Identification and functional characterization of the human T-cell receptor beta gene transcriptional enhancer: common nuclear proteins interact with the transcriptional regulatory elements of the T-cell receptor alpha and beta genes

Regulation of T-cell Receptor Gene Expression by Three-Dimensional Locus Conformation and Enhancer Function

The adaptive immune response in vertebrates depends on the expression of antigen-specific receptors in lymphocytes. T-cell receptor (TCR) gene expression is exquisitely regulated during thymocyte development to drive the generation of αβ and γδ T lymphocytes. The TCRα, TCRβ, TCRγ, and TCRδ genes exist in two different configurations, unrearranged and rearranged. A correctly rearranged configuration is required for expression of a functional TCR chain. TCRs can take the form of one of three possible heterodimers, pre-TCR, TCRαβ, or TCRγδ which drive thymocyte maturation into αβ or γδ T lymphocytes. To pass from an unrearranged to a rearranged configuration, global and local three dimensional (3D) chromatin changes must occur during thymocyte development to regulate gene segment accessibility for V(D)J recombination. During this process, enhancers play a critical role by modifying the chromatin conformation and triggering noncoding germline transcription that promotes the recruitment of the recombination machinery. The different signaling that thymocytes receive during their development controls enhancer activity. Here, we summarize the dynamics of long-distance interactions established through chromatin regulatory elements that drive transcription and V(D)J recombination and how different signaling pathways are orchestrated to regulate the activity of enhancers to precisely control TCR gene expression during T-cell maturation.

A new transcript in the TCRB locus unveils the human ortholog of the mouse pre-Dß1 promoter

Introduction

While most transcripts arising from the human T Cell Receptor locus reflect fully rearranged genes, several germline transcripts have been identified. We describe a new germline transcript arising from the human TCRB locus.

Methods

cDNA sequencing, promoter, and gene expression analyses were used to characterize the new transcript.

Results

The new germline transcript encoded by the human TCRB locus consists of a new exon of 103 bp, which we named TRBX1 (X1), spliced with the first exon of gene segments Cß1 or Cß2. X1 is located upstream of gene segment Dß1 and is therefore deleted from a V‐DJ rearranged TCRB locus. The X1‐Cß transcripts do not appear to code for a protein. We define their transcription start and minimal promoter. These transcripts are found in populations of mature T lymphocytes from blood or tissues and in T cell clones with a monoallelic TCRB rearrangement. In immature thymocytes, they are already detectable in CD1a⁻CD34⁺CD4⁻CD8⁻ cells, therefore before completion of the TCRB rearrangements.

Conclusions

The X1 promoter appears to be the ortholog of the mouse pre‐Dß1 promoter (PDß1). Like PDß1, its activation is regulated by Eß in T cells and might facilitate the TCRB rearrangement process by contributing to the accessibility of the Dß1 locus.

New insights on the transcriptional regulation of CD69 gene through a potent enhancer located in the conserved non-coding sequence 2

The CD69 type II C-type lectin is one of the earliest indicators of leukocyte activation acting in lymphocyte migration and cytokine secretion. CD69 expression in hematopoietic lineage undergoes rapid changes depending on the cell-lineage, the activation state or the localization of the cell where it is expressed, suggesting a complex and tightly controlled regulation. Here we provide new insights on the transcriptional regulation of CD69 gene in mammal species. Through in silico studies, we analyzed several regulatory features of the 4 upstream conserved non-coding sequences (CNS 1-4) previously described, confirming a major function of CNS2 in the transcriptional regulation of CD69. In addition, multiple transcription binding sites are identified in the CNS2 region by DNA cross-species conservation analysis. By functional approaches we defined a core region of 226bp located within CNS2 as the main enhancer element of CD69 transcription in the hematopoietic cells analyzed. By chromatin immunoprecipitation, binding of RUNX1 to the core-CNS2 was shown in a T cell line. In addition, we found an activating but not essential role of RUNX1 in CD69 gene transcription by site-directed mutagenesis and RNA silencing, probably through the interaction with this potent enhancer specifically in the hematopoietic lineage. In summary, in this study we contribute with new evidences to the landscape of the transcriptional regulation of the CD69 gene.

Thyrotropin acts as a T-cell developmental factor in mice and humans

Using gene expression profiling, we detected differential thyrotropin receptor (TSH-R) expression during human T-cell development in the thymus. This expression pattern indicated a potential role for the TSH-R within the thymus, independent of its function in the thyroid gland. Here, we demonstrate that TSH-R expression is thymus-specific within the immune system. TSH was able to bind and activate the TSH-R present on thymocytes, thereby activating calcium signaling and cyclic adenosine monophosphate signaling pathways. Mice lacking functional TSH-R expression (hyt/hyt mice) were shown to have lower frequencies of DP and SP thymocytes compared to their heterozygous littermates. Moreover, addition of TSH to co-cultures of human thymocytes enhanced T-cell development. Thus, TSH acts as a previously unrecognized growth factor for developing T cells, with potential clinical use to enhance thymic output and thereby the functional T-cell repertoire in the periphery. The direct effects of TSH on thymocytes may also explain the thus far enigmatic thymic hyperplasia in Graves' disease.

New insight into the genomic structure of dog T cell receptor beta (TRB) locus inferred from expression analysis

Here is an updated report on the genomic organization of T cell receptor beta (TRB) locus in the domestic dog (Canis lupus familiaris) as inferred from comparative genomics and expression analysis. The most interesting results we found were a second TRBD-J-C cluster, which is absent from the reference genome sequence, and the annotation of two additional TRBV genes. In dogs, TRB locus consists of a library of 37 TRBV genes positioned at the 5' end of two in tandem aligned D-J-C gene clusters, each composed of a single TRBD, 6 TRBJ and one TRBC genes, followed by a single TRBV gene with an inverted transcriptional orientation. The TRB genes are distributed in less than 300kb, making the canine locus, one of the smaller mammalian TRB locus studied so far. The small size may be ascribed to reduced gene duplication occurrences and a lower density of total interspersed repeats compared to humans and mice. Despite the low TRBV gene content, a large and diversified beta chain repertoire is displayed in the dog peripheral blood. A full usage of TRBV and TRBJ genes, including pseudogenes, and a high level of allelic polymorphism contribute to generate diversity. Finally, this study suggests that the overall TRB locus organization is evolutionarily conserved supporting the dog as a highly suited model system for immune development and diseases.

