both Edelta and the TCR alpha enhancer (Ealpha) are active at the onset of alpha rearrangements or alternatively, the initial activation of the J alpha locus is controlled by Edelta. In addition, Vdelta1 Ddelta2 J alpha50 gene segments are replaced by secondary alpha rearrangements, indicating that thymocytes with the early alpha rearrangement are committed to the alphabeta lineage.

A developmental switch from TCR delta enhancer to TCR alpha enhancer function during thymocyte maturation

V(D)J recombination and transcription within the TCR alpha/delta locus are regulated by three characterized cis-acting elements: the TCR delta enhancer (Edelta), TCR alpha enhancer (Ealpha), and T early alpha (TEA) promoter. Analysis of enhancer and promoter occupancy and function in developing thymocytes in vivo indicates Edelta and Ealpha to be developmental-stage-specific enhancers, with Edelta "on" and Ealpha "off" in double-negative III thymocytes and Edelta "off" and Ealpha "on" in double-positive thymocytes. Edelta downregulation reflects a loss of occupancy. Surprisingly, Ealpha and TEA are extensively occupied even prior to activation. TCR delta downregulation in double-positive thymocytes depends on two events, Edelta inactivation and removal of TCR delta from the influence of Ealpha by chromosomal excision.

Developmental regulation of TCR delta locus accessibility and expression by the TCR delta enhancer

We have used gene-targeted mutation to assess the role of the T cell receptor delta (TCR delta) enhancer (E delta) in alphabeta and gammadelta T cell development. Mice lacking E delta exhibited no defects in alphabeta T cell development but had a severe reduction in thymic and peripheral gammadelta T cells and decreased VDJ delta rearrangements. Simultaneous deletion of both E delta and the TCR alpha enhancer (E alpha) demonstrated that residual TCR delta rearrangements were not driven by E alpha, implicating additional elements in TCR delta locus accessibility. Surprisingly, while deletion of E delta severely impaired germline TCR delta expression in double-negative thymocytes, absence of E delta did not affect expression of mature delta transcripts in gammadelta T cells. We conclude that E delta has an important role in TCR delta locus regulation at early, but not late, stages of gammadelta T cell development.

Characterization of TCR Gene Rearrangements During Adult Murine T Cell Development

Development of the αβ and γδ T cell lineages is dependent upon the rearrangement and expression of the TCRα and β or γ and δ genes, respectively. Although the timing and sequence of rearrangements of the TCRα and TCRβ loci in adult murine thymic precursors has been characterized, no similar information is available for the TCRγ and TCRδ loci. In this report, we show that approximately half of the total TCRδ alleles initiate rearrangements at the CD44highCD25+ stage, whereas the TCRβ locus is mainly in germline configuration. In the subsequent CD44lowCD25+ stage, most TCRδ alleles are fully recombined, whereas TCRβ rearrangements are only complete on 10–30% of alleles. These results indicate that rearrangement at the TCRδ locus can precede that of TCRβ locus recombination by one developmental stage. In addition, we find a bias toward productive rearrangements of both TCRδ and TCRγ genes among CD44highCD25+ thymocytes, suggesting that functional γδ TCR complexes can be formed before the rearrangement of TCRβ. These data support a model of lineage commitment in which sequential TCR gene rearrangements may influence αβ/γδ lineage decisions. Further, because TCR gene rearrangements are generally limited to T lineage cells, these analyses provide molecular evidence that irreversible commitment to the T lineage can occur as early as the CD44highCD25+ stage of development.

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.

