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Human TCR That Incorporate CD3 Induce Highly Preferred Pairing between TCR and β Chains following Gene Transfer¹

Zsolt Sebestyén^*, Erik Schooten^*, Tamara Sals^*, Irene Zaldivar, Esther San José, Balbino Alarcón, Sara Bobisse, Antonio Rosato, János Szöllsi, Jan Willem Gratama^*, Ralph A. Willemsen^* and Reno Debets^2,*

^* Unit Clinical and Tumor Immunology, Department of Medical Oncology, Erasmus Medical Center–Daniel den Hoed Cancer Center, Rotterdam, The Netherlands; Consejo Superior de Investigaciones Cientificas–Universidad Autónoma de Madrid, Madrid, Spain; Department of Oncology and Surgical Sciences, University of Padova and Instituto Oncologico Veneto, Padova, Italy; and Department of Biophysics and Cell Biology, Research Center for Molecular Biology, University of Debrecen, Debrecen, Hungary

	Abstract

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TCR gene therapy is adversely affected by newly formed TCRβ heterodimers comprising exogenous and endogenous TCR chains that dilute expression of transgenic TCRβ dimers and are potentially self-reactive. We have addressed TCR mispairing by using a modified two-chain TCR that encompasses total human CD3 with specificities for three different Ags. Transfer of either TCR:CD3 or β:CD3 genes alone does not result in surface expression, whereas transfer of both modified TCR chains results in high surface expression, binding of peptide-MHC complexes and Ag-specific T cell functions. Genetic introduction of TCRβ: does not compromise surface expression and functions of an endogenous TCRβ. Flow cytometry fluorescence resonance energy transfer and biochemical analyses demonstrate that TCRβ:CD3 is the first strategy that results in highly preferred pairing between CD3-modified TCR and β chains as well as absence of TCR mispairing between TCR:CD3 and nonmodified TCR chains. Intracellular assembly and surface expression of TCR:CD3 chains is independent of endogenous CD3, , and . Taken together, our data support the use of TCRβ:CD3 to prevent TCR mispairing, which may provide an adequate strategy to enhance efficacy and safety of TCR gene transfer.

	Introduction

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Adoptive transfer of Ag-specific T lymphocytes has recently shown clinical success in the treatment of viral infections and tumors (1, 2, 3, 4). We and others have demonstrated that transfer of TCRβ genes into T cells (i.e., genetic T cell retargeting) represents a feasible and attractive alternative to provide tumor-specific immunity (5, 6, 7, 8, 9), and at the same time circumvents the laborious nature and limited success of isolating and expanding tumor-reactive T cells from patients ex vivo. Currently, gene transduction and T cell expansion procedures have been optimized (10), meet good clinical practice criteria, and are implemented in various phase I trials using patient-derived autologous T cells gene-modified with Ab-based receptors (11, 12). More recently, TCR gene therapy to treat metastatic melanoma patients has been pursued, showing that TCR gene transfer is a safe strategy but appears limited by an objective response rate of 12% (13).

One way to enhance the efficacy of TCR gene therapy is to improve the avidity of TCR-transduced T cells, which is often compromised when compared with parental CTL clones. It has been observed that high-avidity CTL provide better protection against viral infections because target cells are recognized at lower Ag densities and initiate lysis more rapidly when compared with low-avidity CTL (14). T cell avidity can be improved significantly by selecting TCR chains with appropriate ligand-binding affinity (15), the use of optimal retroviral transfer vectors and strategies that address gene silencing in vivo (16, 17). In addition, T cell avidity would benefit from enhanced surface expression levels of TCR transgenes (7, 18). In fact, introduced TCR and β transgenes can assemble with endogenously present TCR chains (i.e., TCR mispairing) and thereby dilute the surface expression level of TCR transgenes (9). Consequently, TCR mispairing impairs the avidity of the transduced T cell population toward the target Ag of interest due to a reduction in the density of the desired TCRβ on the cell surface and may result in compromised T cell activation (19) and efficient tumor killing (7, 18). Furthermore, mispairing of TCR chains may result in possible formations of self-reactive TCRβ heterodimers and as such adversely affects the safety of treatments with TCR-transduced T lymphocytes.