Stage-specific functions of E-proteins at the β-selection and T-cell receptor checkpoints during thymocyte development

The E-protein transcription factors E2A and HEB function in a lineage- and stage-specific manner to orchestrate many critical events throughout lymphocyte development. The function of E-proteins in both B- and T-lymphocyte development has been extensively studied through the use of single-gene knockout animals. Unlike B cells, which rely primarily on E2A alone, T cells are regulated by the combinatorial expression of both E2A and HEB. Therefore, many of the roles of E-proteins during T-cell development may be masked in single-gene knockout studies due to the compensatory function of E2A and HEB. More recently, our laboratory has established double-conditional knockout models to eliminate both E2A and HEB in a stage-specific manner throughout T-cell development. These models, in combination with other complimentary genetic approaches, have identified new E-protein functions at each of the two major T-cell developmental checkpoints. Here, we will discuss how E-proteins function to regulate the expression of T-cell receptor components and cell cycle at the β-selection checkpoint, and how they control positive selection, survival, and lineage-specific gene expression at the subsequent T-cell receptor checkpoint.

Promoter characterization and role of CRE in the basal transcription of the rat SNAT2 gene

Small neutral amino acid transporter 2 (SNAT2) is the most abundant and ubiquitous transporter for zwitterionic short-chain amino acids. The activity of this amino acid transporter is stimulated in vivo or in vitro by glucagon or cAMP analogs. However, it is not known whether the increase in activity at the protein level is due to an increase in SNAT2 gene transcription. Thus, the aim of the present work was to study whether cAMP was able to stimulate SNAT2 gene expression and to localize and characterize the presence of cAMP response elements (CRE) in the promoter that controls the expression of the rat SNAT2 gene. We found that consumption of a high-protein diet that increased serum glucagon concentration or the administration of glucagon or incubation of hepatocytes with forskolin increased the SNAT2 mRNA level. We then isolated the 5' regulatory region of the SNAT2 gene and determined that the transcriptional start site was located 970 bp upstream of the translation start codon. We identified two potential CRE sites located at -354 and -48 bp. Our results, using deletion analysis of the 5' regulatory region of the SNAT2 gene, revealed that the CRE site located at -48 bp was fully responsible for SNAT2 regulation by cAMP. This evidence was strongly supported by mutation of the CRE site and EMSA and ChIP analysis. Alignment of rat, mouse, and human sequences revealed that this CRE site is highly conserved among species, indicating its essential role in the regulation of SNAT2 gene expression.

Regulation of V(D)J recombination by E-protein transcription factors

Extensive study of the E-proteins E2A and HEB duringlymphocyte development has revealed various functions for these bHLH transcription factors in regulating V(D)J recombination in both B- and T-cells. The study of E-proteins in mammals began with the identification of E2A by its ability to bind immunoglobulin heavy and light chain enhancers. Subsequent analysis has identified numerous roles for E2A and HEB at the immunoglobulin and T-cell receptor loci. E-protein targets also include the rag genes and other factors critical for recombination and for regulation of the developmental windows when cells undergo recombination. E-proteins appear to be master regulators that coordinate antigen receptor gene rearrangement and expression. This chapter focuses on how E-proteins regulate V(D)J recombination by activating transcription, initiating rearrangement and driving differentiation during B- and T-cell development.

Molecular mechanisms that control mouse and human TCR-alphabeta and TCR-gammadelta T cell development

Following specification of hematopoietic precursor cells into the T cell lineage, several developmental options remain available to the immature thymocytes. The paradigm is that the outcome of the T cell receptor rearrangements and the corresponding T cell receptor signaling events will be predominant to determine the first of these choices: the alphabeta versus gammadelta T cell pathways. Here, we review the thymus-derived environmental signals, the transcriptional mediators, and other molecular mechanisms that are also involved in this decision in both the mouse and human. We discuss the differences in cellular events between the alphabeta and gammadelta developmental pathways and try to correlate these with a corresponding complexity of the molecular mechanisms that support them.

Differential activation of dual promoters alters Dbeta2 germline transcription during thymocyte development

Ag receptor genes are assembled through somatic rearrangements of V, D, and J gene segments. This process is directed in part by transcriptional enhancers and promoters positioned within each gene locus. Whereas enhancers coordinate reorganization of large chromatin stretches, promoters are predicted to facilitate the accessibility of proximal downstream gene segments. In TCR beta locus, rearrangement initiates at two D-J cassettes, each of which exhibits transcriptional activity coincident with DJ rearrangement in CD4/CD8 double-negative pro-T cells. Consistent with a model of promoter-facilitated recombination, assembly of the DJbeta1 cassette is dependent on a Dbeta1 promoter (PDbeta1) positioned immediately 5' of the D. Assembly of DJbeta2 proceeds independent from that of DJbeta1, albeit with less efficiency. To gain insight into the mechanisms that selectively alter D usage, we have defined transcriptional regulation at Dbeta2. We find that both DJbeta cassettes generate germline messages in murine CD44+CD25- double-negative 1 cells. However, transcription of unrearranged DJbeta2 initiates at multiple sites 400-550 bp downstream of the Dbeta2. Unexpectedly, loci from which germline promoter activity has been deleted by DJ rearrangement redirect transcription to sites immediately 5' of the new DJbeta2 joint. Our analyses suggest that 3'-PDbeta2 activity is largely controlled by NF-kappaB RelA, whereas 5'-PDbeta2 activity directs germline transcription of DJbeta2 joints from initiator elements 76 bp upstream of the Dbeta2 5' recombination signal sequence. The unique organization and timing of Dbeta2 promoter activity are consistent with a model in which promoter placement selectively regulates the rearrangement potential of Dbeta2 during TCR beta locus assembly.

Nomenclature of the human T cell receptor genes

The human T cell receptors (TcR) alpha-beta and gamma-delta are the products of four sets of genes on two chromosomes: T cell receptors alpha (TRA) and delta (TRD) on chromosome 14 at 14q11.2, T cell receptor beta (TRB) on chromosome 7 at 7q35, and T cell receptor gamma (TRG) on chromosome 7 at 7p15-p14. This appendix presents tabulated lists of the human TcR alpha, beta, gamma, and delta genes named in accordance with the International ImMunoGeneTics database and approved by the Human Genome Organization Nomenclature Committee in 1999. Two additional tables list corresponding nomenclatures for these genes.