Developmental regulation of V(D)J recombination at the TCR alpha/delta locus

The T-cell receptor (TCR) alpha/delta locus includes a large number of V, D, J and C gene segments that are used to produce functional TCR delta and TCR alpha chains expressed by distinct subsets of T lymphocytes. V(D)J recombination events within the locus are regulated as a function of developmental stage and cell lineage during T-lymphocyte differentiation in the thymus. The process of V(D)J recombination is regulated by cis-acting elements that modulate the accessibility of chromosomal substrates to the recombinase. Here we evaluate how the assembly of transcription factor complexes onto enhancers, promoters and other regulatory elements within the TCR alpha/delta locus imparts developmental control to VDJ delta and VJ alpha rearrangement events. Furthermore, we develop the notion that within a complex locus such as the TCR alpha/delta locus, highly localized and region-specific control is likely to require an interplay between positive regulatory elements and blocking or boundary elements that restrict the influence of the positive elements to defined regions of the locus.

Crucial function of the pre-T-cell receptor (TCR) in TCR beta selection, TCR beta allelic exclusion and alpha beta versus gamma delta lineage commitment

The analysis of T-cell receptor (TCR) beta selection, TCR beta allelic exclusion and TCR beta rearrangement in gamma delta T cells from normal and pre-TCR-deficient mice has shown that the pre-TCR has a crucial role in T-lymphocyte development: The pre-TCR is by far the most effective receptor that generates large numbers of CD4+8+ T cells with productive TCR beta rearrangements. In the absence of the pre-TCR, TCR beta rearrangement proceeds in developing cells irrespective of whether they already contain a productive TCR beta gene. The pre-TCR directs developing T cells to the alpha beta lineage because gamma delta T cells from pT alpha-/- mice proceed much further in TCR beta rearrangement than gamma delta T cells from wild-type mice. It is argued that the pre-TCR commits developing T cells to the alpha beta lineage by an instructive mechanism, which has largely replaced an evolutionarily more ancient mechanism that involves stochastic alpha beta lineage commitment.

Alternative splicing of rearranged T cell receptor delta sequences to the constant region of the alpha locus

The T cell receptor (TCR) alpha/delta locus is composed of a common, shared set of variable (V) and distinct diversity (D), joining (J), and constant (C) genes. It has been recognized for several years that transcripts of the rearranged VDJdelta or VJalpha genes are spliced to the Cdelta or Calpha genes, respectively, encoding distinct TCR delta and alpha proteins. Herein, we describe the discovery of a splicing variation that allows the assembled VDJdelta genes to be fused with the Calpha gene. This variation is prominent in TCRdelta gene-deficient mice but is also detectable in wild-type mice. Furthermore, we show that several in-frame VDJdelta rearrangements in TCRdelta gene-deficient mice are strikingly underrepresented, suggesting that the alternative transcripts, with protein coding capacity, influence the development of alphabeta thymocytes. In-frame TCRgamma gene rearrangements do not appear underrepresented, indicating that the effect is not mediated by the gamma chain. Instead, indirect evidence supports the hypothesis that the delta/alpha chimeric protein acts in conjunction with the TCRbeta chain. These results have implications for the transcriptional control of the TCRalpha/delta locus and provide a novel insight into the distinct functional capacities of the TCR alpha and delta proteins during thymocyte development.

The common cytokine receptor gamma chain controls survival of gamma/delta T cells

We have investigated the role of common gamma chain (gamma c)-signaling pathways for the development of T cell receptor for antigen (TCR)-gamma/delta T cells. TCR-gamma/delta-bearing cells were absent from the adult thymus, spleen, and skin of gamma c-deficient (gamma c-) mice, whereas small numbers of thymocytes expressing low levels of TCR-gamma/delta were detected during fetal life. Recent reports have suggested that signaling via interleukin (IL)-7 plays a major role in facilitating TCR-gamma/delta development through induction of V-J (variable-joining) rearrangements at the TCR-gamma locus. In contrast, we detected clearly TCR-gamma rearrangements in fetal thymi from gamma c- mice (which fail to signal in response to IL-7) and reduced TCR-gamma rearrangements in adult gamma c thymi. No gross defects in TCR-delta or TCR-beta rearrangements were observed in gamma c- mice of any age. Introduction of productively rearranged TCR V gamma 1 or TCR V gamma 1/V delta 6 transgenes onto mice bearing the gamma c mutation did not restore TCR-gamma/delta development to normal levels suggesting that gamma c-dependent pathways provide additional signals to developing gamma/delta T cells other than for the recombination process. Bcl-2 levels in transgenic thymocytes from gamma c- mice were dramatically reduced compared to gamma c+ transgenic littermates. We favor the concept that gamma c-dependent receptors are required for the maintenance of TCR-gamma/delta cells and contribute to the completion of TCR-gamma rearrangements primarily by promoting survival of cells committed to the TCR-gamma/delta lineage.

