Inducible expression of a p56Lck transgene reveals a central role for Lck in the differentiation of CD4 SP thymocytes.

The T lymphocyte-specific protein tyrosine kinase p56lck (Lck) is an essential component of the TCR-mediated signal transduction complex. Lck knockout mice have reduced numbers of double-positive thymocytes and very few mature single-positive cells, particularly of the CD4 lineage. Here we demonstrate the ability of a tetracycline-based tissue-specific inducible Lck transgene to restore expansion of early thymocytes and maturation of single-positive cells in Lckneg mice upon induction with doxycycline. Restoration of Lck expression is particularly important for positive selection to the CD4+ lineage but has a lesser impact on selection to the CD8+ lineage, suggesting activation of Lck is an important component of the signals involved in lineage choice during thymic differentiation.

Heterochromatin protein 1 modifies mammalian PEV in a dose- and chromosomal-context-dependent manner.

Locus control regions (LCRs) are gene regulatory elements in mammals that can overcome the highly repressive effects normally associated with heterochromatic transgene locations (for example the centromere) in mice. Deletion of essential LCR sequences renders the cognate gene susceptible to this form of repression, so a proportion of the cells from transgenic mice that would normally express the transgene are silenced-a phenomenon known as position effect variegation (PEV). We show here that PEV can also occur when the transgene is non-centromeric and that the extent of variegation can be developmentally regulated. Furthermore, by overexpressing a mammalian homologue (M31) of Drosophila melanogaster heterochromatin protein 1 (HP1; refs 7,8) in transgenic mouse lines that exhibit PEV, it is possible to modify the proportion of cells that silence the transgene in a dose-dependent manner. Thus, we show M31 overexpression to have two contrasting effects which are dependent on chromosomal context: (i) it enhanced PEV in those lines with centromeric or pericentromeric transgene locations; and (ii) it suppressed PEV when the transgene was non-centromeric. Our results indicate that components or modifiers of heterochromatin may have a chromosomal-context-dependent role in gene silencing and activation decisions in mammals.

Human HMG box transcription factor HBP1: a role in hCD2 LCR function.

The locus control region (LCR) of the human CD2 gene (hCD2) confers T cell-specific, copy-dependent and position-independent gene expression in transgenic mice. This LCR consists of a strong T cell-specific enhancer and an element without enhancer activity (designated HSS3), which is required for prevention of position effect variegation (PEV) in transgenic mice. Here, we identified the HMG box containing protein-1 (HBP1) as a factor binding to HSS3 of the hCD2 LCR. Within the LCR, HBP1 binds to a novel TTCATTCATTCA sequence that is higher in affinity than other recently reported HBP1-binding sites. Mice transgenic for a hCD2 LCR construct carrying a deletion of the HBP1-binding sequences show a propensity for PEV if the transgene integrates in a heterochromatic region of the chromosome such as the centromere or telomere. We propose that HBP1 plays an important role in chromatin opening and remodelling activities by binding to and bending the DNA, thus allowing DNA-protein and/or protein-protein interactions, which increase the probability of establishing an active locus.

Bad can act as a key regulator of T cell apoptosis and T cell development.

Bad is a distant relative of Bcl-2 and acts to promote cell death. Here, we show that Bad expression levels are greatly increased in thymocytes during apoptosis. We generated bad transgenic mice to study the action of upregulated Bad expression on T cell apoptosis. The T cells from these mice are highly sensitive to apoptotic stimuli, including anti-CD95. The numbers of T cells are greatly depleted and the processes of T cell development and selection are perturbed. We show that the proapoptotic function of Bad in primary T cells is regulated by Akt kinase and that Bad overexpression enhances both cell cycle progression and interleukin 2 production after T cell activation. These data suggest that Bad can act as a key regulator of T cell apoptosis and that this is a consequence of its upregulation after exposure to death stimuli.

Hierarchical interactions of control elements determine CD8alpha gene expression in subsets of thymocytes and peripheral T cells.

