Both TCR alpha and TCR delta chain diversity are regulated during thymic ontogeny

Specification of Vδ and Vα usage by Tcra/Tcrd locus V gene segment promoters

The Tcra/Tcrd locus undergoes V-Dδ-Jδ rearrangement in CD4(-)CD8(-) thymocytes to form the TCRδ chain of the γδ TCR and V-Jα rearrangement in CD4(+)CD8(+) thymocytes to form the TCRα-chain of the αβ TCR. Most V segments in the locus participate in V-Jα rearrangement, but only a small and partially overlapping subset participates in V-Dδ-Jδ rearrangement. What specifies any particular Tcra/Tcrd locus V gene segment as a Vδ, a Vα, or both is currently unknown. We tested the hypothesis that V segment usage is specified by V segment promoter-dependent chromatin accessibility in developing thymocytes. TRAV15/DV6 family V gene segments contribute to both the Tcrd and the Tcra repertoires, whereas TRAV12 family V gene segments contribute almost exclusively to the Tcra repertoire. To understand whether the TRAV15/DV6 promoter region specifies TRAV15/DV6 as a Vδ, we used gene targeting to replace the promoter region of a TRAV12 family member with one from a TRAV15/DV6 family member. The TRAV15/DV6 promoter region conferred increased germline transcription and histone modifications to TRAV12 in double-negative thymocytes and caused a substantial increase in usage of TRAV12 in Tcrd recombination events. Our results demonstrate that usage of TRAV15/DV6 family V gene segments for Tcrd recombination in double-negative thymocytes is regulated, at least in part, by intrinsic features of TRAV15/DV6 promoters, and argue that Tcra/Tcrd locus Vδ gene segments are defined by their local chromatin accessibility in CD4(-)CD8(-) thymocytes.

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.

ZAP-70 restoration in mice by in vivo thymic electroporation

Viral and non-viral vectors have been developed for gene therapy, but their use is associated with unresolved problems of efficacy and safety. Efficient and safe methods of DNA delivery need to be found for medical application. Here we report a new monopolar system of non-viral electro-gene transfer into the thymus in vivo that consists of the local application of electrical pulses after the introduction of the DNA. We assessed the proof of concept of this approach by correcting ZAP-70 deficient severe combined immunodeficiency (SCID) in mice. The thymic electro-gene transfer of the pCMV-ZAP-70-IRES-EGFP vector in these mice resulted in rapid T cell differentiation in the thymus with mature lymphocytes detected by three weeks in secondary lymphoid organs. Moreover, this system resulted in the generation of long-term functional T lymphocytes. Peripheral reconstituted T cells displayed a diversified T cell receptor (TCR) repertoire, and were responsive to alloantigens in vivo. This process applied to the thymus could represent a simplified and effective alternative for gene therapy of T cell immunodeficiencies.

IMGT/GeneInfo: T cell receptor gamma TRG and delta TRD genes in database give access to all TR potential V(D)J recombinations

BACKGROUND

Adaptative immune repertoire diversity in vertebrate species is generated by recombination of variable (V), diversity (D) and joining (J) genes in the immunoglobulin (IG) loci of B lymphocytes and in the T cell receptor (TR) loci of T lymphocytes. These V-J and V-D-J gene rearrangements at the DNA level involve recombination signal sequences (RSS). Whereas many data exist, they are scattered in non specialized resources with different nomenclatures (eg. flat files) and are difficult to extract.

DESCRIPTION

IMGT/GeneInfo is an online information system that provides, through a user-friendly interface, exhaustive information resulting from the complex mechanisms of T cell receptor V-J and V-D-J recombinations. T cells comprise two populations which express the alphabeta and gammadelta TR, respectively. The first version of the system dealt with the Homo sapiens and Mus musculus TRA and TRB loci whose gene rearrangements allow the synthesis of the alphabeta TR chains. In this paper, we present the second version of IMGT/GeneInfo where we complete the database for the Homo sapiens and Mus musculus TRG and TRD loci along with the introduction of a quality control procedure for existing and new data. We also include new functionalities to the four loci analysis, giving, to date, a very informative tool which allows to work on V(D)J genes of all TR loci in both human and mouse species. IMGT/GeneInfo provides more than 59,000 rearrangement combinations with a full gene description which is freely available at http://imgt.cines.fr/GeneInfo.

CONCLUSION

IMGT/GeneInfo allows all TR information sequences to be in the same spot, and are now available within two computer-mouse clicks. This is useful for biologists and bioinformaticians for the study of T lymphocyte V(D)J gene rearrangements and their applications in immune response analysis.