To date, various strategies have been reported that have attempted to address TCR mispairing, such as introduction of cysteine residues at structurally favorable positions in TCR-C and β (20) and replacement of human TCR constant domains by the corresponding murine domains (i.e., huV:muC) (21). Pairing between TCR chains modified by either one of these strategies is at best preferential to some extent for certain TCR-V regions, most likely due to stabilized TCR/CD3 conformations (20, 21), whereas it is not preferential for other TCR-V regions when compared with nonmodified TCR (22). We have previously reported on modified TCR and β chains in which the original constant domains downstream of the extracellular cysteine (which mediates the interchain disulphide bridge) have been replaced with complete human CD3 (i.e., TCRβ:CD3), and provided flow cytometry data suggesting an inability of the modified TCR chains to mispair with the endogenous TCR chain and correct pairing of these TCR chains in primary human T cells (6). In the current study, we have not only extended this observation to three sets of TCRs, but more importantly provided novel and direct evidence of a highly preferred pairing between TCR: and β: chains using fluorescence resonance energy transfer (FRET)³ flow cytometry supplemented with classical flow cytometry, biochemistry, and functional analyses. The TCRβ:CD3 format does not compete with endogenous TCRβ chains for available CD3 elements, and when compared with nonmodified TCRβ transgenes, shows high surface expression on T cells, potently mediates intracellular signaling, and does not compromise surface expression and signaling of an already present TCRβ. Importantly, surface expression and function of TCRβ:CD3 have been extensively validated in primary human T cells and this receptor format functionally retargets T cells toward tumor cells positive for various MHC-restricted tumor and viral Ags (6, 22, 23).

	Materials and Methods

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Cells and reagents

Jurkat T cells and the B cell blast cell lines BSM and APD were cultured in RPMI 1640 medium containing 10% FBS (Stonehouse), streptomycin (100 µg/ml), and penicillin (100 U/ml). The human embryonic kidney cell line 293T, the packaging cell line Phoenix-A as well as the MAGE-A1⁺/HLA-A1⁺ melanoma cell line MZ2-MEL.3.0 (provided by Drs. T. Boon and P. Coulie, Christian de Duve Institute of Cellular Pathology, Université catholique de Louvain, Brussels, Belgium) were cultured in DMEM medium (BioWhittaker) supplemented with 10% FBS, 2 mM L-glutamine, and antibiotics. T lymphocytes derived from healthy donors were isolated and expanded as described elsewhere (23). mAbs used for flow cytometry and FACSort comprise nonconjugated and FITC-conjugated anti-TCR V19 mAb (Pierce Biotechnology); FITC-conjugated anti-TCR Vβ27 (Coulter-Immunotech); and PE-conjugated anti-TCR Vβ9, Vβ12, Vβ27, and Vβ2 mAbs (Coulter-Immunotech). Abs used for immune precipitation (IP) and immune detection include anti-TCR Vβ9 mAb (BL37.2; Coulter-Immunotech), anti-CD3 mAb (HMT-3.2) (24), anti-CD3 mAb (APA-1.2) (24), two anti-CD3 mAbs (OKT3, Sanquin; and M-20, Santa Cruz Biotechnology), anti-CD3 mAb (488) (25), and HRP-conjugated sheep anti-mouse or donkey anti-goat IgG (Amersham Biosciences). Other reagents used in this study were: RetroNectin (human fibronectin fragments CH-296; Takara Shuzo), hgp100_280–288 (YLEPGPVTA)/HLA-A*0201, MAGE-1 (EADPTGHSY)/HLA-A*0101, EBNA-4 (IVTDFSVIK)/HLA-A*1101, and Melan-A (ELAGIGILTV)/HLA-A*0201 pentamers (all obtained from Proimmune); PMA (Sigma-Aldrich); and ionomycin (Calbiochem).