Critical function of Ikaros in controlling Aiolos gene expression

To characterize the regulation of lymphoid Aiolos transcription factor, we have cloned its promoter. Full promoter and nested deletions were expressed in lymphoid and non-lymphoid cell lines. The minimal promoter activity could be considered as a 172bp upstream from the ATG for Jurkat and HEK293 cells and as a 370bp fragment for U937 cells. Moreover, we have mapped the transcription initiation site. Retardation gels showed binding activity for Ikaros, NFkappaB and AP4 transcription factors and mutations in their binding sites abolish Aiolos promoter activity. Chromatin immunoprecipitation assay revealed that Ikaros, NFkappaB and AP4 are bound to Aiolos promoter. The important function of Ikaros and NFkappaB is underlined by their over expression, which results in the trans-activation of the promoter and drives Aiolos expression in cell lines and in freshly isolated B and T cells, while over expression of a dominant negative Ikaros isoform is able to block Aiolos expression.

Turning T-cell receptor ? recombination on and off: more questions than answers

Successful V(D)J recombination at the T-cell receptor beta (Tcrb) locus is critical for early thymocyte development. The locus is subject to a host of regulatory mechanisms that impart a strict developmental order to Tcrb recombination events and that insure that Tcrb recombination occurs in an allelically excluded fashion. Progress has been made in the understanding of the cis-acting control of Tcrb locus chromatin structure and the extent to which such accessibility control can account for the developmental regulation of Tcrb recombination. However, recent studies in our laboratory and elsewhere have made it abundantly clear that accessibility control is only part of the story, and multiple additional mechanisms impact both the developmental activation and inactivation of locus recombination events. Here we evaluate our current understanding of developmental regulation at the Tcrb locus. We highlight the many unresolved issues and we discuss how recent concepts emerging from studies of other antigen receptor loci may (or may not) help to resolve these issues.

Cyclic adenosine 5'-monophosphate response element binding protein plays a central role in mediating proliferation and differentiation downstream of the pre-TCR complex in developing thymocytes

The roles played by specific transcription factors during the regulation of early T cell development remain largely undefined. Several key genes induced during the primary checkpoint of T cell development, beta-selection, contain cAMP response element sites within their enhancer-promoter region that are regulated by CREB activation. In this study, we show that CREB is constitutively phosphorylated in the thymus, but not the spleen. We also show that CREB is activated downstream of the pre-TCR complex, and that the induction of CREB activity is regulated by protein kinase C alpha- and ERK-MAPK-mediated signals. We addressed the importance of this activation by expressing a naturally occurring inhibitor of CREB, inducible cAMP early repressor in wild-type fetal liver-derived lymphoid progenitor cells, and assessed their developmental potential. Fetal thymic organ cultures reconstituted with cells constitutively expressing inducible cAMP early repressor displayed a delay in generating CD4(+)CD8(+) thymocytes and a decrease in cellularity compared with control fetal thymic organ cultures. Taken together, our studies establish that CREB plays a central role in relaying proliferation and differentiation signals from the pre-TCR complex into the nucleus in developing thymocytes.

Role of CREB transcription factor in c-fos activation in natural killer cells

In natural killer (NK) cells, interleukin-2 (IL-2) differentially regulates the expression of several transcription factors, including JunB and c-fos. The cAMP response element binding protein, CREB, is a key transcriptional regulator of a large number of genes containing the octanucleotide CRE consensus sequence in their upstream regulatory regions. We studied here the functional role of CREB in the IL-2-mediated transcriptional regulation of c-fos in human NK cells. Our results show that IL-2 activates CREB in human NK cells and that CREB activation hasa prominent regulatory role on the IL-2-induced expression of functional c-fos and AP-1 in NK cells. We identify two domains of the c-fos promoter, containing three CRE sites, which are critical for the transcriptional activity induced by IL-2. The first domain is located within the first 220 nucleotides of the c-fos promoter, while the second encompasses the nucleotides - 440 and - 220. Our results show that CREB has a relevant role in the cytokine-mediated activation of NK cells, and are particularly remarkable in the light of the several genes that are positively regulated by c-fos and AP-1, such as IFN-gamma, IL-2 and GM-CSF genes.

Limited effect of chromatin remodeling on D(beta)-to-J(beta) recombination in CD4+CD8+ thymocyte: implications for a new aspect in the regulation of TCR beta gene recombination

We have generated mutant mice in which TCR beta chain enhancer (E(beta)) was replaced with the TCR alpha chain enhancer (E(alpha)). Using this mouse model, we analyzed (i) recombination status of the TCR beta chain genes after functional V(D)J rearrangements occurred in the first allele during double-negative (DN)-to-double-positive (DP) transition and (ii) involvement of E(beta) for the expression of rearranged TCR beta chain genes. Our data show that E(alpha) substituted for E(beta) function to express a similar extent of TCR beta chains exactly at the same time as did E(beta) (CD25+CD44- DN stage), although the proportion of TCR beta+ cells at this stage was low in mutant mice. At the DP stage, germline transcription and histone acetylation of D(beta)-J(beta) loci were detectable at a high degree in both mutant and wild-type mice. However, DP cells in mutant mice retained the germline D(beta)-J(beta) configuration at a higher frequency than that of wild-type mice, whereas both DP cells expressed TCR beta chains to a similar extent. These data suggest that chromatin opening has a limited impact on D(beta)-to-J(beta) recombination at the DP stage and that E(alpha) is functionally equivalent to E(beta) in promoting expression of functionally rearranged TCR beta chain genes through DN-to-DP transition.

Clusterin gene in rat sertoli cells is regulated by a core-enhancer element

Clusterin is a ubiquitous glycoprotein that is promiscuously expressed at a low basal level but can be highly induced by a variety of stress conditions. In contrast, in some secretory cells associated with tissue-fluid interfaces such as the Sertoli cells in the testis, clusterin demonstrates high constitutive expression. In this study, we address the mechanisms that regulate the constitutive expression of the clusterin gene by using primary cultures of immature rat Sertoli cells. We have identified a region of the rat clusterin gene promoter that activated transcription only in Sertoli cells and that mapped between positions -426 and -311. Sequence analysis of this region revealed a high concentration of potential regulatory elements. Using gel-shift assays combined with hydroxyl radical footprinting, we identified the elements recognized by the Sertoli cell nuclear factors. Comparison of the interactions with this region of the nuclear factors from different cell types demonstrated that recognition of the core-enhancer element is specific for the Sertoli cells, and in vitro, the core region was recognized by the transcription factor CBF. Transient transfections showed that a core enhancer is responsible for more than a half of the total promoter activity and is an essential element for the cell-specific activity of the Sertoli-specific region. In addition to the core enhancer, tandem Sp1 sites are also required for maximal activity of this region.

