Tissue-specific expression of human terminal deoxynucleotidyl transferase is regulated at the transcriptional level

Non-homologous end joining: Common interaction sites and exchange of multiple factors in the DNA repair process

Non-homologous end-joining (NHEJ) is the dominant means of repairing chromosomal DNA double strand breaks (DSBs), and is essential in human cells. Fifteen or more proteins can be involved in the detection, signalling, synapsis, end-processing and ligation events required to repair a DSB, and must be assembled in the confined space around the DNA ends. We review here a number of interaction points between the core NHEJ components (Ku70, Ku80, DNA-PKcs, XRCC4 and Ligase IV) and accessory factors such as kinases, phosphatases, polymerases and structural proteins. Conserved protein-protein interaction sites such as Ku-binding motifs (KBMs), XLF-like motifs (XLMs), FHA and BRCT domains illustrate that different proteins compete for the same binding sites on the core machinery, and must be spatially and temporally regulated. We discuss how post-translational modifications such as phosphorylation, ADP-ribosylation and ubiquitinylation may regulate sequential steps in the NHEJ pathway or control repair at different types of DNA breaks.

Identification of a new cis-regulatory element of the terminal deoxynucleotidyl transferase gene in the 5' region of the murine locus

Terminal deoxynucleotidyl transferase (TdT) expression is controlled at the transcriptional level, however, the TdT core promoter combining D, D', an initiator (Inr) and downstream basal elements (DBE) does not recapitulate the whole complex regulation of TdT expression. We hypothesized that important cis-regulatory elements of the gene are located outside of the TdT promoter. In an attempt to identify these elements, we performed DNase I hypersensitivity assays over 24kb including a 10kb region located upstream of the transcription start site (+1) and a 14kb region spanning exons and introns I to VI. Hypersensitive sites (HS) HS1 and HS2 were localized 8.5 and 8kb upstream of the transcription start site, respectively, and were exclusively detected in TdT+ cell types. HS3, HS4 and HS5 were mapped at positions -7, -3.4 and -3kb, respectively, and detected in both TdT negative and positive cells. HS6, HS7 and HS8 were detected immediately upstream of the TdT promoter. HS10 and HS11 were localized in the first and third intron of the gene. Luciferase reporter assays revealed that HS1, HS2 and HS3 synergize with the TdT promoter to activate transcription in a TdT+ pre-T cell line but not in a TdT+ pro-B cell line. In summary novel cis-regulatory elements have been identified in the 5' region of the TdT locus that synergize with the promoter to activate gene expression and our results suggest these elements may be more active in T cells.

Terminal deoxynucleotidyl transferase is down-regulated by AP-1-like regulatory elements in human lymphoid cells

Terminal deoxynucleotidyl transferase (TdT) is a template-independent DNA polymerase that catalyses the incorporation of deoxyribonucleotides into the 3'-hydroxyl end of DNA templates and is thought to increase junctional diversity of antigen receptor genes. TdT is expressed only on immature lymphocytes and acute lymphoblastic leukaemia cells and its transcriptional expression is tightly regulated. We had previously found that protein kinase C (PKC) activation down-regulates TdT expression. PKC-activation induces the synthesis of the Fos and Jun proteins, known as the major components of activation protein 1 (AP-1) transcriptional factor implicated in transcriptional control. Here we report the identification of several DNA-protein interactions within the TdT promoter region in non-TdT expressing human cells. Sequence analysis revealed the presence of a putative AP-1-like DNA-binding site, suggesting that AP-1 may play a relevant role in TdT transcriptional regulation. Using a different source of nuclear extracts and the AP-1-TdT motif as a probe we identified several DNA-protein retarded complexes in electrophoretic mobility shift assays. Super-band shifting analysis using an antibody against c-Jun protein confirmed that the main interaction is produced by a nuclear factor that belongs to the AP-1 family transcription factors. Our findings suggest that the TdT gene expression is down-regulated, at least in part, through AP-1-like transcription factors.

Substantial N diversity is generated in T cell receptor alpha genes at birth despite low levels of terminal deoxynucleotidyl transferase expression in mouse thymus

N region diversity in antigen receptors is a developmentally regulated process in B and T lymphocytes, which correlates with the differential expression of terminal deoxynucleotidyl transferase (TdT). To precisely determine the onset of TdT gene activation during T cell differentiation and thymic ontogeny, TdT expression was directly detected at the cellular level by in situ hybridization and TdT function was assessed by analyzing the distribution of N additions in alpha and beta TCR genes at early stages of development. Even though TdT transcripts were undetectable at birth, substantial N additions were observed in ValphaJalpha junctions and 3 days later in VbetaDbetaJbeta junctions, indicating that TdT expression could be induced in immature thymocytes much earlier than expected. Indeed low TdT expression level was found in TN3/4 and DP from fetal day 17, suggesting that the onset of TdT expression occurs simultaneously in both populations and may depend on microenvironmental cues. Moreover significant increase in the proportion of thymocytes expressing high levels of TdT mRNA during the first week after birth without a similar increase in the level of N diversity suggests that TdT expression and TdT function in the generation of N diversity are not strictly correlated.