Construction of lentiviral vectors containing MelA/A2 TCRβ genes

MelanA/MART1-specific and HLA-A2-restricted TCRβ (MelA/A2 TCR) cDNA was derived from the MelA peptide-specific CTL clone SELA-A 64 (26), and sequence characterization identified TRAV12-2/J35/C and TRBV27/D2/J2-7/C2 gene usage. The MelA peptide-specific CTL clone SELA-A 64 was treated with TRIzol (Invitrogen) for total RNA isolation, which was converted to cDNA by reverse transcription using oligo-dT primer and Moloney murine leukemia virus reagent (Invitrogen). Full-length TCRβ-encoding genes were PCR amplified, inserted into pCR2.1 TOPO vectors (Invitrogen), and sequenced. Complete TCR and β sequences were cloned between XbaI and SalI sites of a self-inactivating HIV-1-based vector (pRRL.sin18.cPPT.CMV.GFP.Wpre, abbreviated as CMV.GFP and described in more detail elsewhere (27)), obtaining CMV.TCR and CMV.TCRβ, respectively. The lentiviral packaging plasmid pCMVR8.74 (28), devoid of all HIV-1 accessory genes, and the plasmid hCMV-G (29) were used to produce TCR-containing and VSV-G envelope-pseudotyped lentiviruses following calcium-phosphate transfection of 293T cells. The virus-containing supernatants were filtered through 0.45-µm filters, concentrated 30-fold by centrifugation at 104,000 x g for 2 h at 4°C and resuspended in DMEM. Viral particle concentrations were measured by HIV-1 p24 protein ELISA (Innogenetics) and ranged from 0.5–3 µg of p24/ml, which was equivalent to 0.5–1 x 10⁵ therapeutic use/ng p24.

MelA/A2 TCRβ gene transfer and cloning of TCR-expressing Jurkat T cells

Lentiviral TCR gene transfer into TCR-negative Jurkat T cells was performed by mixing 2 x 10⁵ cells with 1 ml of concentrated viral supernatant in the presence of 8 µg/ml protamine sulfate (Sigma-Aldrich). Nontransduced T cells (mock) were used as a negative control. T cells were transduced in a first 6-h cycle with pCMV-TCR containing viral supernatant, washed, and transduced in a second 6-h cycle with pCMV-TCRβ (both cycles at 37°C/5% CO₂). Cells were allowed to recover in fresh culture medium. Seventy-two hours following transduction, T cells were plated and cultured under limiting dilution conditions in 96-well microtiter plates. T cell clones were screened for TCR expression by flow cytometry, and clone J.19 was selected and expanded based on high peptide-MHC (pMHC) binding (99% tetramer-positive T cells). Stability of TCR expression (pMHC binding) and function (TCR-dependent Ca²⁺ signaling) was confirmed over the period this clone was used for the experiments described (>12 mo).

Cloning of TCRβ and TCRβ: genes and retroviral TCR gene transfer into Jurkat T cells

TCR and β DNAs were obtained by PCR using template cDNA from the CTL clones MZ2-82/30 (specificity: MAGE-A1/HLA-A1; TCR gene usage: TRAV19/J39/C and TRBV9/D2/J2-3/C2), MPD (specificity: gp100/HLA-A2; TCR gene usage: TRAV30/J49/C and TRBV12-4/D2/J2-1/C2), and BK289 (specificity: EBNA-4/HLA-A11; TCR gene usage: TRAV8-1/J45/C and TRBV2/D2/J2-1/C2) (6, 9, 30). TCR-V(D)J gene nomenclature is according to http://imgt.cines.fr. TCRβ: specific for MAGE-A1, gp100, and EBNA-4 were constructed by linking the extracellular domains of the TCR and β chain to the complete human CD3 molecule (i.e., VC and VβCβ) as described previously (6, 31, 32). TCRβ and TCRβ: cDNAs were cloned into pBullet retroviral vectors, and used to transduce either TCR-negative or MelA/A2 TCR-positive Jurkat T cells (i.e., clone J.19). VSV-G envelope-pseudotyped Moloney murine leukemia virus retroviruses that contain TCR RNAs were produced by a coculture of the packaging cells 293T and Phoenix-A following calcium-phosphate transfections. The transduction procedure used was optimized for human T cells and described by Lamers et al. (10). In short, 24-well culture plates were coated with RetroNectin and pretreated with TCR-positive retroviral particles. Next, 10⁶ T cells/well were centrifuged in fresh retrovirus containing supernatant, and cultured for 4–5 h at 37°C/5% CO₂. Cells were allowed to recover in culture medium overnight before a second transduction cycle, after which cells were harvested and transferred to T25 culture flasks. After sufficient numbers were obtained, cells were analyzed for TCR expression by flow cytometry.