CD4 and CD8 are crucial for the development and function of T cells. An intergenic deoxyribonuclease I hypersensitive site region (cluster CIII) directs expression in mature CD8 T cells only. Here, we show that two further independent regions from the CD8 gene locus in conjunction with cluster CIII restore transgene expression in appropriate immature thymocytes. Deletion of two of the intergenic cluster CIII DNaseI-HSS in homozygous mutant mice affects expression of CD8alphaalpha homodimers on intraepithelial T cells (IEL), particularly on the gammadeltaTCR+ subset. Surprisingly, none of the thymocyte or peripheral alphabetaTCR T cell subsets are affected by this mutation, indicating hierarchical activation of these elements within the different T cell subsets.

A region in the CD8 gene locus that directs expression to the mature CD8 T cell subset in transgenic mice.

The coreceptors CD4 and CD8 play a crucial role during thymocyte development and T cell effector function, and their expression is developmentally regulated. To determine the underlying molecular mechanisms of CD8 gene regulation we cloned the murine CD8 gene locus from genomic libraries and analyzed this region for deoxyribonuclease (DNase I) hypersensitive sites (HSS). Here we report, using transgenic mice, deletion analysis of one of the identified clusters of DNase I hypersensitivity, consisting of three DNase I-HSS and located in the intergenic region between the CD8alpha and CD8beta genes. Our data show that at least two of the DNase I-HSS constituting this cluster are individually sufficient to direct CD8alpha or heterologous transgene expression to the mature CD8 single-positive T cell subset and that this expression coincides temporally with the appearance of positively selected T cells.

A CD8 genomic fragment that directs subset-specific expression of CD8 in transgenic mice.

Helper and cytotoxic T cell subsets require the expression of different coreceptors (CD4 and CD8, respectively) for their development and function. We have cloned the CD8 gene locus from genomic cosmid and P1 libraries and analyzed the region around the CD8alpha and CD8beta genes for gene expression regulatory elements. DNase I (DNase I) hypersensitivity analysis of 80 kb in the CD8 locus identified four clusters of putative regulatory regions, three of which are thymocyte specific. Transgenic mice carrying the cloned CD8alphabeta genomic locus and containing the identified DNase I-hypersensitive site clusters express the transgenic CD8 in a developmentally regulated, tissue-specific, and CD8 T cell subset-specific manner.

Transgene-encoded human CD2 acts in a dominant negative fashion to modify thymocyte selection signals in mice.

CD2 is a cell surface glycoprotein present on all T cells which has been shown to function as an adhesion and signaling molecule. Expressed early in T cell development, human CD2 (HCD2) has been suggested to play a role during thymopoiesis. However, the relevance of CD2 in T cell development has been called into question recently, as neither disruption of the CD2 gene nor anti-CD2 antibody treatment of fetal thymic organ cultures in mouse were shown to have any discernible consequences. We have expressed HCD2 at high levels in transgenic mice and found a profound effect of the transgene on thymocyte differentiation. Transgenic thymuses are considerably reduced in cell number as a consequence of increased apoptosis of double-positive (DP) thymocytes in the cortex. The remaining DP cells have up-regulated levels of T cell receptor (TCR) and are resistant to apoptosis mediated by administration of antigen. These effects are dependent on the cytoplasmic domain of HCD2, as mice expressing comparable levels of a tailless HCD2 transgene have a normal phenotype. The HCD2 cytoplasmic domain contains several regions of identity with mouse CD2 and can interact effciently with mouse intracellular signaling machinery. These results suggest there is considerable cross-talk between CD2 and TCR on developing thymocytes with consequences for the stimulation threshold of mature T cells.

The cytoplasmic domain of CD4 promotes the development of CD4 lineage T cells.

Thymocytes must bind major histocompatibility complex (MHC) proteins on thymic epithelial cells in order to mature into either CD8+ cytotoxic T cells or CD4+ helper T cells. Thymic precursors express both CD8 and CD4, and it has been suggested that the intracellular signals generated by CD8 or CD4 binding to class I or II MHC, respectively, might influence the fate of uncommitted cells. Here we test the notion that intracellular signaling by CD4 directs the development of thymocytes to a CD4 lineage. A hybrid protein consisting of the CD8 extracellular and transmembrane domains and the cytoplasmic domain of CD4 (CD884) should bind class I MHC but deliver a CD4 intracellular signal. We find that expression of a hybrid CD884 protein in thymocytes of transgenic mice leads to the development of large numbers of class I MHC-specific, CD4 lineage T cells. We discuss these results in terms of current models for CD4 and CD8 lineage commitment.

