Paired analysis of TCRα and TCRβ chains at the single-cell level in mice (original) (raw)
Technical AdvanceImmunology Free access | 10.1172/JCI44752
Jennifer L. McClaren,1 Thomas H. Oguin III,1 William Rothwell,1 Brandon Todd,1 Melissa Y. Morris,1 Jared Becksfort,1 Cory Reynolds,1 Scott A. Brown,1 Peter C. Doherty,1,2 and Paul G. Thomas1
1St Jude Children’s Research Hospital, Memphis, Tennessee, USA. 2Department of Microbiology and Immunology, University of Melbourne, Melbourne, Victoria, Australia.
Address correspondence to: Paul G. Thomas, Department of Immunology, St. Jude Children’s Research Hospital, 262 Danny Thomas Place/MS 351, Memphis, Tennessee 38105-3678, USA. Phone: 901.595.6507; Fax: 901.595.3107; E-mail: paul.thomas@stjude.org.
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1St Jude Children’s Research Hospital, Memphis, Tennessee, USA. 2Department of Microbiology and Immunology, University of Melbourne, Melbourne, Victoria, Australia.
Address correspondence to: Paul G. Thomas, Department of Immunology, St. Jude Children’s Research Hospital, 262 Danny Thomas Place/MS 351, Memphis, Tennessee 38105-3678, USA. Phone: 901.595.6507; Fax: 901.595.3107; E-mail: paul.thomas@stjude.org.
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1St Jude Children’s Research Hospital, Memphis, Tennessee, USA. 2Department of Microbiology and Immunology, University of Melbourne, Melbourne, Victoria, Australia.
Address correspondence to: Paul G. Thomas, Department of Immunology, St. Jude Children’s Research Hospital, 262 Danny Thomas Place/MS 351, Memphis, Tennessee 38105-3678, USA. Phone: 901.595.6507; Fax: 901.595.3107; E-mail: paul.thomas@stjude.org.
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1St Jude Children’s Research Hospital, Memphis, Tennessee, USA. 2Department of Microbiology and Immunology, University of Melbourne, Melbourne, Victoria, Australia.
Address correspondence to: Paul G. Thomas, Department of Immunology, St. Jude Children’s Research Hospital, 262 Danny Thomas Place/MS 351, Memphis, Tennessee 38105-3678, USA. Phone: 901.595.6507; Fax: 901.595.3107; E-mail: paul.thomas@stjude.org.
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1St Jude Children’s Research Hospital, Memphis, Tennessee, USA. 2Department of Microbiology and Immunology, University of Melbourne, Melbourne, Victoria, Australia.
Address correspondence to: Paul G. Thomas, Department of Immunology, St. Jude Children’s Research Hospital, 262 Danny Thomas Place/MS 351, Memphis, Tennessee 38105-3678, USA. Phone: 901.595.6507; Fax: 901.595.3107; E-mail: paul.thomas@stjude.org.
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1St Jude Children’s Research Hospital, Memphis, Tennessee, USA. 2Department of Microbiology and Immunology, University of Melbourne, Melbourne, Victoria, Australia.
Address correspondence to: Paul G. Thomas, Department of Immunology, St. Jude Children’s Research Hospital, 262 Danny Thomas Place/MS 351, Memphis, Tennessee 38105-3678, USA. Phone: 901.595.6507; Fax: 901.595.3107; E-mail: paul.thomas@stjude.org.
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1St Jude Children’s Research Hospital, Memphis, Tennessee, USA. 2Department of Microbiology and Immunology, University of Melbourne, Melbourne, Victoria, Australia.
Address correspondence to: Paul G. Thomas, Department of Immunology, St. Jude Children’s Research Hospital, 262 Danny Thomas Place/MS 351, Memphis, Tennessee 38105-3678, USA. Phone: 901.595.6507; Fax: 901.595.3107; E-mail: paul.thomas@stjude.org.
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1St Jude Children’s Research Hospital, Memphis, Tennessee, USA. 2Department of Microbiology and Immunology, University of Melbourne, Melbourne, Victoria, Australia.
Address correspondence to: Paul G. Thomas, Department of Immunology, St. Jude Children’s Research Hospital, 262 Danny Thomas Place/MS 351, Memphis, Tennessee 38105-3678, USA. Phone: 901.595.6507; Fax: 901.595.3107; E-mail: paul.thomas@stjude.org.
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1St Jude Children’s Research Hospital, Memphis, Tennessee, USA. 2Department of Microbiology and Immunology, University of Melbourne, Melbourne, Victoria, Australia.
Address correspondence to: Paul G. Thomas, Department of Immunology, St. Jude Children’s Research Hospital, 262 Danny Thomas Place/MS 351, Memphis, Tennessee 38105-3678, USA. Phone: 901.595.6507; Fax: 901.595.3107; E-mail: paul.thomas@stjude.org.