Flow cytometry and enrichment of TCR-transduced Jurkat T cells

TCR-transduced Jurkat T cells (5 x 10⁵) were analyzed for transgene expression by flow cytometry using FITC-conjugated anti-TCR mAb (V19 or Vβ27), PE-conjugated anti-TCR mAb (Vβ2, Vβ9, Vβ12, or Vβ27) or R-PE-conjugated pMHC multimers (M1/A1, gp100/A2, EBNA-4/A11, or MelA/A2). Cells were incubated with mAbs on ice for 30 min, or pMHC multimers at room temperature for 15 min. Analysis was performed on a Cytomics FC-500 flow cytometer (Beckman Coulter). Enrichment of Jurkat T cells expressing M1/A1 TCRβ or TCRβ: in the presence or absence of MelA-A2 TCRβ was performed by two-color FACS following staining with anti-TCR-V19 and Vβ9 mAbs.

Flow cytometry-based FRET

Flow cytometry-based FRET is performed principally as described previously (33), and fluorophores were selected on the basis of optical properties of the dyes and the available excitation wavelengths of the flow cytometer (34). mAb were directly labeled with Cy3- and Cy5-monoreactive sulfoindocyanine N-hydroxysuccinimidyl ester-conjugated dyes (Amersham Biosciences) according to the manufacturer's specifications. Dye-to-protein labeling efficiencies were determined spectrophotometrically and ratios of 3:1 were considered appropriate for FRET applications. In brief, FRET was performed as follows. Cell samples were stained either with 1) anti-TCR-V19 mAb followed by Cy5-conjugated goat-anti-mouse IgG Fab (acceptor) and Cy3-conjugated anti-TCR-Vβ9 mAb (donor); 2) anti-TCR-V19 mAb followed by Cy3-conjugated goat-anti-mouse IgG Fab (donor) and Cy5-conjugated anti-TCR-Vβ9 mAb (acceptor); 3) anti-TCR-V19 mAb followed by Cy5-conjugated goat-anti-mouse IgG Fab (acceptor) and PE-conjugated anti-TCR-Vβ27 mAb (donor); or 4) Cy5-conjugated anti-CD3 mAb (acceptor) and Cy3-conjugated anti-TCR-Vβ9 (donor). Fluorescence intensities were subsequently measured on a FACSCalibur dual-laser flow cytometer (BD Biosciences). Emissions at 570 nm (donor channel, excitation at 488 nm), 670 nm (acceptor channel, excitation at 635 nm), and over 670 nm (FRET channel, excitation at 488 nm) were collected. Data were analyzed with the FLEX software on a per cell basis (35).

IP and Western blotting

TCR-transduced Jurkat T cells (25 x 10⁶) were lysed in 10 mM Tris-Cl (pH 7.6), 150 mM NaCl, 2 mM EDTA, and 0.5% Brij96 (Sigma-Aldrich) for 30 min on ice in the presence of protease inhibitors (protease inhibitor mixture Complete; Roche Applied Science). Cleared lysates were immune precipitated either with anti-TCR-Vβ9, anti-CD3 (HMT-3.2), anti-CD3 (APA-1.2), anti-CD3 (OKT-3) or anti-CD3 (488) Abs overnight at 4°C followed by protein G Sepharose coated with rabbit-anti-mouse IgG for 1 h at 4°C. The immune precipitates were washed, loaded, and run on 7–17% Tris-HCl gels, and transferred to nitrocellulose membranes (Whatman) under wet conditions. The membranes were subsequently used for immune detection with anti-CD3 (M20) or anti-CD3 (488) Abs for 3 h at room temperature, followed by peroxidase-labeled sheep anti-mouse or donkey anti-goat IgG (1:2,500; Amersham Bioscience) for 30 min at room temperature and developed via chemiluminescence (SuperSignal West Pico Chemiluminescent Substrate; Pierce).

