T-cell receptor V delta-J alpha rearrangements in human thymocytes: the role of V delta-J alpha rearrangements in T-cell receptor-delta gene deletion

Identification of TRDV-TRAJ V domains in human and mouse T-cell receptor repertoires

Here, we describe the identification of two T-cell receptors (TRs) containing TRDV genes in their TRA chains, the first one in human and the second one in mouse. First, using 5'RACE on a mixed lymphocyte-tumor cell culture (MLTC), we identified TRDV1 5'-untranslated region (UTR) and complete coding sequence rearranged productively to TRAJ24. Single-cell TR RNA sequencing (RNA-seq) of the MLTC, conducted to identify additional clonotypes, revealed that the analysis software detected the hybrid TRDV-TRAJ TRA (TRA) chain but excluded it from the final results. In a separate project, we performed TR sequencing of tumor-infiltrating lymphocytes (TILs) in a murine tumor model. Here, the predominant clonotype contained a TRA chain with a TRDV2-2-TRAJ49 rearrangement. Again, the hybrid TRA chain was not reported in the final results. Transfection of both TR cDNAs resulted in cell surface localization of TR together with CD3, suggesting a productive protein in both cases. Tumor recognition of the Homo sapiens (Homsap) TRDV1-containing TR could be demonstrated by IFN Gamma ELISA ELISpot kit, whereas the Mus musculus (Musmus) TR did not recognize a tumor-derived cell line. To determine whether the TRDV-containing TRA chains we detected were rare events or whether TRDV genes are commonly incorporated into TRA chains, we queried the NCBI Sequence Read Archive for TR single-cell RNA-seq data and analyzed 21 human and 23 murine datasets. We found that especially Homsap TRDV1, Musmus TRDV1, and to some extent Musmus TRDV2-2 are more commonly incorporated into TRA chains than several TRAV genes, making those TRDV genes a relevant contribution to TRA diversity. TRDV-containing TRA chains are currently excluded from the final results of V-(D)-J dataset analyses with the CellRanger software. We provide a work-around to avoid exclusion of those hybrid TRA chains from the final analysis results.

Human thymic T cell repertoire is imprinted with strong convergence to shared sequences

A highly diverse repertoire of T cell antigen receptors (TCR) is created in the thymus by recombination of gene segments and the insertion or deletion of nucleotides at the junctions. Using next-generation TCR sequencing we define here the features of recombination and selection in the human TCRα and TCRβ locus, and show that a strikingly high proportion of the repertoire is shared by unrelated individuals. The thymic TCRα nucleotide repertoire was more diverse than TCRβ, with 4.1 × 10⁶ vs. 0.81 × 10⁶ unique clonotypes, and contained nonproductive clonotypes at a higher frequency (69.2% vs. 21.2%). The convergence of distinct nucleotide clonotypes to the same amino acid sequences was higher in TCRα than in TCRβ repertoire (1.45 vs. 1.06 nucleotide sequences per amino acid sequence in thymus). The gene segment usage was biased, and generally all individuals favored the same genes in both TCRα and TCRβ loci. Despite the high diversity, a large fraction of the repertoire was found in more than one donor. The shared fraction was bigger in TCRα than TCRβ repertoire, and more common in in-frame sequences than in nonproductive sequences. Thus, both biases in rearrangement and thymic selection are likely to contribute to the generation of shared repertoire in humans.

Topology and expressed repertoire of the Felis catus T cell receptor loci

Background

The domestic cat (Felis catus) is an important companion animal and is used as a large animal model for human disease. However, the comprehensive study of adaptive immunity in this species is hampered by the lack of data on lymphocyte antigen receptor genes and usage. The objectives of this study were to annotate the feline T cell receptor (TR) loci and to characterize the expressed repertoire in lymphoid organs of normal cats using high-throughput sequencing.