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1St Jude Children’s Research Hospital, Memphis, Tennessee, USA. 2Department of Microbiology and Immunology, University of Melbourne, Melbourne, Victoria, Australia.
Address correspondence to: Paul G. Thomas, Department of Immunology, St. Jude Children’s Research Hospital, 262 Danny Thomas Place/MS 351, Memphis, Tennessee 38105-3678, USA. Phone: 901.595.6507; Fax: 901.595.3107; E-mail: paul.thomas@stjude.org.
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1St Jude Children’s Research Hospital, Memphis, Tennessee, USA. 2Department of Microbiology and Immunology, University of Melbourne, Melbourne, Victoria, Australia.
Address correspondence to: Paul G. Thomas, Department of Immunology, St. Jude Children’s Research Hospital, 262 Danny Thomas Place/MS 351, Memphis, Tennessee 38105-3678, USA. Phone: 901.595.6507; Fax: 901.595.3107; E-mail: paul.thomas@stjude.org.
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Published December 6, 2010 -More info
Published December 6, 2010 -Version history
Received: August 13, 2010; Accepted: October 20, 2010
Characterizing the TCRα and TCRβ chains expressed by T cells responding to a given pathogen or underlying autoimmunity helps in the development of vaccines and immunotherapies, respectively. However, our understanding of complementary TCRα and TCRβ chain utilization is very limited for pathogen- and autoantigen-induced immunity. To address this problem, we have developed a multiplex nested RT-PCR method for the simultaneous amplification of transcripts encoding the TCRα and TCRβ chains from single cells. This multiplex method circumvented the lack of antibodies specific for variable regions of mouse TCRα chains and the need for prior knowledge of variable region usage in the TCRβ chain, resulting in a comprehensive, unbiased TCR repertoire analysis with paired coexpression of TCRα and TCRβ chains with single-cell resolution. Using CD8+ CTLs specific for an influenza epitope recovered directly from the pneumonic lungs of mice, this technique determined that 25% of such effectors expressed a dominant, nonproductively rearranged Tcra transcript. T cells with these out-of-frame Tcra mRNAs also expressed an alternate, in-frame Tcra, whereas approximately 10% of T cells had 2 productive Tcra transcripts. The proportion of cells with biallelic transcription increased over the course of a response, a finding that has implications for immune memory and autoimmunity. This technique may have broad applications in mouse models of human disease.
Recent advances have allowed us to analyze the development and persistence of virus-specific CD8+ T cell–mediated immunity from naive CTL precursors (CTLps) in peripheral lymphoid tissue, through the antigen-driven phase in lymph nodes and spleen, to the CTL effectors in a site of virus-induced pathology, and then, ultimately, to the persistence and recall of immune memory (1–3). However, unless we use lymphocytes from TCR-transgenic mice, our capacity to follow the fate and persistence of defined clonotypes is very limited. Several approaches have been used to estimate the extent of TCR diversity and to track clonally expanded T cell populations throughout the course of antigen-specific CTL responses (4), but none has given the complete picture. A commonly used protocol is to double-stain CD8+ T cells with mAbs specific for TCR variable (V) region β (TRBV) and tetramers specific for peptide+ class I MHC glycoprotein (pMHCI) epitopes (5–9). Such low-resolution analysis provides no insight into the extent of clonal diversity within a particular TRBV-specific population and offers little scope for determining the spectrum of TCRα usage, as there are few mAb reagents. Another approach, known as immunoscope or spectratyping, uses gel electrophoresis of total mRNA from TRBV-specific populations (RT-PCR product) to determine profiles of complementarity-determining region 3β (CDR3β) length (4, 10). Combining spectratyping with cloning and sequencing allows for more definitive identification of CDR3β transcripts, but the approach is compromised by the possibility of bias during the process of amplification from the RNA pool (10).
Any such skewing effect can be totally avoided by using single-cell RT-PCR of flow cytometer–sorted, epitope-specific CD8+ CTLs to define the spectrum of CDR3β usage within a particular responding T cell population (9, 11–14). This approach has allowed us to determine the spectrum of TRBV recruitment for a range of influenza epitope–specific CD8+ CTL responses within dominant TRBV populations using TRBV-specific primers. A few studies have used primer panels to amplify TRAV, but were not extensively characterized to show total repertoire coverage (15, 16). However, in the absence of any contemporary single-cell analysis of TRAV as well as of an unbiased TRBV method, we have not been able to measure the true extent of clonal diversity for CD8+ CTL effector populations recovered directly from virus-infected individuals (10). The same is true for those analyzing the relative prevalence of T cell clones in diseases like HIV/AIDS (17, 18).
Here, we describe an extension of the single-cell RT-PCR protocol, a technique that allowed for simultaneous identification of CDR3α and CDR3β transcripts from the same responding T cell, without the necessity for any prior knowledge of specific TRAV or TRBV usage. This protocol has wide applications, allowing tracking of endogenous clonotypic responses, complete characterization of the responding paired α/β TCR repertoire, and investigation of TCRα chain regulation during immune activation.