NFAT reporter gene assay

For reporter gene assays, exponentially growing Jurkat T cells were transiently transfected by nucleofection with an Amaxa nucleofector (Amaxa Biosystems) according to the manufacturer's instructions. A total of 5 x 10⁶ cells were resuspended in 100 µl of buffer V (Amaxa Biosystems), after which 10 µg of an NFAT-luciferase construct (containing six NFAT-binding sites followed by a minimal IL-2 promoter and TATA box, synthesized by Base Clear) and 1 µg of the β-galactosidase construct was added and cells were pulsed with the Nucleofector set at S-10. After transfection, the cells were immediately put into 2 ml of fresh culture medium in wells of 12-well plates and incubated at 37°C/5% CO₂. Twenty hours posttransfection, Jurkat T cells were transferred to round-bottom 96-well plates (Costar) at 2 x 10⁵ cells in 200 µl/well and were stimulated with anti-TCR Vβ mAbs in RPMI 1640 medium supplemented with 10% BCS for 6 h at 37°C/5% CO₂. Wells were precoated with anti-TCRVβ9 mAb, anti-TCRVβ27 mAb, or control murine Ig (at 0.1 µg/well final), and stimulations with PMA (10 ng/ml) and ionomycin (1 µM) served as positive controls. After stimulation, T cells were collected, lysed with cell lysis buffer (Promega), and luciferase and β-galactosidase activities were assessed using chemiluminescent substrates according to the manufacturer's instructions (Mediators). Samples were analyzed in a 96-well plate luminometer (Mediators), and luciferase activities were normalized on the basis of β-galactosidase activities and expressed (in relative light units (RLU)) relative to nonstimulated conditions (medium only: set to 1.0).

Cytotoxicity assays

Cytolytic activity of human T lymphocytes was measured in 4-h ⁵¹Cr-release assays as described previously (36). Percentage-specific ⁵¹Cr release was calculated as follows: ((test counts – spontaneous counts)/(maximum counts – spontaneous counts)) x 100%.

	Results

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
TCRβ:CD3 does not pair with TCRβ and shows enhanced surface expression on T cells when compared with nonmodified TCRβ