Locus control region function and heterochromatin-induced position effect variegation.

Human CD2 locus control region (LCR) sequences are shown here to be essential for establishing an open chromatin configuration. Transgenic mice carrying an hCD2 mini-gene attached only to the 3' CD2 transcriptional enhancer exhibited variegated expression when the transgene integrated in the centromere. In contrast, mice carrying a transgene with additional 3' sequences showed no variegation even when the latter integrated in centromeric positions. This result suggests that LCRs operate by ensuring an open chromatin configuration and that a short region, with no enhancer activity, functions in the establishment, maintenance, or both of an open chromatin domain.

Tolerance in TCR/cognate antigen double-transgenic mice mediated by incomplete thymic deletion and peripheral receptor downregulation.

Influenza nucleoprotein (NP)-specific T-cell receptor transgenic mice (F5) were crossed with transgenic mice expressing the cognate antigenic protein under the control of the H-2Kb promoter. Double-transgenic mice show negative selection of thymocytes at the CD4+8+TCRlo to CD4+8+TCRhi transition stage. A few CD8+ T cells, however, escape clonal deletion, and in the peripheral lymphoid organs of these mice, they exhibit low levels of the transgenic receptor and upregulated levels of the CD44 memory marker. Such cells do not proliferate upon exposure to antigen stimulation in vivo or ex vivo, however, they can develop low but detectable levels of antigen-specific cytotoxic function after stimulation in vitro in the presence of IL-2.

Improved version of a human CD2 minigene based vector for T cell-specific expression in transgenic mice.

A human CD2 minigene cassette has been used in the past to express several reporter genes in the T cell lineage of transgenic mice. However, in order to achieve appreciable levels of expression it has been necessary to integrate many copies of the transgene. In this report we describe an improved version of this cassette. The new cassette directs the expression of a reporter mouse CD8 alpha cDNA on all T cells of transgenic mice with an efficiency ten times higher than the previous cassette. The new cassette includes 5 kb 5' and 5.5 kb 3' flanking sequences containing, respectively, the promoter and locus control region (LCR) of the human CD2 gene. The LCR confers position independent, transgene copy number dependent expression of the genes linked to it in transgenic mice. The cassette also provides a transcription initiation site, the first intron of human CD2 gene and the two polyadenylation signals found in the 3' untranslated region of hCD2 gene.

Random activation of a transgene under the control of a hybrid hCD2 locus control region/Ig enhancer regulatory element.

Locus control regions such as those of human CD2 and beta-globin differ from classical enhancers in that, whereas the former confer high level, copy-dependent, position-independent expression to linked genes in transgenic mice, the latter do not, expression levels being dependent on the site of integration. We report that the position independence of the CD2 locus control region is modified by coupling it to the immunoglobulin heavy chain enhancer. Whilst in the majority of transgenic lines the Ig heavy chain enhancer has little or no effect on T cell expression of the hCD2 transgene, in others transgene expression is non-specifically extinguished in a proportion of lymphoid cells. The transgenic locus chromatin appears inaccessible to DNase I in these cells, which do not express the gene. Furthermore, mice homozygous for the hybrid hCD2-Ig heavy chain enhancer construct contain T cells with both an active and an inactive transgene. The 'decision' to express or repress the gene appears to be a random process which involves each chromosome separately, occurs at early stages in differentiation and is heritable by daughter cells. These data suggest the possibility that stochastic decisions might control a number of biological processes.

Functional commitment to helper T cell lineage precedes positive selection and is independent of T cell receptor MHC specificity.

Thymocyte differentiation proceeds from double positive CD4+CD8+ to single positive T cells. It has been proposed that this process occurs by an instructive or a stochastic mechanism. In this report, we show that in recombination-deficient mice (RAG-1-I-) constitutive expression of a CD8 transgene allows maturation of CD4+(CD8tg+) cells, which express mature levels of a transgenic class I-restricted T cell receptor, F5. Rescued F5+CD4+(CD8tg+) cells have equivalent levels of T cell receptor expression as CD8end+ cells, respond to cognate antigen and, upon stimulation, they exhibit a phenotype characteristic of CD4+ helper T cells. These data are consistent with a model of differentiation that predicts that thymocytes become functionally committed to a helper or cytotoxic lineage before the final step of positive selection and independently of MHC specificity of their T cell receptor.