Amplification of CDR3α and CDR3β from single CD8+ T cells. Using a multiplex, nested PCR-based assay, we successfully amplified TCR CDR3α and CDR3β transcripts from epitope (KbPB1703) specific CD8+ T cells (19) isolated directly from the inflamed airways of influenza virus–infected mice (Figure 1, A and B). In general, the success rate of amplification with this method was approximately 45%–65% for CDR3α and 55%–75% for CDR3β. The purified KbPB1703+ TCRα and TCRβ CDR3 PCR products were then sequenced using internal constant chain (C; i.e., TRAC and TRBC) reverse primers, allowing us to pair the coexpressing CDR3α and CDR3β sequences from the same well (Supplemental Table 1; supplemental material available online with this article; doi:10.1172/JCI44752DS1). The fact that we only ever observed 1 CDR3β transcript per well leaves us in no doubt that we are looking at the spectrum of TCR mRNA expression from single, epitope-specific T cells. A representative dataset of TCRα and TCRβ coexpression on KbPB1703+CD8+ CTLs from BAL of a mouse infected with HK×31 influenza A virus (H3N2; referred to herein as ×31) for 10 days is shown in Supplemental Table 1. The TCRα and TCRβ sequences could also be assigned with respective TRAV/TRAJ and TRBV/TRBD/TRBJ families (see Supplemental Table 1) by using an in-house developed BLAST analysis software querying the International ImMunoGeneTics information system (IMGT) database (20). An important caveat is that in certain families of TRAV genes, the closeness of the TRAV internal primer to the CDR3 region results in ambiguous family assignment. As shown in Supplemental Table 1, 4% of the sequences had 2 different TRAV family assignments with more than 99% similarities. In this case, if absolute assignment is needed for receptor expression, performing seminested PCR with the external forward primer can give greater accuracy in calling family names.
Unbiased single-cell amplification of TCR CDR3α and CDR3β. (A) Schematic diagram of the multiplex PCR method used to simultaneously amplify and sequence the TCR CDR3α and CDR3β regions. Following single-cell sorting of KbPB1703+CD8+ T cells into a PCR plate, the first round of PCR used a primer mixture of 23 TRAV and 19 TRBV forward and single TRAC and TRBC reverse primers. Subsequently, a nested PCR was performed for α and β in a separate plate using a corresponding internal primer mix (23 TRAV forward, single TRAC reverse, and 19 TRBV forward, single TRBC reverse, respectively). (B) Schematic representation of the TCR CDR3 region, showing the relative positions of the oligonucleotide primers. An agarose gel electrophoresis image of TCR segments containing CDR3α and CDR3β amplified from single KbPB1703+CD8+ T cells is also shown. L, 100-bp ladder lane. The α and β products were loaded alternately in each twin-lane (separated by vertical lines). Negative control PCR reactions (for contamination) without any cDNA are shown in the boxed region. (C) TRBV usage in the primary KbPB1703+CD8+ T cell response determined by multiplex RT-PCR and sequencing (n = 9 mice). (D) Correlation of the data in C to data acquired by costaining tetramer-specific KbPB1703+CD8+ T cells with a panel of anti-TRBV antibodies.
Validation of multiplex single-cell TCRβ RT-PCR method. Having successfully amplified and sequenced the complementary CDR3α and CDR3β transcripts from individual KbPB1703+ CTLs, we then sought to confirm that the spectrum of TRBV usage determined by this approach is broadly in accordance with the profiles of TRBV protein expression determined by the established mAb staining protocol for tetramer+CD8+ T cells. In addition to the profile of prominent Vβ8.1/8.2 (TRBV13-3/13-2), Vβ10b (TRBV4), Vβ13 (TRBV14), and Vβ14 (TRBV31) usage observed by flow cytometric analysis using a TRBV-specific mAb panel, our CDR3β multiplex RT-PCR TCR transcriptome protocol also showed that Vβ6 (TRBV19) and Vβ1 (TRBV5) figured in this KbPB1703-specific response (Figure 1C), highlighting the greater acuity of this mRNA-based protocol (Supplemental Table 2). Overall, there was good correlation between the profiles of preferred TRBV usage derived from our single-cell multiplex RT-PCR method and the standard, flow cytometry TRBV mAb scan for the KbPB1703-specific response (Figure 1D). The relative lack of mAbs meant that a similar comparison was not possible for the TCRα chain.