Results

The Felis catus TRG locus contains 30 genes: 12 TRGV, 12 TRGJ and 6 TRGC, the TRB locus contains 48 genes: 33 TRBV, 2 TRBD, 11 TRBJ, 2 TRBC, the TRD locus contains 19 genes: 11 TRDV, 2 TRDD, 5 TRDJ, 1 TRDC, and the TRA locus contains 127 genes: 62 TRAV, 64 TRAJ, 1 TRAC. Functional feline V genes form monophyletic clades with their orthologs, and clustering of multimember subgroups frequently occurs in V genes located at the 5′ end of TR loci. Recombination signal (RS) sequences of the heptamer and nonamer of functional V and J genes are highly conserved. Analysis of the TRG expressed repertoire showed preferential intra-cassette over inter-cassette rearrangements and dominant usage of the TRGV2–1 and TRGJ1–2 genes. The usage of TRBV genes showed minor bias but TRBJ genes of the second J-C-cluster were more commonly rearranged than TRBJ genes of the first cluster. The TRA/TRD V genes almost exclusively rearranged to J genes within their locus. The TRAV/TRAJ gene usage was relatively balanced while the TRD repertoire was dominated by TRDJ3.

Conclusions

This is the first description of all TR loci in the cat. The genomic organization of feline TR loci was similar to that of previously described jawed vertebrates (gnathostomata) and is compatible with the birth-and-death model of evolution. The large-scale characterization of feline TR genes provides comprehensive baseline data on immune repertoires in healthy cats and will facilitate the development of improved reagents for the diagnosis of lymphoproliferative diseases in cats. In addition, these data might benefit studies using cats as a large animal model for human disease.

Visualization and quantification of monoallelic TCRα gene rearrangement in αβ T cells

T-cell receptor α (TCRα) chain rearrangement is not constrained by allelic exclusion and thus αβ T cells frequently have rearranged both alleles of this locus. Thereby, stepwise secondary rearrangements of both TCRα loci further increase the odds for generation of an α-chain that can be positively selected in combination with a pre-existing TCRβ chain. Previous studies estimated that approximately 2-12% of murine and human αβ T cells still carry one TCRα locus in germline configuration, which must comprise a partially or even fully rearranged TCRδ locus. However, these estimates are based on a relatively small amount of individual αβ T-cell clones and αβ T-cell hybridomas analyzed to date. To address this issue more accurately, we made use of a mouse model, in which a fluorescent reporter protein is introduced into the constant region of the TCRδ locus. In this TcrdH2BeGFP system, fluorescence emanating from retained TCRδ loci enabled us to quantify monoallelically rearranged αβ T cells on a single-cell basis. Via fluorescence-activated cell sorting analysis, we determined the frequency of monoallelic TCRα rearrangements to be 1.7% in both peripheral CD4(+) and CD8(+) αβ T cells. Furthermore, we found a skewed 5' Jα gene utilization of the rearranged TCRα allele in T cells with monoallelic TCRα rearrangements. This is in line with previous descriptions of a tight interallelic positional coincidence of Jα gene segments used on both TCRα alleles. Finally, analysis of T cells from transgenic mice harboring only one functional TCRα locus implied the existence of very rare unusual translocation or episomal reintegration events of formerly excised TCRδ loci.

Lymphocyte homeostasis and the antitumor immune response

Lymphocyte homeostasis is regulated by proliferation of antigen-responsive T-cells in the peripheral circulation and their apoptosis. Patients with cancer have altered lymphocyte homeostasis. Spontaneous apoptosis of circulating CD8(+) antigen-responding effector T-cells contributes to rapid lymphocyte turnover and depressed absolute numbers of T-cell subsets observed in patients with cancer. A rapid transit of naive CD8(+) T-cells to the expanded memory pool and enhanced apoptosis of antitumor effector T-cells in the peripheral circulation of patients with cancer are partly responsible for this rapid lymphocyte turnover. Future strategies for restoration of normal lymphocyte homeostasis in cancer will involve therapies with survival cytokines and factors selected for extending survival of antitumor effector cells and establishing long-term immunologic memory.