Mechanisms of transcriptional activation of cAMP-responsive element-binding protein CREB

The CREB-CREM transcription factors are the main gene regulatory effectors of the cAMP signaling pathway. The investigations of this family of transcription factors had a profound impact on the understanding of signaling-induced gene transcription. Here we discuss some key aspects of the underlying biology, review transcriptional activation by CREB proteins through transcription cofactors and present novel insights into the context- and position-specific function of CREB on complex genes.

Functional analysis of the murine TCR beta-chain gene enhancer

The TCR beta-chain gene enhancer activates transcription and V(D)J recombination in immature thymocytes. In this paper we present a systematic analysis of the elements that contribute to the activity of the murine TCR beta enhancer in mature and immature T cell lines. We identified a region containing the beta E4, beta E5, and beta E6 motifs as the essential core of the TCR beta enhancer in pro-T cells. In mature cells, the core enhancer had low activity and required, in addition, either 5' or 3' flanking sequences whose functions may be partially overlapping. Mutation of any of the six protein binding sites located within the beta E4-beta E6 elements essentially abolished enhancer activity, indicating that this core enhancer contained no redundant elements. The beta E4 and beta E6 elements contain binding sites for ETS-domain proteins and the core binding factor. The beta E5 element bound two proteins that could be resolved chromatographically and that were both essential for enhancer activity.

Implications for interrelationships between nuclear architecture and control of gene expression under microgravity conditions

Components of nuclear architecture are functionally interrelated with control of gene expression. There is growing appreciation that multiple levels of nuclear organization integrate the regulatory cues that support activation and suppression of genes as well as the processing of gene transcripts. The linear representation of genes and promoter elements provide the potential for responsiveness to physiological regulatory signals. Parameters of chromatin structure and nucleosome organization support synergism between activities at independent regulatory sequences and render promoter elements accessible or refractory to transcription factors. Association of genes, transcription factors, and the machinery for transcript processing with the nuclear matrix facilitates fidelity of gene expression within the three-dimensional context of nuclear architecture. Mechanisms must be defined that couple nuclear morphology with enzymatic parameters of gene expression. The recent characterization of factors that mediate chromatin remodeling and identification of intranuclear targeting signals that direct transcription factors to subnuclear domains where gene expression occurs link genetic and structural components of transcriptional control. Nuclear reorganization and aberrant intranuclear trafficking of transcription factors for developmental and tissue-specific control occurs in tumor cells and in neurological disorders. Compromises in nuclear structure-function interrelationships can occur as a consequence of microgravity-mediated perturbations in cellular architecture.

Mutant p53: epigenetic mutator of the T-cell receptor via induction of methylation

The mechanism and effects of epigenetic alterations in human carcinogenesis are not well understood, except that cancers often have alterations in the methylation status of their genomes. Additionally, human cancers, including aggressive T-cell leukemias and lymphomas, have a high frequency of p53 mutations, particularly missense mutations, which raises the possibility of gain-of-new-function proteins, but the new proteins' oncogenic functions are mechanistically ill-defined. To investigate the mechanisms behind the high prevalence of p53 tumor suppressor gene mutations in aggressive or relapsed T-cell leukemias, we transfected Jurkat cells null for p53 protein with a temperature-sensitive p53 mutant. We showed that this mutant p53 abrogated expression of the T-cell antigen receptor (TCR) by affecting the methylation of an at least 20-kb region of DNA, 5'to the TCR beta-chain gene enhancer region, which includes TCRbetaC1 and betaC2. Expression of the TCR is restored when the temperature is reduced to 32 degrees C, at which temperature the mutant p53 regains wild-type function. The TCR, a common site of dysfunction in T-cell malignancies, is the principal signal transduction moiety controlling both T-cell activation and activation-induced apoptosis. These results suggest a new role for mutant p53-as an epigenetic mutator, bridging p53, methylation, and transcriptional silencing-and suggest novel mechanisms in immunosuppression and cancer progression.

Nuclear factors that bind to the U3 region of two murine myeloid leukemia-inducing retroviruses, Cas-Br-E and Graffi

Cas-Br-E and Graffi are two myeloid leukemia-inducing murine viruses. Cas-Br-E induces, in NIH-Swiss mice, mostly non-T, non-B leukemia composed of very immature cells with no specific characteristics (Bergeron et al. (1993). Leukemia 7, 954-962). The Graffi murine leukemia virus causes exclusively myeloid leukemia, but the tumor cells are clearly of granulocytic nature (Ru et al. (1993). J. Virol. 67, 4722). We were interested to understand the role of the long terminal repeat (LTR) U3 region in the myeloid specificity of these two retroviruses. We used DNase I footprinting and gel mobility shift assays to identify a number of protein binding sites within Cas-Br-E and Graffi U3 regions. The pattern of protected regions is highly similar for the two viruses. Some factors identified in other murine leukemia viruses, like the core binding factor, also bind to Cas-Br-E and Graffi LTR; however, other binding sites seem specific for these two viruses. Only one difference between them was noted, at the 5' end of the U3 region. Transcriptional activity of both LTRs was also analyzed in various cell lines and compared with other murine leukemia viruses. The results show a slight myeloid specificity for the two LTRs, and indicate that the Graffi enhancer is quite strong in a broad range of cell types.

Regulation of a hair follicle keratin intermediate filament gene promoter

During hair growth, cortical cells emerging from the proliferative follicle bulb rapidly undergo a differentiation program and synthesise large amounts of hair keratin proteins. To identify some of the controls that specify expression of hair genes we have defined the minimal promoter of the wool keratin intermediate filament gene K2.10. The region of this gene spanning nucleotides −350 to +53 was sufficient to direct expression of the lacZ gene to the follicle cortex of transgenic mice but deletion of nucleotides −350 to −150 led to a complete loss of promoter activity. When a four base substitution mutation was introduced into the minimal functional promoter at the binding site for lymphoid enhancer factor 1 (LEF-1), promoter activity in transgenic mice was decreased but specificity was not affected. To investigate the interaction of trans-acting factors within the minimal K2.10 promoter we performed DNase I footprinting analyses and electrophoretic mobility shift assays. In addition to LEF-1, Sp1, AP2-like and NF1-like proteins bound to the promoter. The Sp1 and AP2-like proteins bound sequences flanking the LEF-1 binding site whereas the NF1-like proteins bound closer to the transcription start site. We conclude that the LEF-1 binding site is an enhancer element of the K2.10 promoter in the hair follicle cortex and that factors other than LEF-1 regulate promoter tissue- and differentiation-specificity.