Occurrence of peripheral influenza epitope–specific CD8+ T cells with a nonproductive Tcra mRNA. The in vivo analysis focused directly on KbPB1703+CD8+ CTL effectors recovered from the inflamed airways of naive mice that had been infected with the relatively avirulent ×31. Surprisingly, single-cell RT-PCR at the peak of the primary response on day 10 showed the presence of nonproductive or out-of-frame Tcra transcripts in a number of the KbPB1703+CD8+ T cells. Extending this analysis to 650 TCRα sequences from 19 infected mice, the frequency of nonproductive mRNAs in multiple experiments was found to vary from 3% to 52%, with an average of 25% (Figure 2A). Concerned that these transcripts were the sole CDR3α product recovered, we also looked at a second epitope-specific CTL population, the DbPB1-F262 set, with comparable results (Figure 2B). Furthermore, the occurrences of the out-of-frame Tcra transcript–bearing cells in the peak of the primary response appeared to be clonal (Figure 2C). On the other hand, none of the 540 CDR3βs analyzed by this multiplex method for KbPB1703+CD8+ or DbPB1-F262+CD8+ T cells had nonproductive rearrangements (Figure 2, A and B), consistent with other CDR3β profiles analyzed by our research group over a number of years (9, 12–14).
Prevalence of out-of-frame TCRα transcripts in influenza epitope–specific peripheral CD8+ T cells. Single-cell analysis of KbPB1703+CD8+ T cells (A) or DbPB1-F262+CD8+ T cells (B) obtained by BAL (day 10) from infected mice showed that 25% (of the 650 cells analyzed from 19 mice) and 15.6% (of the 192 cells analyzed from 8 mice) of total cells, respectively, expressed an out-of-frame Tcra transcript, whereas all Tcrb transcripts were in-frame. Each dot represents a single mouse. (C) Clonal frequency (25 clones from 14 mice) of individual out-of-frame sequences, with each dot representing a single clone. We considered 2 or more cells with identical CDR3α/CDR3β pairing as clonal. The number of sequences analyzed per mouse is shown. (D) Analysis of KbPB1703+CD8+ T cells from the BAL of Tcra–/+ mice on day 10 after primary infection showed no out-of-frame Tcra sequences. Each dot represents a single mouse.
To rule out that the nonproductive transcripts detected in these single cells reflected some PCR amplification artifact, we repeated the single-cell analysis of CDR3α transcripts for KbPB1703+CD8+ T cells from influenza virus–infected Tcra–/+ hemizygous mice. Although these Tcra–/+ hemizygotes can only generate productively rearranged TCRα chains from 1 chromosome, they are phenotypically and functionally normal (21, 22). As shown in Figure 2D, our conclusion that conventional Tcra+/+ mice indeed express nonproductive transcripts from 1 of the 2 available TCRαs was confirmed by the observation that no such transcripts were detected in 237 sequences from 4 influenza virus–infected Tcra–/+ mice.
Evidence of allelic modulation in influenza-specific peripheral CD8+ T cells. Since all the epitope-specific cells were isolated by KbPB1703 tetramer binding, we assumed that those lymphocytes with nonproductive Tcra transcripts must also express a productive TCRα chain in order to form a functional TCRαβ heterodimer. We used 2 approaches to identify the productive Tcra transcript in out-of-frame cells. The first was a split PCR protocol (23), in which the input cDNA, reverse transcribed from individual cells, was split among 3 wells and amplified separately (Figure 3A). The second protocol depended on cloning and sequencing the original nested PCR product that had a nonproductive transcript (Figure 3B). Using these methods, we were able to capture the expression of 2 Tcra transcripts from single cells expressing a nonproductive transcript, with the second chain representing an in-frame rearrangement. Additionally, T cells that expressed 2 in-frame transcripts (Figure 3C) were found to account for approximately 10% of the tetramer+CD8+ population. These dual–in-frame CTLs have the potential to recognize 2 distinct and non–cross-reactive pMHCI epitopes, making them of considerable interest in light of the much-discussed possibility that virus infections may trigger autoimmunity (24, 25). The percentage of cells that had 2 transcripts (both dual–in-frame and in-frame/out-of-frame), as measured by the split PCR method, was 35%, derived from examination of 3 mice and 240 split reactions (Figure 3C). In addition, a mean of 42% and 23% of total cells were found to express a productive or a nonproductive transcript, respectively (Figure 3C). Again, as these cells were sorted for tetramer binding specificity, we assumed that this latter group must contain an as-yet undetected in-frame rearrangement, making the total percentage of TCRα biallelic cells approximately 60% at this time point (day 10 after infection). Furthermore, when looking within the same individual, we found other cells containing the same productive CDR3α/CDR3β rearrangements, also paired with the same nonproductive CDR3α (Table 1 and data not shown), which indicates that these are the progeny of clonally expanded CTLps. This phenomenon — cells with a particular CDR3β chain but different CDR3α chains representing a clonal population — was found in a different context by Hamrouni et al. (16).