Gene discovery at the human T-cell receptor alpha/delta locus

The human T-cell receptor (TCR) alpha/delta variable loci are interspersed on the chromosome 14q11 and consist of 57 intergenic spaces ranging from 4 to 100 kb in length. To elucidate the evolutionary history of this locus, we searched the intergenic spaces of all TCR alpha/delta variable (TRAV/DV) genes for pseudogenes and potential protein-coding genes. We applied direct open reading frame (ORF) searches, an exon-finding algorithm and comparative genomics. Two TRAV/DV pseudogenes were discovered bearing 80 and 65% sequence similarity to TRAV14DV4 and TRAV9-1/9-2 genes, respectively. A gene bearing 85% sequence identity to B lymphocyte activation-related protein, BC-1514, upstream of TRAV26-2 was also discovered. This ORF (BC-1514tcra) is a member of a gene family whose evolutionary history and function are not known. In total, 36 analogs of this gene exist in the human, the chimpanzee, the Rhesus monkey, the frog and the zebrafish. Phylogenetic analyses show convergent evolution of these genes. Assays for the expression of BC-1514tcra revealed transcripts in the bone marrow, thymus, spleen, and small intestine. These assays also showed the expression of another analog to BC-1514, found on chromosome 5 in the bone marrow and thymus RNA. The existence of at least 17 analogs at various locations in the human genome and in nonsyntenic chromosomes of the chimpanzee suggest that BC-1514tcra, along with its analogs may be transposable elements with evolved function(s). The identification of conserved putative serine phosphorylation sites provide evidence of their possible role(s) in signal transduction events involved in B cell development and differentiation.

Recent thymic emigrants and subsets of naive and memory T cells in the circulation of patients with head and neck cancer

Apoptosis of circulating CD8+ T lymphocytes is a frequent finding in patients with cancer. T-cell output by the thymus or antigen-driven expansion of circulating T cells could compensate for apoptosis and thus normalize their homeostasis. We studied the frequency of recent thymic emigrants (RTE) identified by T-cell receptor excision circles (TREC) and of naive and memory T-cell subsets in peripheral blood samples obtained from 39 patients with head and neck cancer (HNC) and 33 age-matched controls (NC). TREC numbers were determined by real-time quantitative PCR, and CD8+CD45RO-CD27+ or CD4+CD45RO-CD27+ T-cell subsets were quantified by flow cytometry. Age-associated decreases in TREC numbers and proportions of naive CD8+ and CD4+ T-cell subsets were significantly greater in cancer patients than NC. In contrast, the memory compartment was expanded, with increased proportions of CD4+CD45RO+ but not CD8+CD45RO+ T cells, in cancer patients vs. NC. These alterations did not normalize in patients who were NED. The data suggest that lower thymic output combined with rapid turnover of naive CD8+ T cells account for altered lymphocyte homeostasis in HNC patients. The defect persists long after curative treatments and may contribute to immune cell dysregulation in patients with cancer.

Evolution of the variable gene segments and recombination signal sequences of the human T-cell receptor alpha/delta locus

The T-cell receptor (TCR) alpha and delta loci are particularly interesting because of their unique genomic structure, in that the gene segments for each locus are interspersed. The origin of this remarkable gene segment arrangement is obscure. In this report, we investigated the evolution of the TCRalpha and delta variable loci and their respective recombination signal sequences (RSSs). Our phylogenetic analyses divided the alpha and delta variable gene segments into two major groups each with distinguishing motifs in both the framework and complementarity determining regions (CDRs). Sequence analyses revealed that TCRdelta variable segments share similar CDR2 sequences with immunoglobulin light chain variable segments, possibly revealing similar evolutionary histories. Maximum likelihood analysis of the region on Chromosome 14q11.2 containing the loci revealed two possible ancestral TCR alpha/delta variable segments, TRDV2 and TRAV1-1/ 1-2, respectively. Maximum parsimony revealed different evolutionary patterns between the variable segment and RSS of the same variable gene arguing for dissimilar evolutionary origins. Two models could account for this difference: a V(D)J recombination activity involving embedded heptamer-like motifs in the germline genome, or, more plausibly, an unequal sister chromatid crossing-over. Either mechanism would have resulted in increased diversity for the adaptive immune system.