To examine TCR mispairing and study how gene transfer of TCRβ or TCR β:CD3 affects the surface expression and function of an existing TCRβ, we generated a dual TCR Jurkat T cell model. This model is schematically presented in Fig. 1, and is based on a Jurkat T clone expressing Melan-A/HLA-A2 TCRβ (MelA/A2 TCR) as a first TCR and acting as a recipient T cell for gene transfer of MAGE1/HLA-A1-specific TCRβ or TCRβ:CD3 (M1/A1 TCRβ or TCRβ:) as a second TCR. In a first experiment, we confirmed surface expression of M1/A1 TCR19 or β9 chains in MelA/A2 TCR-positive Jurkat T cells following genetic introduction of either a TCR or β chain as a measure of TCR mispairing (Fig. 2A and Table I). Surface expression of M1/A1 TCR19 or β9 chains can only result from mispaired TCR heterodimers constituting MelA/A2 TCR and M1/A1 TCRβ or vice versa. Consequently, the introduction of M1/A1 TCRβ9 limits the surface expression level of MelA/A2 TCRβ27 as a result of competition between the two TCRβ chains for the only available MelA/A2 TCR12 chain (Fig. 2A and Table I). In fact, a decreased surface expression of the first TCRβ upon TCRβ gene transfer may represent an indirect measurement (i.e., a surrogate marker) of TCR mispairing. Note that the validity of this assay was confirmed by FRET analyses which show that in the context of dual TCR T cells the TCRβ27 truly mispairs with the introduced TCR chain (see Fig. 5C). Strikingly, genetic introduction of only TCR: or β: neither result in surface expression of the M1/A1 TCR19: or β9: chain nor in a decreased expression level of MelA/A2 TCRβ27 chain (Fig. 2B and Table I). Interestingly, T cells transduced with TCR: and β: show a unique and extended diagonal dot plot when stained with the corresponding anti-TCR-V19 and Vβ9 Abs, indicative of coordinated expression of both TCR chains and most likely contributing to enhanced surface expression of TCRβ: (Fig. 2B). Mean fluorescence intensities (MFI) of anti-TCR V19 mAb^FITC and Vβ9 mAb^PE stainings of T cells gene-transferred with either TCRβ- or TCRβ:-expressing dual TCR T cells support this conclusion (Table I). In addition, gene transfer of TCR: and β: does not compromise the surface expression of the already present TCRβ and results in T cells coexpressing both TCRs. Percentages and MFIs of MelA/A2 TCRβ-positive T cells were reduced almost 2-fold when gene-transferring M1/A1 TCRβ (percent of TCRβ27-positive T cells changed from 94 to 49 and MFI from 5.6 to 1.7) but were nonaffected when gene-transferring M1/A1 TCRβ: (percent changed from 94 to 92 and MFI from 5.6 to 5.3). Double immunofluorescent stainings with pMHC multimers and anti-TCR or β Abs extended these observations and showed little surface coexpression (up to 20%) of noncorresponding M1/A1 and MelA/A2 TCR chains in TCRβ-transduced T cells. In contrast, there was clear coexpression (up to 80%) of these TCR chains in TCRβ:-transduced T cells (Fig. 3: percentages correspond to fraction of M1/A1 TCR-positive T cells (set to 100% and highlighted by black rectangles) that coexpress MelA/A2 TCR).

View larger version (24K): [in this window] [in a new window]   FIGURE 1. Scheme of Jurkat dual TCR model. To what extent TCR mispairing is addressed successfully by TCRβ: was tested in dual TCR T cells, representing the end-products of TCR gene transfer. To this end, a Jurkat T cell clone expressing MelanA/HLA-A2 (MelA/A2) TCR12β27 as a first TCR was gene transferred with TCR19 plus β9 or TCR19: plus β9: as a second TCR. Second TCRs were specific for either MAGE-A1/HLA-A1 (M1/A1 as indicated in figure), gp100/HLA-A2, or EBNA4/HLA-A11.

View larger version (41K): [in this window] [in a new window]   FIGURE 2. M1/A1 TCRβ: does not mispair with MelA/A2 TCRβ and shows high surface expression on T cells. A, Jurkat T cells expressing MelA/A2 TCR12β27 were transduced with a second M1/A1 TCR19β9, or their individual TCR19 or TCRβ9 chains. The TCR transductants were monitored for expression of introduced M1/A1 TCRβ using flow cytometry with anti-TCR19 and Vβ9 mAbs (upper panel, second TCR). The expression of MelA/A2 TCRβ was monitored using anti-TCRVβ27 mAb (lower panel, first TCR). Filled gray histograms correspond to background fluorescence of T cells stained with isotope control Ab. B, Jurkat T cells expressing MelA/A2 TCRβ were transduced as described in A but now using M1/A1-specific TCR19β9: chains. Flow cytometry was performed as described in A. Please note that flow cytometry settings did neither allow for full compensation of autofluorescence (high for the TCRneg Jurkat T cells clone used in the study) nor for "bleedover" from one channel to another, especially evident from FL2 to FL1 channels (due to enhanced sensitivity of PE-labeled over FITC-labeled Abs). Background signals never exceed 5% of the total T cell population. Data represent one of four independent experiments with similar results.