Biallelic expression of TCRα in KbPB1703+CD8+ T cells. (A) Split RT-PCR of single cells shows both mono- (m) and biallelic (b) TCRα expression. The cDNA from a single cell was split 3 ways, and 2 rounds of PCR were used to amplify the CDR3α, as shown by agarose gel electrophoresis (vertical lines separate triplet-lanes). Some cells contained transcript from both alleles, others from a single allele. Most cells with nonproductive transcripts (bold) also had in-frame transcripts. (B) Schematic representation of the PCR sequencing-cloning-sequencing method used to identify the alternate allele. The PCR products (from single cells) that showed either an out-of-frame, in-frame, or unreadable overlap Tcra transcript sequence pairing with the identical CDR3β were cloned using TA cloning, and multiple products were sequenced. (C) The percentage of cells that had 2 transcripts (dual–in-frame and in-frame/out-of-frame) was 35%. In addition, approximately 42% and 23% of all cells analyzed had a monoallelic productive or nonproductive transcript, respectively (data derived from 3 mice and 240 split reactions). Values are mean ± SEM. (D) Comparing nonbiased amplification of TCRα by TRAV primers. Relative frequencies of in-frame and out-of-frame TCRαs paired with the same TCRβ showed that the varying efficiency of amplification was clone specific, rather than TRAV specific (data derived from 78 sequences from 5 mice). (E) KbPB1703+CD8+ T cells were analyzed on days 7, 8, 9, and 10 after primary virus challenge (672 cells from 16 individual mice) for the proportion of the total response represented by out-of-frame cells, showing a significant change (P = 0.0215) between day 7 and day 10.
Identification of the other allele in single KbPB1703+CD8+ T cells
Could the selective amplification of individual TCRα chains in our protocol result from efficiency differences among the TRAV primer families that give the appearance of modulation at the transcript level? Using the data across different mice in which a nonproductive and productive Tcra transcript was associated with a single CDR3β, we tested for a preferential PCR efficiency effect by analyzing the frequency of specific TRAV regions for nonproductive and productive transcripts from these clonotypes. That is, we sought to determine whether particular TRAV regions are consistently amplified over others in cases where transcripts for 2 CDR3αs are found in the same CTLp. The data in Figure 3D (78 T cells from 5 different mice) shows a frequency analysis for situations in which 2 TRAV products were paired with 1 specific CDR3β. The varying frequencies of amplification of these TRAV families across the population indicated that this phenomenon is not some reflection of preferential PCR efficiency for particular TRAV primers. For example, in the clonal cell population where RGTDSAETLY was the CDR3β, the in-frame TRAV3 dominated, while the out-of-frame TRAV7 product was detected at a lower frequency. Conversely, in the clonal population with the GGAESAETLY CDR3β sequence, the exact same 2 TRAV regions were found, but their detection frequency was inverted (Figure 3D). If PCR bias were contributing to this result, we would expect to find the preferred allele consistently; instead, the allelic dominance was cell specific rather than sequence specific (Figure 3D).
Antigen-specific CD8+ T cells with nonproductive TCRα increase over the course of an inflammatory response. The repeated observation of clonal populations in which only one allele was detected by the initial RT-PCR analysis and the split PCR protocol, but both alleles were clearly being expressed, provides strong evidence for transcriptional modulation of allele expression. One hypothesis suggested by this finding is that allelic modulation varies over the course of an inflammatory response. To test this, we used the relative level of out-of-frame cells as a proxy for allelic modulation — as the data in Figure 3, A and B, and Table 1 demonstrated that all out-of-frame cells were by definition dual mRNA expressers. We sorted KbPB1703+CD8+ T cells on days 7, 8, 9, and 10 after infection and determined the percentage of cells expressing an out-of-frame cell TCRα allele. Intriguingly, the frequency of out-of-frame cells increased significantly (P = 0.0215) between days 7 and 10 after infection, as measured for a total of 672 sequences from 16 mice (Figure 3E). The upregulation of the dual TCRα phenotype may have important functional implications for these peripheral effector cells, including generating novel, nonselected specificities under inflammatory conditions or, in the case of nonfunctional gene expression, reducing TCR signaling potential by limiting functional TCR expression.
We report the development of a technique, which we believe to be novel, for amplifying and direct sequencing TCRα and TCRβ chains directly ex vivo from a single cell. The TCRβ repertoire has proved to be an important functional determinant of T cell quality in a number of model systems (10). Additionally, although multiple clonotypic lineages might contain the same TCRβ, the combination of dual TCRα chains paired with a specific TCRβ chain provides a more unique CDR3α/β signature for tracking. This will allow endogenous studies similar to the recently reported barcoding technique, but without the necessity of viral transduction and adoptive transfer (26, 27). Of course, we cannot distinguish between cells derived from a single, peripheral naive progenitor and cells that had undergone homeostatic expansion. Furthermore, although deep sequencing technology has expanded the scope to which α or β CDR3 regions can be sequenced in bulk (28), only a single-cell–based analysis can measure the true repertoire diversity. Given the difficulties previously encountered with analysis of the CDR3α resulting from its broad diversity, this approach represents the first ex vivo analysis to our knowledge of TCRα expression during an antigen-specific response.