Vδ2-Jα rearrangements are frequent in precursor-B–acute lymphoblastic leukemia but rare in normal lymphoid cells

The frequently occurring T-cell receptor delta (TCRD) deletions in precursor-B–acute lymphoblastic leukemia (precursor-B–ALL) are assumed to be mainly caused by Vδ2-Jα rearrangements. We designed a multiplex polymerase chain reaction tified clonal Vδ2-Jα rearrangements in 141 of 339 (41%) childhood and 8 of 22 (36%) adult precursor-B–ALL. A significant proportion (44%) of Vδ2-Jα rearrangements in childhood precursor-B–ALL were oligoclonal. Sequence analysis showed preferential usage of the Jα29 gene segment in 54% of rearrangements. The remaining Vδ2-Jα rearrangements used 26 other Jα segments, which included 2 additional clusters, one involv ing the most upstream Jα segments (ie, Jα48 to Jα61; 23%) and the second cluster located around the Jα9 gene segment (7%). Real-time quantitative PCR studies of normal lymphoid cells showed that Vδ2 rearrangements to upstream Jα segments occurred at low levels in the thymus (10–2 to 10–3) and were rare (generally below 10–3) in B-cell precursors and mature T cells. Vδ2-Jα29 rearrangements were virtually absent in normal lymphoid cells. The monoclonal Vδ2-Jα rearrangements in precursor-B–ALL may serve as patient-specific targets for detection of minimal residual disease, because they show high sensitivity (10–4 or less in most cases) and good stability (88% of rearrangements preserved at relapse).

Design and standardization of PCR primers and protocols for detection of clonal immunoglobulin and T-cell receptor gene recombinations in suspect lymphoproliferations: report of the BIOMED-2 Concerted Action BMH4-CT98-3936

In a European BIOMED-2 collaborative study, multiplex PCR assays have successfully been developed and standardized for the detection of clonally rearranged immunoglobulin (Ig) and T-cell receptor (TCR) genes and the chromosome aberrations t(11;14) and t(14;18). This has resulted in 107 different primers in only 18 multiplex PCR tubes: three VH-JH, two DH-JH, two Ig kappa (IGK), one Ig lambda (IGL), three TCR beta (TCRB), two TCR gamma (TCRG), one TCR delta (TCRD), three BCL1-Ig heavy chain (IGH), and one BCL2-IGH. The PCR products of Ig/TCR genes can be analyzed for clonality assessment by heteroduplex analysis or GeneScanning. The detection rate of clonal rearrangements using the BIOMED-2 primer sets is unprecedentedly high. This is mainly based on the complementarity of the various BIOMED-2 tubes. In particular, combined application of IGH (VH-JH and DH-JH) and IGK tubes can detect virtually all clonal B-cell proliferations, even in B-cell malignancies with high levels of somatic mutations. The contribution of IGL gene rearrangements seems limited. Combined usage of the TCRB and TCRG tubes detects virtually all clonal T-cell populations, whereas the TCRD tube has added value in case of TCRgammadelta(+) T-cell proliferations. The BIOMED-2 multiplex tubes can now be used for diagnostic clonality studies as well as for the identification of PCR targets suitable for the detection of minimal residual disease.

