A single universal primer for the T-cell receptor (TCR) variable genes enables enzymatic amplification and direct sequencing of TCR beta cDNA of various T-cell clones

Smg1 haploinsufficiency predisposes to tumor formation and inflammation

SMG1 is a member of the phosphoinositide kinase-like kinase family of proteins that includes ATM, ATR, and DNA-PK, proteins with known roles in DNA damage and cellular stress responses. SMG1 has a well-characterized role in nonsense-mediated decay as well as suggested roles in the DNA damage response, resistance to oxidative stress, regulation of hypoxic responses, and apoptosis. To understand the roles of SMG1 further, we generated a Genetrap Smg1 mouse model. Smg1 homozygous KO mice were early embryonic lethal, but Smg1 heterozygous mice showed a predisposition to a range of cancers, particularly lung and hematopoietic malignancies, as well as development of chronic inflammation. These mice did not display deficiencies in known roles of SMG1, including nonsense-mediated decay. However, they showed elevated basal tissue and serum cytokine levels, indicating low-level inflammation before the development of tumors. Smg1 heterozygous mice also showed evidence of oxidative damage in tissues. These data suggest that the inflammation observed in Smg1 haploinsufficiency contributes to susceptibility to cancer and that Smg1-deficient animals represent a model of inflammation-enhanced cancer development.

Use of a Pan-Vbeta primer permits the amplification and sequencing of TCRbeta chains expressed by bovine T-cell clones following a single semi-nested PCR reaction

We report in this study the design and validation of a Pan-Vbeta primer that in combination with Cbeta-specific primers enables the amplification, in a single semi-nested PCR, of TCRbeta chains expressed by bovine T-cell clones irrespective of the expressed Vbeta sequence. Using the Pan-Vbeta primer we examined the TCRbeta chains expressed by 16 Theileria parva-specific clones that had not been previously analysed. TCRbeta chain sequence was obtained from 15 of the clones following direct sequencing of the PCR product, whilst the other clone appeared to express 2 different TCRbeta chains which were characterised following sub-cloning of the PCR product. We have also successfully used the Pan-Vbeta primer to amplify the TCRbeta chains expressed by 19 T-cell clones, on which previous analysis using Vbeta-subfamily-specific primers had failed to do. Sequencing of these TCRbeta chains has identified members of 2 novel bovine Vbeta subfamilies-Vbeta5 and VbetaX. This method offers a simple and rapid method of analyzing the TCRbeta chains of bovine T-cell clones that has many potential applications in the investigation of bovine T-cell responses.

High throughput analysis of TCR-beta rearrangement and gene expression in single T cells

Analysis of T-cell receptor beta chain (TCR-beta) rearrangement is essential to investigate T-cell responses in human autoimmune diseases, infection and cancer. Since the TCR-beta locus contains 55 variable (V) region gene segments, multiple assays have been necessary to determine TCR-beta rearrangements of individual T cells. We established a seminested rtPCR method for single T-cell analysis with two sets of degenerate primers covering 76 and 24% of the TCR-Vbeta genes, respectively. The specificity of the approach was validated by screening cDNAs obtained from T-cell clones (TCC) with defined TCR-beta rearrangement. We applied the method successfully to profile TCR-beta rearrangement of single T cells sorted from body fluids or dissected tissue. Concomitant analysis of other gene transcripts allowed determining phenotype and function of TCR-beta-defined single T cells. Our fast, cost-efficient and high throughput approach will facilitate studies on T-cell responses in human diseases.

High detection rate of T-cell receptor beta chain rearrangements in T-cell lymphoproliferations by family specific polymerase chain reaction in combination with the GeneScan technique and DNA sequencing

The distinction between benign polyclonal and malignant monoclonal lymphoid disorders by morphology or immunophenotyping is frequently difficult. Therefore, the demonstration of clonal B-cell or T-cell populations by detecting identically rearranged immunoglobulin (Ig) or T-cell receptor (TCR) genes is often used to solve this diagnostic problem. Whereas the detection of rearranged Ig genes is well established, TCR gamma (γ) and beta (β) gene rearrangements often escape detection with the currently available polymerase chain reaction (PCR) assays. To establish a sensitive, specific, and rapid method for the detection of rearranged TCR-β genes, we developed a new PCR approach with family-specific Jβ primers and analyzed the resulting PCR products by high-resolution GeneScan technique. The superior efficiency of this new method was demonstrated by investigating 132 DNA samples extracted from lymph node and skin biopsy specimens (mostly formalin fixed) and blood samples of 62 patients who had a variety of T-cell lymphomas and leukemias. In all but 1 of the tumor samples (98.4%) a clonal amplificate was detectable after TCR-β PCR and the same clonal T-cell population was also found in 15 of 18 (83%) of the regional lymph nodes and in 7 of 11 (64%) of the peripheral blood samples. Direct comparison of these results with those obtained currently by the most widely applied TCR-γ PCR revealed an approximate 20% lower detection rate in the same set of samples than with the TCR-β PCR method. These results indicate that the new TCR-β PCR is most suitable for a rapid and reliable detection of clonal T-cell populations.