The usefulness of this study in generating large numbers of distinct antigen-specific T cell receptors is immediately apparent, as similar technology is now used for specific Ig expression (29). However, the existence of dual–in-frame cells may result in the wrong in-frame TCRα chain being chosen for expression. Still, our results suggest that this phenomenon is present in approximately 10% of antigen-specific cells. Similarly, to obtain the antigen-specific receptor, an out-of-frame result would need to be followed by cloning to obtain the in-frame allele, which we were able to obtain in 100% of tetramer+ cells. The high prevalence of CTLs with nonproductive Tcra transcripts (Figure 2, A and B) was surprising. It is possible that stochastic PCR competition could result in observation of out-of-frame cells without representing transcriptional dominance of the out-of-frame allele. However, we did not find any preferential bias for particular V regions across multiple pairs of coexpressed TCRα alleles, in which the out-of-frame transcript was dominant over the in-frame transcript (Figure 3B). Further, in our split PCR method of determining the repertoire in single cells (Figure 3A), we found cells with a particular in-frame CDR3α (e.g., SANYAQGLTFGLGTRV) in all the split reactions from a single cell, whereas in some cells derived from the same clonal precursor, we found an out-of-frame CDR3α transcript in addition to the expected in-frame CDR3α (e.g., SANYAQGLTFGLGTRV and R*LCPGINLRSWHQSI) in different split reactions. This observation suggests that the detection of any particular TRAV (representing either an out-of-frame or an in-frame transcript) reflects the amount of transcript present and not the result of primer competition.
Allelic exclusion is known to be a relatively inefficient process for TCRα (30–32). In some circumstances, phenotypic exclusion has been reported to efficiently downregulate the nonselected, nonspecific product at the protein level. In Ig and TCRβ chain, a process known as nonsense-mediated mRNA decay (NMD) has been suggested as a control mechanism for limiting the transcription and subsequent translation of these prematurely terminated mRNAs (33–37). Similar mechanisms could also play a role in downmodulating nonproductively rearranged Tcra mRNAs. Indeed, although detection of nonproductive transcripts in CDR3α and CDR3β PCR products from total mRNA of antigen-specific clones has been described previously (31), we failed to detect any nonproductive Tcrb transcript in our single-cell analysis. The detection frequency of nonproductive Tcra transcript only has been previously reported to be very low in a single-cell analysis of immunized mice, although it is possible that the low frequency of CDR3α transcripts reported may be due to the limited set of TRAV primers used in that study (16). In contrast, we recovered multiple CD8+ T cells bearing the same nonproductive Tcra mRNA paired with 1 Tcrb from the infected lungs of 14 of 19 mice (data not shown), indicating that these tetramer+CD8+ CTLs are functioning somewhat normally, at least with respect to clonal expansion in lymphoid tissue and trafficking to a site of inflammatory pathology.
The increase in the prevalence of out-of-frame cells during the course of the primary response was very interesting. This may be a result of conversion from the in-frame antigen-specific cells that were recruited to the immune response to an out-of-frame phenotype by allelic modulation. However, it is also possible that cells with the out-of-frame phenotype are differentially recruited, appearing later in the response. Ongoing experiments are addressing this possibility; however, we found that the degree of tetramer binding did not correlate with out-of-frame expression (our unpublished observations).
In summary, we describe a technique that allows the simultaneous amplification of TCRα and TCRβ chain transcripts from single T lymphocytes recovered directly ex vivo. This protocol, which allows us to track T cell clonotypes throughout an infection, showed a startling level of dual-allele expression for TCRα (but not TCRβ) chains, with dual–in-frame and in-frame/out-of-frame mRNA combinations accounting for approximately 60% of the CTLs recovered from the lungs of mice with influenza pneumonia. Additionally, the fact that T cells with the potential to express 2 functional TCRα chains (dual–in-frame) had passed through thymic selection raises the possibility that clonotypes bearing TCRs that have not been subject to effective negative selection may translate to the periphery, where expression of the second allele is markedly enhanced in response to an inflammatory response. Furthermore, the fact that the incidence of 2-TCR CTLs expands during a virus infection, and that these cells locate to distal, nonlymphoid tissue sites, has implications for the induction of autoimmunity (25, 38–40). This possibility is now under active investigation in our laboratory, as is the further analysis of our finding that these T cells with dual Tcra transcripts did not contribute to long-term memory. If that is indeed the case, the risk of triggering autoimmunity as a consequence of infection may be reduced.