Characterization of human TCR Vbeta gene promoter. Role of the dodecamer motif in promoter activity

During T-lymphocyte development, the T-cell antigen receptor (TCR) gene expression is controlled by its promoter and enhancer elements and regulated in tissue- and development stage-specific manner. To uncover the promoter function and to define positive and negative regulatory elements in TCR gene promoters, the promoter activities from 13 human TCR Vbeta genes were determined by the transient transfection system and luciferase reporter assay. Although most of the TCR Vbeta gene promoters that we tested are inactive by themselves, some promoters were found to be constitutively strong. Among them, Vbeta6.7 is the strongest. 5'-Deletion and fragmentation experiments have narrowed the full promoter activity of Vbeta6.7 to a fragment of 147 base pairs immediately 5' to the transcription initiation site. A decanucleotide motif with the consensus sequence AGTGAYRTCA has been found to be conserved in most TCR Vbeta gene promoters. There are three such decamer motifs in the promoter region of Vbeta6.7, and the contribution of each such motif to the promoter activity has been examined. Further site-directed mutagenesis analyses showed that: 1) when two Ts in the decamer were mutated, the promoter activity was totally abolished; 2) when two additional nucleotides 3' to the end of decamer were mutated, the promoter activity was decreased to two-thirds of the full level; and 3) when the element with the sequence AGTGATGTCACT was inserted into other promoters, the original weak promoters become very strong. Taken together, our data suggest that the positive regulatory element in Vbeta6.7 should be considered a dodecamer rather than a decamer and that it confers strong basal transcriptional activity on TCR Vbeta genes.

Elf-1 Regulates Basal Expression from the T Cell Antigen Receptor ζ-Chain Gene Promoter

In mature T cells, limited synthesis of the TCR-ζ subunit is primarily responsible for regulating surface expression of TCRs. Transcription of ζ is directed by a complex promoter that includes two potential binding sites for the Ets family of transcription factors at −52 (zEBS1) and −135 (zEBS2). Mutation of these two sites results in a marked reduction of transcription from this promoter. Using electrophoretic mobility shift analysis, Elf-1 was demonstrated to be the Ets family member that binds to these sites. One site, zEBS1, matches the optimal Elf-1 consensus sequence in eight of nine bases, making it the best match of any known mammalian Elf-1 binding site. A role for Elf-1 in TCR-ζ trans-activation was confirmed by ectopic expression of Elf-1 in COS-7 cells. This resulted in an increase in TCR-ζ promoter activity that mapped to zEBS1 and zEBS2. Additional support for the involvement of Elf-1 in TCR-ζ trans-activation derives from the finding that a GAL4-Elf-1 fusion protein trans-activated TCR-ζ promoter constructs that had been modified to contain GAL4 DNA binding sites. These results demonstrate that Elf-1 plays an essential role in the trans-activation of a constitutively expressed T cell-specific gene, and that trans-activation occurs in the context of the native promoter in both lymphoid and nonlymphoid cells. Taken together with the existing literature, these data also suggest that the requirement for inducible factors in Elf-1-mediated trans-activation may decrease as the affinity and number of Elf-1 sites increase.

Cloning of a T-cell receptor beta-chain enhancer binding protein

Several eukaryotic DNA binding proteins have been isolated by screening lambda expression libraries with DNA probes containing their binding site. This strategy has been employed to isolate clones of the factor that interacts with the T-cell receptor beta-chain enhancer motif. A cDNA clone encoding a protein similar to YB-1 has been isolated with this. It seems probable that this protein YB, might interact with other proteins and regulate the transcription of the T-cell receptor beta-chain gene.

A molecular basis for species differences in Thy-1 expression patterns

Thy-1 is a membrane glycoprotein that displays species-specific differences in its pattern of expression. Although it is expressed on thymocytes and splenocytes in mice, it is only expressed on thymocytes in rats. Based on previous studies suggesting that the third intron of the mouse Thy-1 gene is required for its expression in thymocytes, in vivo footprinting analysis was performed on the third introns of both the mouse and rat Thy-1 genes, and led to the identification of homologous 36 bp "footprinted" regions. The mouse 36 bp region was found to be capable of specifically binding an Ets-1-like nuclear factor present in both mouse thymocytes and splenocytes. In contrast, the homologous 36 bp region of the rat which differs from the mouse 36 bp region by three nucleotides resulting in the loss of the Ets-1 binding site, is unable to bind a similar Ets-1-like factor present in rat thymocytes. Instead, this region of the rat third intron binds another nuclear factor which is present in rat thymocytes but not splenocytes. These observations suggest that the differential expression of the mouse and rat Thy-1 genes in thymocytes and splenocytes is the result of differential expression of nuclear factors that bind to this 36 bp region.

Embryonic lethality and impairment of haematopoiesis in mice heterozygous for an AML1-ETO fusion gene

Acute myeloid leukaemia (AML) is a major haematopoietic malignancy characterized by the proliferation of a malignant clone of myeloid progenitor cells. A reciprocal translocation, t(8;21)(q22;q22), observed in the leukaemic cells of approximately 40% of patients with the M2 subtype of AML disrupts both the AML1 (CBFA2) gene on chromosome 21 and the ETO (MTG8) gene on chromosome 8 (refs 3-5). A chimaeric protein is synthesized from one of the derivative chromosomes that contains the N terminus of the AML1 transcription factor, including its DNA-binding domain, fused to most of ETO, a protein of unknown function. We generated mice that mimic human t(8;21) with a "knock-in' strategy. Mice heterozygous for an AML1-ETO allele (AML1-ETO/+) die in midgestation from haemorrhaging in the central nervous system and exhibit a severe block in fetal liver haematopoiesis. This phenotype is very similar to that resulting from homozygous disruption of the AML1 (Cbfa2) or Cbfb genes, indicating that AML1-ETO blocks normal AML1 function. However, yolk sac cells from AML1-ETO/+ mice differentiated into macrophages in haematopoietic colony forming unit (CFU) assays, unlike Cbfa2-/- or Cbfb-/-cells, which form no colonies in vitro. This indicates that AML1-ETO may have other functions besides blocking wild-type AML1, a property that may be important in leukaemogenesis.