Regulation of TCR delta and alpha repertoires by local and long-distance control of variable gene segment chromatin structure

Murine Tcrd and Tcra gene segments reside in a single genetic locus and undergo recombination in CD4- CD8- (double negative [DN]) and CD4+ CD8+ (double positive [DP]) thymocytes, respectively. TcraTcrd locus variable gene segments are subject to complex regulation. Only a small subset of approximately 100 variable gene segments contributes substantially to the adult TCRdelta repertoire. Moreover, although most contribute to the TCRalpha repertoire, variable gene segments that are Jalpha proximal are preferentially used during primary Tcra recombination. We investigate the role of local chromatin accessibility in determining the developmental pattern of TcraTcrd locus variable gene segment recombination. We find variable gene segments to be heterogeneous with respect to acetylation of histones H3 and H4. Those that dominate the adult TCRdelta repertoire are hyperacetylated in DN thymocytes, independent of their position in the locus. Moreover, proximal variable gene segments show dramatic increases in histone acetylation and germline transcription in DP thymocytes, a result of super long-distance regulation by the Tcra enhancer. Our results imply that differences in chromatin accessibility contribute to biases in TcraTcrd locus variable gene segment recombination in DN and DP thymocytes and extend the distance over which the Tcra enhancer can regulate chromatin structure to a remarkable 525 kb.

Cryptic O2- -generating NADPH oxidase in dendritic cells

All the components of the O(2)(-)-generating NADPH oxidase typically found in neutrophils, namely a membrane-bound low potential flavocytochrome b and oxidase activation factors of cytosolic origin, are immunodetectable in murine dendritic cells (DCs). However, in contrast to neutrophils, DCs challenged with phorbol myristate acetate (PMA) can barely mount a significant respiratory burst. Nevertheless, DCs generate a substantial amount of O(2)(-) in the presence of PMA following preincubation with pro-inflammatory ligands such as lipopolysaccharide and pansorbin, and to a lesser extent with anti-CD40 or polyinosinic polycytidylic acid. We found that the virtual lack of the oxidase response to PMA alone is specifically controlled in DCs. Through the use of homologous and heterologous cell-free systems of oxidase activation, we showed the following: (1) a NADPH oxidase inhibitory factor is located in DC membranes; it exerts its effect on oxidase activation and not on the activated oxidase. (2) The inhibition is relieved by pretreatment of DC membranes with beta-octylglucoside (beta-OG). (3) The beta-OG-extracted inhibitory factor prevents the activation of neutrophil oxidase. (4) The inhibitory activity is lost after treatment of DC membranes with proteinase K or heating, which points to the protein nature of the inhibitory factor. Overall, these data indicate that the O(2)(-)-generating oxidase in DCs is cryptic, owing to the presence of a membrane-bound inhibitor of protein nature that prevents oxidase activation. The inhibition is relieved under specific conditions, including a prolonged contact of DCs with pro-inflammatory ligands from microbial origin, allowing a substantial production of O(2)(-), which may contribute to the response of DCs to a microbial exposure.

Enforcing order within a complex locus: current perspectives on the control of V(D)J recombination at the murine T-cell receptor alpha/delta locus

V(D)J recombination proceeds according to defined developmental programs at T-cell receptor (TCR) and immunoglobulin loci as a function of cell lineage and stage of differentiation. Although the molecular details are still lacking, such regulation is thought to occur at the level of accessibility of chromosomal recombination signal sequences to the recombinase. The unique and complex organization of the TCRalpha/delta locus poses intriguing regulatory challenges in this regard: embedded TCRalpha and TCRdelta gene segments rearrange at distinct stages of thymocyte development, there is a highly regulated progression of primary followed by secondary rearrangements involving Jalpha segments, and there are important developmental constraints on V gene segment usage. The locus therefore provides a fascinating laboratory in which to explore the basic mechanisms underlying developmental control. We provide here a current view of cis-acting mechanisms that enforce the TCRalpha/delta locus developmental program, and we emphasize the unresolved issues that command the attention of our and other laboratories.