Function of the TCR alpha enhancer in alphabeta and gammadelta T cells

We have used gene targeted mutational approaches to assess the role of the T cell receptor alpha (TCR alpha) enhancer (E alpha) in the control of TCR alpha and TCR delta gene rearrangement and expression. We show that E alpha functions in cis to promote V alpha to J alpha rearrangement across the entire J alpha locus, a distance of greater than 70 kb. We also show that E alpha is required for normal alphabeta T cell development; in this lineage, E alpha is required for germline J alpha expression, for normal expression levels of rearranged V alpha J alpha genes, and for expression of a diverse V alpha repertoire. In gamma delta T cells, E alpha is not required for VdeltaDJdelta rearrangement, but, surprisingly, is required for normal expression levels of mature VdeltaDJdelta transcripts and for expression of germline J alpha transcripts. Our findings imply that E alpha function is not limited to the TCR alpha components of the TCRalpha/delta locus or to the alpha beta lineage; rather, E alpha function is important in both alphabeta and gammadelta lineage T cells.

Cryptic signals and the fidelity of V(D)J joining

V(D)J recombination is responsible for the de novo creation of antigen receptor genes in T- and B-cell precursors. To the extent that lymphopoiesis takes place throughout an animal's lifetime, recombination errors present an ongoing problem. One type of aberrant rearrangement ensues when DNA sequences resembling a V(D)J joining signal are targeted by mistake. This study investigates the type of sequence likely to be subject to mistargeting, the level of joining-signal function associated with these sequences, and the number of such cryptic joining signals in the genome.

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.

Characterization of excised DNA intermediates associated with V(D)J recombination at the T-cell receptor delta locus

Lymphocyte development requires the assembly of antigen receptor genes through the specialized process of V(D)J recombination. This process is initiated by cleavage at the junction between coding segments (V, D, and J) and the recombination signal sequences that border these segments, resulting in generation of double-strand break intermediates. We have used a two-dimensional gel system to characterize broken molecules arising from V(D)J recombination at the T-cell receptor (TCR) delta locus and have identified linear species excised by Ddelta1-Ddelta2 and V-Ddelta2 rearrangement in thymus DNA. Relatively few (approximately 10) V-Ddelta2-excised linear species were detected in DNA from fetal thymocytes. The sizes of these species corresponded to the estimated distances between Ddelta2 and the V gene segments utilized by gammadelta T cells and indicated that both Ddelta2-proximal and -distal V gene segments are targeted for V-Ddelta2 rearrangement. Similar-sized species were observed in DNA from thymocytes of scid mice in which T-cell development is arrested prior to TCR expression. Since previous studies suggest that the TCR alpha/delta locus encodes more than 100 V gene segments, our results indicate that a few select V gene segments are predominantly targeted for rearrangement to Ddelta2, and this primarily accounts for the restricted Vdelta gene repertoire of gammadelta T cells.