High detection rate of T-cell receptor beta chain rearrangements in T-cell lymphoproliferations by family specific polymerase chain reaction in combination with the GeneScan technique and DNA sequencing

The distinction between benign polyclonal and malignant monoclonal lymphoid disorders by morphology or immunophenotyping is frequently difficult. Therefore, the demonstration of clonal B-cell or T-cell populations by detecting identically rearranged immunoglobulin (Ig) or T-cell receptor (TCR) genes is often used to solve this diagnostic problem. Whereas the detection of rearranged Ig genes is well established, TCR gamma (γ) and beta (β) gene rearrangements often escape detection with the currently available polymerase chain reaction (PCR) assays. To establish a sensitive, specific, and rapid method for the detection of rearranged TCR-β genes, we developed a new PCR approach with family-specific Jβ primers and analyzed the resulting PCR products by high-resolution GeneScan technique. The superior efficiency of this new method was demonstrated by investigating 132 DNA samples extracted from lymph node and skin biopsy specimens (mostly formalin fixed) and blood samples of 62 patients who had a variety of T-cell lymphomas and leukemias. In all but 1 of the tumor samples (98.4%) a clonal amplificate was detectable after TCR-β PCR and the same clonal T-cell population was also found in 15 of 18 (83%) of the regional lymph nodes and in 7 of 11 (64%) of the peripheral blood samples. Direct comparison of these results with those obtained currently by the most widely applied TCR-γ PCR revealed an approximate 20% lower detection rate in the same set of samples than with the TCR-β PCR method. These results indicate that the new TCR-β PCR is most suitable for a rapid and reliable detection of clonal T-cell populations.

Truncated fragments in polymerase chain reaction-based DNA sequencing

Reconstitution experiments were performed by using an ordinary dye-primer protocol of a template spiked with known amounts of truncated fragments. We observed that as little as 0.2 mole-percentage of the truncated fragment caused sequence interpretation problems. Two protocols were developed for sequencing with dye-labeled terminators; this eliminates the problems with truncated fragments, which are adapted to a one-dye chemistry. One was designed for single extension sequencing using T7 DNA polymerase and one for cycle sequencing. To avoid precipitation and centrifugation and to facilitate automation, the dye-terminator protocols included the use of a biotinylated sequencing primer. Thus, the Sanger fragments were recovered and, by magnetic separation, washed and released by formamide, EDTA, and heat treatment before loading on the electrophoresis gel. Integrated procedures for sequencing PCR products using one-dye-labeled terminators suitable for automation are described. High quality data in terms of long reads and detection of polymorphisms is obtained. The protocols serve as attractive alternatives to internal labeling and dye-primer approaches.

Rapid screening of T-cell receptor (TCR) variable gene usage by multiplex PCR: application for assessment of clonal composition

The selection of various T-cell receptor (TCR) gene families and complex rearrangements during intra-thymic differentiation provide the basis for the expression of antigen specificity by mature T cells. TCR beta variable (TCRBV) transcripts can be identified by RT-PCR, but multiple reactions are required to detect all genes of the TCRBV subfamilies. We describe here a multiplex PCR method that amplifies 46 functional genes comparing 23 TCRBV families in 5 reactions where each reaction contains 4 to 7 specific primers together with a single fluorescence-tagged TCR beta constant region primer. Between 8 and 10 distinct subtypes within each of the 23 TCRBV families can be identified by analysis of the CDR3 length. Multiplex PCR products isolated from agarose gels can be subjected to direct sequencing for confirmation and definitive clonotyping if necessary. The data illustrated here show that the multiplex PCR technique is useful for screening TCRBV usage and can be easily adapted for analysis of clonal composition in T-cell populations.