T-cell specific avian TdT: characterization of the cDNA and recombinant enzyme

A cDNA clone coding for avian terminal deoxynucleotidyl transferase (TdT) has been isolated and sequenced. The size of this cDNA was 2545 bp with an open reading frame of 1521 bp and a predicted translation product of 58 kDa. Comparison of this TdT sequence with other known TdT sequences has revealed a very high degree of homology at both the DNA and predicted amino acid levels. The chicken TdT cDNA was expressed in a bacterial system and the protein was purified by affinity chromatography. The purified recombinant enzyme, with a specific activity of approximately 1700 U/mg protein, was significantly less active than TdTs from mammalian species. This finding correlates with the observation that TdT isolated from avian thymus has lower activity than that isolated from any mammalian thymus source. Northern blot hybridization analyses and reverse transcription PCR of RNA preparations were carried out with the chicken cDNA. The data generated from these experiments revealed that the TdT RNA was only expressed in the thymus and not in the bone marrow or the bursa of Fabricius during pre- and post hatching chicken development. These data suggest that while TdT is probably involved in N region addition in chicken T-cell receptor genes, it is unlikely to play a role in diversification of immunoglobulin genes.

Stage-specific induction of terminal deoxynucleotidyl transferase in a T-lymphoid line upon coculture with a thymic stromal line

We previously reported an in vitro T-cell differentiation system in which the L4 lymphoid clone was cocultured with the St3 stromal line derived from the same murine thymic tumor, 15#4T.L4 cells in L4-St3 cocultures sequentially express Thy-1 and CD4 in a manner typical of normal thymocytes. In contrast, L4 cells grown in medium alone retain their Thy-1-CD4- phenotype. We also isolated L4 subclones from the coculture with increasingly differentiated phenotypes with respect to Thy-1 and CD4. We now report induction of an additional thymocyte differentiation marker, terminal deoxynucleotidyl transferase (TdT) in 15#4T cells (and to a lesser extent subcloned L4 cells) upon coculture with St3 stroma. Coculture of 15#4T cells with St3 stroma resulted in expression of TdT as measured by ribonuclease protection for TdT RNA and Western immunoblotting for TdT protein. Cocultured L4 cells were induced for TdT expression to a lesser degree and for a shorter period of time. The magnitude of TdT RNA induction was maximal for cell lines with the least mature differentiation phenotype (15#4T and L4: Thy-1-CD4-) and decreased proportionally for subclones with increasingly mature phenotype, e.g., L4E cells (Thy-1+CD4+). TdT protein was undetectable by Western immunoblotting and immunofluorescent staining of the L4E subclone on or off stroma. Recombination-activating gene-1 (RAG-1), which is expressed in immature thymocytes during T-cell receptor rearrangement, but suppressed in mature thymocytes, was also examined using the ribonuclease protection assay.(ABSTRACT TRUNCATED AT 250 WORDS)

Initiation of transcription at the human terminal deoxynucleotidyl transferase gene promoter: a novel role for the TATA binding protein

Control of initiation of transcription of the human terminal deoxynucleotidyl transferase (TdT) gene was investigated by using an in vitro transcription assay. The precise contribution of discrete basal promoter elements to transcription initiation was determined by testing deletion and substitution mutations. The primary element, contained within the region spanning -34 to -14 bp relative to the transcription start site, accounted for 80% of basal promoter activity. TdT promoter activity required the sequence ACCCT at -24 to -20 bp since a dramatic decrease in transcription initiation was observed after mutation of this sequence, whereas mutation of the adjacent sequence from -32 to -25 bp did not alter promoter activity. The secondary element contained sequences surrounding the transcription start site and had 20% of promoter activity. Deletion of both elements completely abolished transcription initiation. Initiator characteristics of the secondary element were revealed by using the in vitro assay: promoter sequences at the transcription start site were sufficient to direct accurate initiation at a single site. Mutation of the sequence GGGTG spanning the transcription start site resulted in loss of transcription initiation. Both the primary and secondary elements were nonhomologous to corresponding regions from the mouse TdT gene promoter. While the human basal promoter functioned in the absence of TATA consensus sequences or GC-rich SP1 binding sites, it was dependent on active TFIID. In contrast to other TATA-less promoters, purified TATA binding protein substituted for the TFIID complex and restored promoter activity to TFIID-inactivated nuclear extracts.

Differential expression of terminal transferase (TdT) in acute lymphocytic leukaemia expressing myeloid antigens and TdT positive acute myeloid leukaemia as compared to myeloid antigen negative acute lymphocytic leukaemia

We examined whether the allegedly aberrant expression of the lymphoid lineage associated DNA polymerase, terminal deoxynucleotidyl transferase (TdT), in acute myeloid leukaemia (AML) is associated with alterations of the enzyme at the cellular, biochemical or transcriptional level when compared to lymphoid leukaemia (ALL), either lacking or expressing myeloid antigens. By flowcytometric analysis, the intensity of TdT staining with monoclonal anti-TdT antibody was considerably weaker in TdT+ AML and myeloid+ ALL (M+ ALL) than in myeloid- ALL (M- ALL). TdT enzyme activity in TdT+ AML was on an average 10%, and in M+ ALL 25% of that measured in M- ALL. Anti-TdT antibodies precipitated a major specific protein of identical relative molecular mass (58 kD) from metabolically labelled TdT+ myeloblasts and lymphoblasts. By Northern blot analysis and ribonuclease protection assay, TdT transcript levels were significantly lower in TdT+ myeloblasts and M+ lymphoblasts than in M- ALL (P < 0.0001). The level of TdT transcription in AML was independent of the simultaneous expression of lymphoid-specific antigens, such as CD2 and CD19. Our data demonstrate that TdT expression is downregulated in association with myeloid features, not only in AML but also in ALL. This observation may provide the molecular basis for the differential therapeutic responsiveness, particularly to glucocorticoids, in these various leukaemia subtypes.