T cell receptor alpha gene rearrangement and transcription in adult thymic gamma delta cells

T cells belong to two separate lineages based on surface expression of alpha beta or gamma delta T cell receptors (TCR). Since during thymus development TCR beta, gamma, and delta genes rearrange before alpha genes, and gamma delta cells appear earlier than alpha beta cells, it has been assumed that gamma delta cells are devoid of TCR alpha rearrangements. We show here that this is not the case, since mature adult, but not fetal, thymic gamma delta cells undergo VJ alpha rearrangements more frequently than immature alpha beta lineage thymic precursors. Sequence analysis shows VJ alpha rearrangements in gamma delta cells to be mostly (70%) nonproductive. Furthermore, VJ alpha rearrangements in gamma delta cells are transcribed normally and, as shown by analysis of TCR beta-/- mice, occur independently of productive VDJ beta rearrangements. These data are interpreted in the context of a model in which precursors of alpha beta and gamma delta cells differ in their ability to express a functional pre-TCR complex.

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.

Defect in rearrangement of the most 5' TCR-J alpha following targeted deletion of T early alpha (TEA): implications for TCR alpha locus accessibility

To address the role of the TEA germline transcription, which initiates upstream of the TCR-J alpha S, in the regulation of TCR-J alpha locus accessibility, we created a mouse in which this region has been removed by homologous recombination. Normal development of T alpha beta cells and the expression of other TCR alpha germline transcripts in TEA-/- mice ruled out an exclusive role for TEA in the overall accessibility of the J alpha cluster. However, the rearrangement of the most 5' J alpha (J alpha 61 to J alpha 53) was severely impaired, indicating that TEA may control the DNA accessibility of a particular J alpha window. Moreover, the relative usage of every J alpha segment was affected. These results are consistent with TEA acting as a "rearrangement-focusing" element, targeting the primary waves of V alpha-J alpha recombination to the most 5' J alpha S in an ongoing TCR-J alpha rearrangement model.

The alpha beta T cell receptor can replace the gamma delta receptor in the development of gamma delta lineage cells

In peripheral lymphoid tissues of TCR transgenic mice that express the nominal antigen (HY peptide plus H-2Db MHC) recognized by the transgenic TCR, there exist unusual CD4-CD8- and CD4-CD8low cells bearing the transgenic TCR. Here we show that, unlike TCR alpha beta T cells that are generated in the absence of nominal antigen, these unusual cells do not express endogenous TCR alpha genes, have maintained the TCR delta locus on both chromosomes, and can coexpress TCR alpha beta and TCR gamma delta chains on the cell surface. The latter is also true for CD4-CD8-, HSA+ TCR alpha beta + thymocytes in male and female TCR transgenic mice. The number of TCR alpha beta and TCR gamma delta coexpressing cells is increased in pre-TCR-deficient mice. The data indicate that the TCR alpha beta can replace the TCR gamma delta in the development of gamma delta lineage cells and that the pre-TCR interferes with the generation of gamma delta-expressing cells.

Transient restoration of gene rearrangement at multiple T cell receptor loci in gamma-irradiated scid mice

The developmental arrest of thymocytes from scid mice, deficient in variable, (diversity), and joining, or V(D)J recombination, can be overcome by sublethal gamma-irradiation. Since previous studies focused on restoration of rearrangement of the T cell receptor (TCR) beta locus, productive rearrangement of which is selected for, we sought to examine to what extent locus specificity and cellular selection contributed to the observed effects. We report here that irradiation of newborn scid mice induces normal V-D-J rearrangements of the TCR delta locus, which like TCR beta, is also actively rearranged in CD(4-)CD(8-) (double negative) thymocytes. In contrast, no complete V-J alpha rearrangements were detected. Instead, we detected substantial levels of hairpin-terminated coding ends at the 5' end of the J alpha locus, demonstrating that TCR alpha rearrangements manifest the effects of the scid mutation. Irradiation, therefore, transiently compensates for the effects of the scid mutation in a locus-nonspecific manner in thymocytes, resulting in a burst of normal TCR beta and delta rearrangements. Irradiation also allows the development of cells that can initiate but fail to complete V(D)J recombination events at the TCR alpha locus, which is normally inaccessible in scid thymocytes.