Mice, infection, and reagents. Female C57BL6/J mice were obtained from The Jackson Laboratory at 4–6 weeks of age and maintained in the Animal Resource Center at St. Jude Children’s Research Hospital under an IACUC-approved protocol. The TCR hemizygous (Tcra–/+) mice were generated by crossing the C57BL6/J and B6.129S2-Tcratm1Mom/J (Tcra–/–) strains. Naive (primary) mice were infected intranasally with 106 egg ID50 of ×31. Inflammatory cells were recovered from the lung by bronchoalveolar lavage (BAL) on day 10 after primary infection. Antigen-specific CD8+ T cells were stained with fluorochrome-conjugated tetrameric complexes of the H2Kb MHC class I glycoprotein and the influenza PB1703–711 (SSYRRPVGI) peptide or H2Db plus the PB1-F262–71 (LSLRNPILVF) peptide (obtained from Trudeau Institute). All antibodies were purchased from BD Biosciences — Pharmingen unless otherwise indicated.
Single-cell sorting. After removing the erythrocytes using rbc lysis buffer (8.3 g NH4Cl, 1 g KHCO3, and 1 ml 0.1% Phenol Red in 1 l distilled water), the BAL cells were treated with Fc block (rat anti-mouse CD16/CD32) and then stained using allophycocyanin- or PE-conjugated KbPB1703 tetramer at room temperature for 1 hour, followed by eFluor780- or allophycocyanin-conjugated anti-CD8 antibody (clone 53-6.7, eBiosciences), FITC-conjugated anti-CD4, anti-mouse pan-macrophage marker BM8 (F4/80), anti-mouse CD11c, and anti-mouse CD11b for 20 minutes on ice. The non-CD8+ T cells were excluded using a dump gate based on CD4, F4/80, CD11c, and CD11b staining. In some experiments, the KbPB1703+CD8+ T cells were also stained using a panel of TRBV-specific antibodies (12, 13). The tetramer+CD8+ T cells were suspended in buffer (PBS containing 2% BSA and 200 U RNAsin/ml, Promega) and deposited as single cells into the wells of a 96-well PCR plate (Biorad) using a MoFlo flow cytometer (Cytomation) fitted with a Cyclone single-cell deposition unit. The last 2 columns of the plate were left blank for negative controls. After sorting, the plates were sealed using adhesive films and frozen at –80°C prior to RT-PCR. The staining profile and gating strategy is shown in Supplemental Figure 1.
Design of oligonucleotide primers for CDR3α and CDR3β amplification. A nested, single-cell, multiplex PCR approach was used to amplify the CDR3α and CDR3β TCR regions from individual T cells. Known functional and open reading frame nucleotide sequences of the TCRα and TCRβ families were retrieved from the IMGT database (http://www.imgt.org; ref. 20). For the TCRα chain, there were 82 different functional and open reading frame TRAV sequences. These sequences were grouped in a phylogenetic tree, and the forward oligonucleotide primers (both external and internal) were designed (Supplemental Table 3) to amplify closely related TRAV sequences. When a consensus region could not be found, degenerate bases were used in the primer design to amplify these groups. In contrast, the TRBV families were substantially less diverse. Therefore, the TRBV-specific forward oligonucleotide primers (both external and internal) were designed to amplify individual V regions, except in the case of multisequence families like TRBV12 and TRBV13 where a single oligonucleotide was designed to amplify all family members (Supplemental Table 4). In total there were 23 TRAV and 19 TRBV forward primers each for external and internal rounds of PCR. The antisense oligonucleotides primers (both external and internal) for TCRα and TCRβ were designed from TRAC and TRBC sequences, respectively. All oligonucleotide primers were synthesized at the Hartwell Centre of St. Jude Children’s Research Hospital and validated using cDNA as template from total RNA isolated from resting CD8+ T cells (Supplemental Figure 2). The positions of the primers are shown in Figure 1B.