An enhancer LEF-1/TCF-1 site is essential for insertion site-independent transgene expression in thymus

Transcriptional activation of eukaryotic genes involves assembly of specific multiprotein complexes on the promoters and enhancers of the genes. Recently, it has been proposed that the role of some of the proteins in the complex may be architectural, involving DNA bending, orchestration of protein-protein interaction and modulation of nucleosome structure. This role has been proposed for the HMG proteins LEF-1 and TCF-1. We examined the role of a LEF-1/TCF-1 binding site in the human adenosine deaminase (ADA) thymic enhancer. Mutational analysis demonstrated that a functional LEF-1/TCF-1 binding site is not required for enhancer-mediated transcriptional activation in transient transfection studies, but is essential for enhancer function in the in vivo chromatin context of transgenic mice. Mutation of the LEF-1/TCF-1 site destroyed the ability of the ADA enhancer/locus control region to specify high level, insertion site-independent transgene expression in thymus. DNase I and DpnII accessibility experiments indicated dramatic changes in the chromatin organization of the ADA enhancer in transgenic mice with a mutated LEF-1/TCF-1 site. This supports the hypothesis that factors binding the LEF-1/TCF-1 site play an architectural role during the in vivo activation of the ADA enhancer, possibly involving chromatin modification.

Structural and functional characterization of the human CD36 gene promoter: identification of a proximal PEBP2/CBF site

CD36 is a cell surface glycoprotein composed of a single polypeptide chain, which interacts with thrombospondin, collagens type I and IV, oxidized low density lipoprotein, fatty acids, anionic phospholipids, and erythrocytes parasitized with Plasmodium falciparum. Its expression is restricted to a few cell types, including monocyte/macrophages. In these cells, CD36 is involved in phagocytosis of apoptotic cells, and foam cell formation by uptake of oxidized low density lipoprotein. To study the molecular mechanisms that control the transcription of the CD36 gene in monocytic cells we have isolated and analyzed the CD36 promoter. Transient expression experiments of 5'-deletion fragments of the CD36 promoter coupled to luciferase demonstrated that as few as 158 base pairs upstream from the transcription initiation site were sufficient to direct the monocyte-specific transcription of the reporter gene. Within the above region, the fragment spanning nucleotides -158 to -90 was required for optimal transcription in monocytic cells. Biochemical analysis of the region -158/-90 revealed a binding site for transcription factors of the polyomavirus enhancer-binding protein 2/core-binding factor (PEBP2/CBF) family at position -103. Disruption of the PEBP2/CBF site markedly diminished the role of the PEBP2/CBF factors in the constitutive transcription of the CD36 gene. The involvement of members of the PEBP2/CBF family in chromosome translocations associated with acute myeloid leukemia, and in the transcriptional regulation of the myeloid-specific genes encoding for myeloperoxidase, elastase, and the colony-stimulating factor receptor, highlights the relevance of the regulation of the CD36 gene promoter in monocytic cells by members of the PEBP2/CBF family.

Direct and indirect mechanisms of repression participate in suppression of T-cell-specific gene expression in T x L-cell hybrids

Expression of tissue-specific genes can be altered upon fusion of mammalian cells of different types. To resolve the genetic basis of this phenomenon and to identify components of the regulatory circuits that are involved, we have established a series of somatic cell hybrids between mouse T cells and L cells. These hybrids have an unusual and interesting phenotype. Unlike many hybrid cells studied, in which the expression of an entire set of tissue-specific genes was coordinately extinguished, in our T x L-cell hybrids only two out of seven T-cell-restricted genes were completely extinguished, whereas the other genes were repressed to various degrees. These hybrids extinguish the production of TCR beta and Thy-1 mRNA, repress the expression of TCR alpha, GATA-3, TCF-1, and LEF-1 genes to different extents, exhibit small changes in the level of CD3-epsilon mRNA, and continue to express the fibroblast-specific fibronectin gene, and the ets-1 gene. In this study we have evaluated for the first time the molecular mechanisms that underlie the repression of TCR alpha and TCR beta chain genes in T x L-cell hybrids. We have shown that multiple repression mechanisms, both direct and indirect, contribute to TCR alpha and TCR beta suppression. Repression of the expression of these genes correlated not only with the downregulation of GATA-3, TCF-1, and LEF-1 transcription factor expression, and with a change in the chromatin structure, but more importantly, with the activation of the silencer activity. Our study provides evidence for the existence of at least two negatively regulating elements, located at the TCR alpha enhancer-containing fragment and at the silencer region, which are active in our hybrid cells. We have shown that there was no correlation between the levels of GATA-3, TCF-1, and LEF-1 expression versus the level of TCR alpha mRNA in the independent hybrids. In contrast, both the silencer activity and the ability of the TCR alpha enhancer to downregulate thymidine kinase (TK) promoter activity were found to be in an inverse correlation with the ability of the different hybrid cells to express TCR alpha mRNA.

Rearrangement of the AML1/CBFA2 gene in myeloid leukemia with the 3;21 translocation: expression of co-existing multiple chimeric genes with similar functions as transcriptional repressors, but with opposite tumorigenic properties