Identification of a new cluster of T-cell receptor delta recombining elements

Within the human T-cell receptor delta (TCRD) gene we have identified a new cluster of seven delta recombining elements (deltaRec2.1-2.7), located 2.6-5.2 kilobases downstream of the Vdelta2 gene segment. The deltaRec2 elements are isolated recombining signal sequences (RSS), which were shown to rearrange with the Ddelta3 and Jdelta1 segments of the TCRD gene as well as with the psiJalpha of the TCRA gene. Rearrangements involving the deltaRec2 elements were found in all peripheral blood (PB) samples from 10 healthy individuals, although their frequency was about 100-fold lower than that of classical deltaRec rearrangements. The total frequency of deltaRec2 rearrangements was lower in PB T lymphocytes, as compared with thymocytes, suggesting that they are deleted during T-cell development. The decrease of the frequency of the deltaRec2-Ddelta3 rearrangements was most prominent: 11 times lower in PB T lymphocytes than in thymocytes. Since the deltaRec2-Jdelta1 rearrangements contained the Ddelta3 segment in the junctional region, we assume that they are derived from the deltaRec2-Ddelta3 rearrangements. In contrast, the majority of deltaRec2-psiJalpha rearrangements did not contain the Ddelta3 segment, indicating that they are single step rearrangements. The deltaRec2-Jdelta1 and deltaRec2-psiJalpha rearrangements seem to be T-lineage specific, but the deltaRec2-Ddelta3 rearrangements were also found at very low frequencies in B lymphocytes and natural killer cells. Our results suggest that deltaRec2 rearrangements are transient steps in the recombinatorial process of the TCRAD locus and are probably deleted by subsequent Valpha-Jalpha rearrangements. We hypothesize, that in a similar manner to the classical deltaRec rearrangements, the deltaRec2 rearrangements might also contribute to T-cell differentiation towards the TCR-alphabeta lineage.

Decreased levels of recent thymic emigrants in peripheral blood of simian immunodeficiency virus-infected macaques correlate with alterations within the thymus

The thymus is responsible for de novo production of CD4(+) and CD8(+) T cells and therefore is essential for T-cell renewal. The goal of this study was to assess the impact of simian immunodeficiency virus (SIV) infection on the production of T cells by the thymus. Levels of recent thymic emigrants within the peripheral blood were assessed through quantification of macaque T-cell receptor excision circles (TREC). Comparison of SIV-infected macaques (n = 15) to uninfected macaques (n = 23) revealed stable or increased TREC levels at 20 to 34 weeks postinfection. Further assessment of SIV-infected macaques (n = 4) determined that TREC levels decreased between 24 and 48 weeks postinfection. Through the assessment of longitudinal time points in three additional SIVmac239-infected macaques, the SIV infection was divided into two distinct phases. During phase 1 (16 to 30 weeks), TREC levels remained stable or increased within both the CD4 and CD8 T-cell populations. During phase 2 (after 16 to 30 weeks), TREC levels declined in both T-cell populations. As has been described for human immunodeficiency virus (HIV)-infected patients, this decline in TREC levels did at times correlate with an increased level of T-cell proliferation (Ki67(+) cells). However, not all TREC decreases could be attributed to increased T-cell proliferation. Further evidence for thymic dysfunction was observed directly in a SIVmac239-infected macaque that succumbed to simian AIDS at 65 weeks postinfection. The thymus of this macaque contained an increased number of memory/effector CD8(+) T cells and an increased level of apoptotic cells. In summary, reduced levels of TREC can be observed beginning at 16 to 30 weeks post-SIV infection and correlate with changes indicative of dysfunction within the thymic tissue. SIV infection of macaques will be a useful model system to elucidate the mechanisms responsible for the thymic dysfunction observed in HIV-infected patients.

Evidence for thymic function in the elderly

The thymus represents the major site of lymphopoiesis of T-cell receptor (TCR) alphabeta T-cells. Age-related involution may affect its potential to reconstitute T-cells that are lost during HIV infection, chemotherapy, and bone marrow transplantation. However, there is mounting evidence that the age-related changes in the thymus are quantitative, not qualitative, and recent data suggest that the adult thymus can indeed contribute to T-cell reconstitution. Using newer methods to assess thymic function, it can be shown that the increases in naïve T-cell numbers in patients receiving antiretroviral therapy for AIDS are largely derived from the thymus. This provides direct evidence for the functional capacity of the adult thymus.