Single-cell RT-PCR, sequencing, and cloning. cDNA synthesis was performed directly from single cells using the iScript cDNA Synthesis Kit (Bio-Rad) per the manufacturer’s instructions, with minor modifications. The cDNA synthesis used 2.5 μl of reaction mix consisting of 0.5 μl 5× iScript reaction mix, 0.5 μl iScript reverse transcriptase, and 0.1% Triton X-100 (Sigma-Aldrich), with the remainder H2O. This was incubated at 25°C for 5 minutes, 42°C for 30 minutes, and 85°C for 5 minutes. Following RT, a multiplex nested PCR was done with a Taq polymerase–based PCR kit (Qiagen) to amplify the CDR3α and CDR3β transcripts from each cell in a 25-μl reaction mix containing 2.5 μl cDNA. The first round of PCR was performed with 2.5 μl of 10× PCR buffer containing 15 mM MgCl2, 0.5 μl 10 mM dNTP, 0.75 U Taq DNA polymerase, and 0.5 μl oligonucleotide mixture of 23 TRAV forward and single TRAC reverse along with 19 TRBV forward and single TRBC reverse oligonucleotides (each 5 μM final concentration; Supplemental Tables 3 and 4). When cells were sorted with a particular TRBV antibody, the primers (both sense and antisense, 5 μM each) used were specific for that family. A second round of nested PCR was then performed for CDR3α and CDR3β using product from the first PCR round as template and a similar primer mixture for the TRAV and TRBV internal primers. For the split PCR protocol, the cDNA from a single cell was diluted to 10 μl using water and then divided into 3 wells. The first- and second-round PCR was then done as described above. The PCR conditions were 95°C for 5 minutes followed by 34 cycles of 95°C for 20 seconds, 56°C for 20 seconds, and 72°C for 45 seconds, with a final extension at 72°C for 7 minutes. A schematic of the PCR strategy is shown in Figure 1A. The PCR products were visualized on a 2% agarose gel, then purified using a Wizard SV40 PCR purification kit (Promega) and sequenced using TRAC or TRBC reverse primers for α and β PCR products, respectively, using a ABI Big Dye sequencer (Applied Biosystem) at the Hartwell Centre of St. Jude Children’s Research Hospital.
For the PCR cloning studies (see Figure 3B), cells with nonproductive transcripts were identified from the sequence analysis by their well number. The corresponding, purified PCR products were then cloned into a TOPO TA cloning vector (Invitrogen). Individual clones were picked, and colony PCR was performed using M13 forward and reverse primers. The PCR products were then purified as before and sequenced using TRAC reverse primers.
TRBV antibody scan. Cells isolated from the BAL of infected mice were stained with allophycocyanin- or PE-conjugated KbPB1703 tetramer, eFluor780- or allophycocyanin- conjugated anti-CD8 antibody (clone 53-6.7, eBiosciences), and a panel of FITC-conjugated anti-TRBV antibodies (Vβ2, clone B20.6; Vβ3, clone KJ25; Vβ4, clone KT4; Vβ5.1/5.2, clone MR9-4; Vβ6, clone RR4-7; Vβ7, clone TR310; Vβ8.1/8.2, clone MR5-2; Vβ8.3, clone 1B3.3; Vβ9, clone MR10-2; Vβ10b, clone B21.5; Vβ11, clone RR3-15; Vβ12, clone MR11-1; Vβ13, clone 12-3; Vβ14, clone 14-2; Vβ17a, clone KJ23; all from BD Biosciences — Pharmingen). The TRBV usage frequencies were then determined by flow cytometry.
Data analysis. The sequence data for CDR3α and CDR3β were analyzed using Chromas (Technelysium Pty Ltd.) and MegAlign Software (DNASTAR Lasergene) and processed using an Excel spreadsheet containing macros (from http://www.bioc.uzh.ch/antibody) that parse the nucleotide sequences and convert them to amino acid sequences (41). The results were tabulated in the same spreadsheet for paired coexpression analysis. The TRAV/TRAJ and TRBV/TRBD/TRBJ assignments were obtained using an in-house Web application written in PHP 5 and MySQL 5. The TCR Web application allows users to upload FASTA files individually or in zipped archives and queries them against the IMGT T-Cell Receptor online database using PHP cUrl. The HTML returned from the IMGT Web site query is parsed using regular expressions to locate key features in the text. A table is printed at the top of the IMGT HTML results that allows the quick recognition of the overall results of the user query, such as whether the query succeeded, which receptor family names were found, and an amino acid translation of the receptor. More specific information, such as the nucleotide sequence of the translation, is found further down in Results.
Several checks were in place in order to prevent erroneous reporting of null sequence results (false negatives). Additionally, we found that uploading sequences bounded by many unknown nucleotides (Ns) frequently generated false negatives or incorrect receptor family names. To avoid this, the TCR database truncated the number of Ns on either side of an uploaded sequence to 5, 6, or 7 Ns in such a way as to preserve the reading frame. False positives were easily prevented by the fact that IMGT does not display the receptor names if none are found, and the sections that contain the results of true positives are not displayed for genuine null sequences.
Statistics. Nonparametric Kruskal-Wallis ANOVA was used with Dunn post-test to determine individual significance (Figure 3E). All calculations were done using GraphPad software. A P value less than 0.05 was considered significant.
Funding was provided by NIH grants AI70251 (to P.C. Doherty) and AI077714 (to P.G. Thomas), U.S. Department of Health and Human Services contract no. HHSN266200700005C, and the American Syrian Lebanese Associated Charities (ALSAC).
Address correspondence to: Paul G. Thomas, Department of Immunology, St. Jude Children’s Research Hospital, 262 Danny Thomas Place/MS 351, Memphis, Tennessee 38105-3678, USA. Phone: 901.595.6507; Fax: 901.595.3107; E-mail: paul.thomas@stjude.org.
Conflict of interest: The authors have declared that no conflict of interest exists.
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