Several recurring chromosomal translocations involve the AML1 gene at 21q22 in myeloid leukemias resulting in fusion mRNAs and chimeric proteins between AML1 and a gene on the partner chromosome. AML1 corresponds to CBFA2, one of the DNA-binding subunits of the enhancer core binding factor CBF. Other CBF DNA-binding subunits are CBFA1 and CBFA3, also known as AML3 and AML2. AML1, AML2 and AML3 are each characterized by a conserved domain at the amino end, the runt domain, that is necessary for DNA-binding and protein dimerization, and by a transactivation domain at the carboxyl end. AML1 was first identified as the gene located at the breakpoint junction of the 8;21 translocation associated with acute myeloid leukemia. The t(8;21)(q22;q22) interrupts AML1 after the runt homology domain, and fuses the 5' part of AML1 to almost all of ETO, the partner gene on chromosome 8. AML1 is an activator of several myeloid promoters; however, the chimeric AML1/ETO is a strong repressor of some AML1-dependent promoters. AML1 is also involved in the t(3;21)(q26;q22), that occurs in myeloid leukemias primarily following treatment with topoisomerase II inhibitors. We have studied five patients with a 3;21 translocation. In all cases, AML1 is interrupted after the runt domain, and is translocated to chromosome band 3q26. As a result of the t(3;21), AML1 is consistently fused to two separate genes located at 3q26. The two genes are EAP, which codes for the abundant ribosomal protein L22, and MDS1, which encodes a small polypeptide of unknown function. In one of our patients, a third gene EVI1 is also involved. EAP is the closest to the breakpoint junction with AML1, and EVI1 is the furthest away. The fusion of EAP to AML1 is not in frame, and leads to a protein that is terminated shortly after the fusion junction by introduction of a stop codon. The fusion of AML1 to MDS1 is in frame, and adds 127 codons to the interrupted AML1. Thus, in the five cases that we studied, the 3;21 translocation results in expression of two coexisting chimeric mRNAs which contain the identical runt domain at the 5' region, but differ in the 3' region. In addition, the chimeric transcript AML1/MDS1/EVI1 has also been detected in cells from one patient with the 3;21 translocation as well as in one of our patients. Several genes necessary for myeloid lineage differentiation contain the target sequence for AML1 in their regulatory regions. One of them is the CSF1R gene. We have compared the normal AML1 to AML1/MDS1, AML1/EAP and AML1/MDS1/EVI1 as transcriptional regulators of the CSF1R promoter. Our results indicate that AML1 can activate the promoter, and that the chimeric proteins compete with the normal AML1 and repress expression from the CSF1R promoter. AML1/MDS1 and AML1/EAP affect cell growth and phenotype when expressed in rat fibroblasts. However, the pattern of tumor growth of cells expressing the different chimeric genes in nude mice is different. We show that when either fusion gene is expressed, the cells lose contact inhibition and form foci over the monolayer. In addition, cells expressing AML1/MDS1 grow larger tumors in nude mice, whereas cells expressing only AML1/EAP do not form tumors, and cells expressing both chimeric genes induce tumors of intermediate size. Thus, although both chimeric genes have similar effects in transactivation assays of the CSF1R promoter, they affect cell growth differently in culture and have opposite effects as tumor promoters in vivo. Because of the results obtained with cells expressing one or both genes, we conclude that MDS1 seems to have tumorigenic properties, but that AML1/EAP seems to repress the oncogenic property of AML1/MDS1.

The high mobility group transcription factor, SOX4, transactivates the human CD2 enhancer

A strong T cell-specific enhancer is located 3' to the human CD2 gene. Six sequences within this enhancer are bound by proteins present in T cell nuclear extracts. These sequences share homology with sequences bound by several transcription factors involved in T cell- and lymphoid-specific transcription. The results presented here demonstrate that the human T cell-specific transcription factor, SOX4, is able to bind to one of these regions; further, SOX4 transactivates transcription of a reporter gene via three tandem copies of this sequence. The binding of SOX4 to this site is not via a canonical HMG protein binding sequence, identifying a novel class of binding site for this protein. A second sequence within the CD2 enhancer closely resembles the IL-2 NF-AT site. We show that it is bound by the ets-related factor, Elf1. However, unlike the IL-2 NF-AT sequence, the CD2 NF-AT-like sequence is unable to confer transcriptional inducibility on a reporter gene. Consistent with this result, we show that the observed increase in expression of CD2 protein on the cell surface following T cell activation is a post-transcriptional event.

The rat alpha 1B adrenergic receptor gene middle promoter contains multiple binding sites for sequence-specific proteins including a novel ubiquitous transcription factor

Transcription of the rat alpha 1B adrenergic receptor (alpha 1BAR) gene in the liver is controlled by three promoters that generate three mRNAs. The middle promoter (P2), located between -432 and -813 base pairs upstream from the translation start codon and lacking a TATA box, is responsible for generating the major, 2.7-kilobase mRNA-species expressed in many tissues (Gao, B., and Kunos, G. (1994) J. Biol. Chem. 269, 15762-15767). DNase I footprinting using rat liver nuclear extracts identified three protected regions in P2: footprint I (-432 to -452), footprint II (-490 to -540), and footprint III (-609 to -690). Putative response elements in footprints I and III were not analyzed except the AP2 binding site in footprint III, which could be protected by purified AP2 protein. Footprint II contains four sites corresponding to half of the NF-I consensus sequence, but DNA mobility shift assays indicate that this footprint binds two proteins distinct from NF-I: a ubiquitous CP1-related factor and another novel factor, termed alpha-Adrenergic Receptor Transcription Factor (alpha ARTF), which binds to two separate sites in this region. The alpha ARTF is widely distributed, with the highest amounts found in brain, followed by liver, kidney, lung, and spleen, but no detectable activity in heart. Deletions of alpha ARTF binding sites nearly abolished P2 promoter activity, which suggests that the alpha ARTF is essential for the transcription of the alpha 1BAR gene in most tissues.

gamma delta lineage-specific transcription of human T cell receptor gamma genes by a combination of a non-lineage-specific enhancer and silencers

The expression of the T cell receptor (TcR) gamma genes is restricted to TcR gamma delta + T lymphocytes. Transgenic and somatic cell hybrid experiments had suggested that the expression of a functionally rearranged TcR gamma gene was extinguished in TcR alpha beta + T cells, possibly by putative cis-acting transcriptional silencers. We have identified such negative cis-acting sequences in the 3' non-coding region of the human TcR gamma (TRG) locus, upstream of an enhancer located at 6.5 kb of the TcR C gamma 2 gene (TRGC2). These silencers were capable of repressing the transcription from a minimal heterologous promoter in a position- and orientation-independent fashion. When analyzed individually, the silencers and the enhancer were equally active in the TcR alpha beta + and TcR gamma delta + T cell lines studied. In contrast, the association of the enhancer with either silencer was shown to restrict transcription to the TcR gamma delta + T cell lines.

GATA-3 dominant negative mutant. Functional redundancy of the T cell receptor alpha and beta enhancers

The GATA family of transcription factors regulates a wide variety of genes, including those involved in differentiation of erythrocytes and T lymphocytes. We report here the creation of a dominant negative mutant of GATA-3, KRR, which effectively blocks wild-type GATA-1, GATA-2, and GATA-3 transactivation when co-expressed in transient assays. KRR was generated by site-directed mutagenesis while investigating a putative activation domain of GATA-3, located between its two zinc fingers. The GATA-3 KRR mutation does not affect expression, nuclear translocation, or the ability to bind to a consensus GATA sequence. KRR can suppress the activity of the minimal T cell receptor (TCR) alpha and beta enhancers by 12- and 3.4-fold, respectively. However, KRR did not have a significant effect on the activity of larger TCR-alpha and -beta enhancer fragments. Thus, functional redundancy in the TCR-alpha and -beta enhancers can compensate for the loss of GATA-3 activity.