Long-term alloreactive T cell lines and clones express a limited T cell receptor repertoire

Alloreactive T cells recognize either determinants of the intact donor MHC molecules displayed on the surface of transplanted-cells or peptide fragments of donor antigens associated with self-MHC molecules by means of their T cell receptors (TCR). To investigate the relationship between the TCR beta chain structure and allorecognition, we established and characterized four long-term T cell lines and seven T cell clones derived following a mixed lymphocyte reaction (MLR) between fully histoincompatible DA (RT1a) and LEW (RT1(1)) rat lymph node cells. These DA anti-LEW T cells were phenotypically CD4+, CD8-, alpha beta TCR+ and produced interferon-gamma but not IL-4, consistent with being Th1 CD4+ T cells. As might be expected, these cells were not significantly cytotoxic and did not display suppressor activity. Analysis of the TCR beta chain gene structure revealed a very restricted repertoire in both long-term lines and clones. The TCRBV6S1 gene was present in 15/21 of the alloreactive T cell mRNA transcripts but only 1/12 of unstimulated DA splenic TCR mRNA transcripts (p = 0.0018). Similarly, the TCRBJ2S1 gene was also used frequently in the alloreactive transcripts (17/21) but in only 2/12 unstimulated splenic transcripts (p = 0.0013). Furthermore, all 15 of the alloreactive TCRBV6S1 transcripts had a distinctive four amino acid N region motif not present in any of the unstimulated TCR transcripts (p = 0.0003). These experiments reveal a distinct homogeneity amongst stable allogeneic T cells in culture. If these results reflect the situation in vivo, the possibility exists that specific immunotherapy may be successful in preventing allograft rejection.

Assessment of T-cell receptor beta-chain diversity by heteroduplex analysis

The aim of this work was to search for a simple and alternative approach to the currently used methodologies for the analysis of T-cell receptor repertoire diversity. To this end we studied whether the heteroduplex analysis could be adapted to study the clonality of the T-cell receptor beta chain (TCRBV). We therefore analyzed, by sequencing, the molecular characteristics of the V-D-J junctions of numerous TCRBV chains from a variety of patients and from normal individuals, and compared the results with those obtained with the heteroduplex analysis. The latter procedure involves the amplification of the target TCRBV chains and the denaturation and renaturation of the amplified product to permit the random association of the distinct DNA strands encoding the different junctional regions. Whereas amplified material from polyclonal lymphoid cells migrates on a polyacrylamide gel as a "smear" of bands composed of different-sized polyclonal PCR fragments, the mismatched chains derived from oligoclonal populations migrate as discrete "heteroduplexes" and can be separated from the matched "homoduplex" obtained from homogeneous clonal cells. Our results provide evidence demonstrating that heteroduplex analysis can successfully be applied to the analysis of T-cell clonality in a variety of samples and can be complementary or substitute for the standard approach of TCR cloning and multiple sequencing of junctional regions. Thus, the procedure should facilitate the implementation of the analysis of TCR in diagnostic routine and should find applications in numerous physiologic and pathologic conditions.

Restriction fragment length polymorphism of the T-cell receptor beta-chain gene in dogs

Since T-cells and the T-cell receptor (TCR) play a pivotal role in the response of the immune system, they are a target for pathogenesis studies in immune mediated diseases and have been used to generate markers for T-cell dependent diseases in humans and dogs. TCR rearrangement is generated at the genomic DNA level and can be analyzed by Southern blotting techniques. In the present study this method to detect rearrangement of the TCR beta chain in the dog was critically examined. To search for restriction fragment length differences due to either inherited polymorphism or in diseases with suspected superantigen influence (X-linked severe combined immune deficiency and canine juvenile polyarteritis syndrome) 13 dog families of three different breeds were examined. In addition primary spleen cell cultures, stimulated with either phytohemagglutinin A (PHA) or staphylococcus enterotoxin A (SEA) and B (SEB) were studied. The germline digest pattern of the enzymes Pst I, Sst I, Bgl II, Eco RI and Eco RV were identical in all dogs examined with the exception of one dog with canine juvenile polyarteritis syndrome. In this dog an additional band was found in the Bgl II and Eco RV digestion suggestive of specific TCR rearrangement. Bam HI digestion revealed restriction fragment length polymorphisms (RFLPs) showing Mendelian inheritance. After digestion of the genomic DNA extracted from PHA, SEA or SEB stimulated spleen cells and Southern blot analysis, no differences in fragment patterns between the unstimulated cells and the stimulated cells could be detected. An important point to consider before a specific pattern variation between dogs is classified to be a marker for a specific disease or is used in pathogenesis studies, is the possibility of an inherited RFLP, especially after Bam HI digestion. In such studies the combined examination of the parents and the offspring must be recommended.