IMGT/GeneInfo: enhancing V(D)J recombination database accessibility

IMGT/GeneInfo is a user-friendly online information system that provides information on data resulting from the complex mechanisms of immunoglobulin (IG) and T cell receptor (TR) V(D)J recombinations. For the first time, it is possible to visualize all the rearrangement parameters on a single page. IMGT/GeneInfo is part of the international ImMunoGeneTics information system (IMGT), a high-quality integrated knowledge resource specializing in IG, TR, major histocompatibility complex (MHC), and related proteins of the immune system of human and other vertebrate species. The IMGT/GeneInfo system was developed by the TIMC and ICH laboratories (with the collaboration of LIGM), and is the first example of an external system being incorporated into IMGT. In this paper, we report the first part of this work. IMGT/GeneInfo_TR deals with the human and mouse TRA/TRD and TRB loci of the TR. Data handling and visualization are complementary to the current data and tools in IMGT, and will subsequently allow the modelling of V(D)J gene use, and thus, to predict non-standard recombination profiles which may eventually be found in conditions such as leukaemias or lymphomas. Access to IMGT/GeneInfo is free and can be found at http://imgt.cines.fr/GeneInfo.

Epigenetic mechanisms that regulate antigen receptor gene expression

Functional immunoglobulin and T-cell receptor genes are generated from germline V, D and J gene segments by a series of site-specific recombination events. This process is regulated by the availability of recombination machinery and by the ordered accessibility of appropriate target gene segments. Recent studies highlight the importance of chromatin remodelling and locus positioning for controlling antigen receptor gene expression and recombination.

Quantitative and qualitative changes in V-J alpha rearrangements during mouse thymocytes differentiation: implication for a limited T cell receptor alpha chain repertoire

Knowledge of the complete nucleotide sequence of the mouse TCRAD locus allows an accurate determination V-J rearrangement status. Using multiplex genomic PCR assays and real time PCR analysis, we report a comprehensive and systematic analysis of the V-J recombination of TCR alpha chain in normal mouse thymocytes during development. These respective qualitative and quantitative approaches give rise to four major points describing the control of gene rearrangements. (a) The V-J recombination pattern is not random during ontogeny and generates a limited TCR alpha repertoire; (b) V-J rearrangement control is intrinsic to the thymus; (c) each V gene rearranges to a set of contiguous J segments with a gaussian-like frequency; (d) there are more rearrangements involving V genes at the 3' side than 5' end of V region. Taken together, this reflects a preferential association of V and J gene segments according to their respective positions in the locus, indicating that accessibility of both V and J regions is coordinately regulated, but in different ways. These results provide a new insight into TCR alpha repertoire size and suggest a scenario for V usage during differentiation.

T lymphocytes potentiate murine dendritic cells to produce IL-12

IL-12 is mainly produced by CD8alpha(+) dendritic cells (DCs) and induces Th1 polarization of the immune response. We investigated the influence of lymphocytes on splenic DC (SDC) and thymic DC (TDC) development and on their IL-12 production capacity. First, CD3epsilon(-/-) mice, lacking T cells, and RAG-2(-/-) mice, lacking T and B cells, possess numbers of SDCs, TDCs, and CD8alpha(+) SDCs similar to wild-type (WT) mice. Second, SDCs and TDCs from CD3epsilon(-/-) mice do not secrete IL-12 in vitro after different stimulations, whereas DCs from pTalpha(-/-) mice, possessing reduced T cell number, and RAG-2(-/-) mice, produce an IL-12 level similar to that of WT DCs. We show that T lymphocytes restore the capacity of DCs to produce IL-12 after stimulation in vivo by reconstitution of CD3epsilon(-/-) mice with WT T cells and in vitro by coculture of CD3epsilon(-/-) DCs with WT T cells. The regulation of IL-12 production occurred at the transcriptional level, with an increase of IL-12p35 transcripts and a decrease of IL-12p40 transcripts. Although IL-4 restores IL-12 production by CD3epsilon(-/-) SDCs, anti-IL-4 Abs inhibited only partially the IL-12 production in coculture of CD3epsilon(-/-) DCs and WT T cells. Taken together, these data show that T lymphocytes potentiate IL-12 production by DCs and that IL-4 is not solely involved in this regulation. In conclusion, B and T cells exert balanced actions on DCs by respectively inhibiting or promoting IL-12 production.

Access roads for RAG-ged terrains: control of T cell receptor gene rearrangement at multiple levels

Antigen-specific immune response requires the generation of a diverse antigen (Ag)-receptor repertoire. The primary repertoire is generated through somatic gene rearrangement and molded by subsequent cellular selection. Constraints during gene recombination influence the ultimate shape of the repertoire. One major control mechanism of gene rearrangement, investigated for many years, is exerted through regulated chromosomal accessibility of the recombinase to the antigen receptor loci. More recent studies began to explore the role of interactions between the recombinase and its cognate recognition DNA sequences. The emerging results suggest that formation of the primary repertoire is controlled by two, partially independent factors: chromosomal accessibility and direct recombinase-DNA interactions.