Identification of a T cell-specific transcriptional enhancer 3' of the human T cell receptor gamma locus

Positive and negative transcriptional regulatory mechanisms are thought to play a major role in the expression of T cell antigen receptor (TCR) genes. Since the alpha beta and gamma delta T cell receptor heterodimers are expressed in a mutually exclusive fashion and since TCR genes are sequentially activated during T cell ontogeny, transcriptional activation and repression must at least in part determine T lineage-specific and developmental-specific expression of these genes. We have identified a transcriptional enhancer located 6.5 kb downstream from the human T cell receptor gamma (TRG) locus. The nucleotide sequence of the enhancer core element shows strong sequence homology to the recently identified murine C gamma 1 enhancer. The enhancer demonstrates T cell-specific activity, but not gamma delta sublineage-specificity in combination with either a heterologous or gene-specific promoter. Thus, additional regulatory elements may be required to repress the expression of rearranged TRG genes in non-gamma delta T cells.

Organization, structure, and function of 95 kb of DNA spanning the murine T-cell receptor C alpha/C delta region

We have analyzed the organization, structure, and function of the murine T-cell receptor C alpha/C delta region. This region spans 94.6 kb of DNA and contains the C alpha and C delta genes, as well as the V delta 5, J delta 2, and 50 different J alpha gene segments. Within this sequence we have identified 15 new J alpha gene segments, 40 new 5' RNA splice signals, and 40 new DNA rearrangement signals for the J alpha gene segments. The murine C alpha/C delta sequence contains an exceptionally high level of coding sequence with over 5.7% of the total sequence found in the exons. This is much more than that found in the beta-globin locus and the HPRT locus. Using the sequence data obtained from the C alpha/C delta region, we have designed simple assays to test for J alpha gene segment transcription and to determine the level of polymorphism for simple repeat sequences among different inbred strains of mice using the polymerase chain reaction. Furthermore, comparisons of this 95 kb of sequence with the available sequence from homologous regions of other species have led to the identification of a highly conserved sequence that is present throughout vertebrates and in the mouse binds lymphocyte-specific nuclear proteins. Comparisons of a 10-kb region, which includes the C alpha gene in human and mouse, average 66% sequence similarity. These studies support the contention that large-scale DNA sequencing projects of homologous regions of mouse and human will provide powerful new tools for studying the biology and evolution of loci such as the T-cell receptor and for identifying and posing new questions about the functions of conserved sequences.

Differential expression of subspecies of polyomavirus and murine leukemia virus enhancer core binding protein, PEBP2, in various hematopoietic cells

The core sequence of the enhancer of murine leukemia virus (MuLV) long terminal repeat is highly conserved in a large number of MuLV strains and appears to play an essential role when SL3-3 or Moloney strains induce T cell lymphoma in mice. We found by using the electrophoretic mobility shift assay that a polyomavirus enhancer core-binding protein, PEBP2, bound to this core motif of MuLV. We also noted that PEBP2 in several hematopoietic cell lines derived from B lymphocyte, macrophage and myelocyte lineages migrated significantly faster than the authentic PEBP2 detected in NIH3T3 fibroblasts. Interestingly, PEBP2 detected in the cell lines of T lymphocyte lineage appeared to contain both types, which were indistinguishable in electrophoretic mobility from those of NIH3T3 and of B lymphocyte, macrophage and myelocyte lineages. The treatment of the nuclear extract containing PEBP2 with phosphatase generated PEBP3, which is a subcomponent of PEBP2 and retained the same DNA-binding specificity as PEBP2. The altered mobility of hematopoietic cell-derived or T lymphocyte-derived PEBP2 was found to be due to the alteration of the mobility of PEBP3. Based on the distinct mobility of PEBP2/3 of T lymphocytes from those of other hematopoietic cells, we discuss the implication of PEBP2 in MuLV-induced T cell leukemia and T cell-specific gene expression.

Transcriptional regulation during T-cell development: the alpha TCR gene as a molecular model

The regulation of gene expression during lymphocyte differentiation is a complex process involving interactions between multiple positive and negative transcriptional regulatory elements. In this article, transcriptional regulation of the archetypal T-cell-specific gene, alpha TCR, is discussed. Major recent developments, including the identification of novel families of transcription factors that regulate multiple T-cell genes during thymocyte ontogeny and T-cell activation, are described.

The LCK gene is involved in the t(1;7)(p34;q34) in the T-cell acute lymphoblastic leukemia derived cell line, HSB-2

HSB-2 is a cell line derived from a patient who had T-cell acute lymphoblastic leukemia (T-cell ALL) with a t(1;7)(p34;q34). We used a genomic probe from the T-cell receptor beta (TCR beta) locus (7q34) to identify DNA rearrangements in HSB-2. Two rearranged BglII DNA fragments were cloned, and one of these clones was shown to contain the translocation breakpoint on the derivative chromosome I [der(I)]. We used a probe derived from this clone to isolate an unrearranged phage clone encompassing the breakpoint at Ip34. The restriction map of this clone was compared to the published maps of known protooncogenes located at Ip32-34. By restriction mapping, Southern blot analysis, and DNA sequencing we showed that the translocation breakpoint on chromosome I is located within the first intron of the LCK gene. The LCK gene codes for p56lck, a member of the SRC family of cytoplasmic tyrosine protein kinases. There are two classes of LCK transcripts (type I and type II), each expressed from a distinct promoter, and each having a unique 5' untranslated region (UTR); the protein coding regions of the two classes are identical. The breakpoint in the t(1;7) separates the two LCK promoters and juxtaposes the constant region of the TCR beta locus with the proximal promoter and with the protein-coding region of the LCK gene on the der(I) chromosome.

Regulation of the early stages of T-cell development

During the past year, there have been rapid advances in our understanding of the early events of T-cell development, at the molecular level. Studies at the transcriptional level of T-cell receptor gene regulation have started to yield important clues about how different T-cell-specific genes can share the same transcription factors and how alpha beta and gamma delta T cells are differentially regulated. In addition, studies using transgenic mice with the T-cell receptor gamma delta genes have further strengthened the separate lineage model of alpha beta and gamma delta T cells and brought into play the importance of negative cis-regulatory elements for lineage-specific determination.