View this table: [in this window] [in a new window]   Table I. Surface expression of endogenous and exogenous TCR chains on Jurkat T cells following gene transfer of M1/A1 TCR, β, or TCR:, β:a

View larger version (19K): [in this window] [in a new window]   FIGURE 5. Highly preferred pairing between TCR: and β: but not TCR and β in dual TCR T cells. Jurkat T cells expressing either M1/A1 TCRβ or TCRβ: in the absence or presence of MelA/A2 TCRβ (i.e., single and double TCR T cells, respectively), previously enriched by FACS with anti-TCR V19 and Vβ9 mAbs (specific for M1/A1 TCR), were stained with donor- and acceptor-conjugated anti-TCR and β mAbs and analyzed for FRET efficiency using a FACSCalibur dual-laser flow cytometer as described in Materials and Methods. As a measure of correct TCR pairing T cells were stained either with (A) Cy5-labeled anti-TCR V19 and Cy3-labeled anti-TCR Vβ9 mAbs, or (B) Cy3-labeled anti-TCR V19 and Cy5-labeled anti-TCR Vβ9 mAbs, whereas as a measure of TCR mispairing T cells were stained with (C) Cy5-labeled anti-TCR V19 and PE-labeled anti-TCR Vβ27 mAbs. Please note that FRET measurements between M1/A1 and MelA/A2 TCR chains were limited to donor-labeled TCRβ and acceptor-labeled TCR chain due to lack of Cy5 (donor) labeled TCR-Vβ27 Ab. Also, single M1/A1 TCR T cells (not transduced with MelA/A2 TCR) were not exposed to FRET measurements with Cy5-labeled anti-TCR V19 and PE-labeled anti-TCR Vβ27 mAbs. TCR was stained indirectly, whereas TCRβ was stained directly (see Materials and Methods for details). The bars represent mean FRET values ± SEM of three independent measurements. *, A statistically significant difference between TCRβ: and TCRβ based on Student's t test (p < 0.01).

View larger version (43K): [in this window] [in a new window]   FIGURE 3. TCRβ:, but not TCRβ, coexpresses with TCRβ in dual TCR T cells. Jurkat T cells expressing MelA/A2 TCRβ (i.e., TCR12β27) were transduced with a second M1/A1 TCRβ or TCRβ: (i.e., TCR19β9) after which T cells were enriched by FACS using anti-TCR-V19 and TCRVβ9 mAbs and analyzed for coexpression of MelA/A2 and M1/A1 TCR using flow cytometry. Double immunostainings of T cells were performed either with FITC-labeled anti-TCRβ27 mAb and PE-labeled M1/A1 multimers (upper panel) or FITC-labeled anti-TCR19 mAb and PE-labeled Mel/A2 multimers (lower panel). Numbers indicate either percentage of M1/A1 multimer-positive T cells (set to 100%, highlighted by a black rectangle) that costain with anti-TCR-Vβ27 mAb (upper panel) or percentage of anti-TCR-V19 mAb-positive T cells (set to 100%, highlighted by a black rectangle) that costain with MelA/A2 multimer (lower panel). Data represent one of two independent experiments with similar results.

View larger version (17K): [in this window] [in a new window]   FIGURE 4. TCRβ: chains do not mispair with TCRβ chains, irrespective of Ag specificity. MelA/A2-TCR Jurkat T cells were transduced with TCRβ or TCRβ: specific for either M1/A1, gp100/A2, or EBNA4/A11 Ags, and the level of surface expression of the MelA/A2 TCR was monitored with flow cytometry using either (A) anti-TCR-Vβ27 mAbPE or (B) MelA/A2-multimerPE. The bars represent the percent of positive cells and show mean ± SEM of three independent measurements. *, A statistically significant decrease compared with the Jurkat T cells expressing MelA/A2-TCR only (single TCR T cells, first bar) based on Student's t test (p < 0.05).

View this table: [in this window] [in a new window]   Table II. Surface expression of endogenous and exogenous TCR on Jurkat T cells following gene transfer of TCRβ or TCRβ:a

Highly preferred pairing between TCR: and β: but not TCR and β in dual TCR T cells

To extend our flow cytometry data and provide direct evidence that TCR: and β: transgenes pair correctly, we used flow cytometry-based FRET as a measure of molecular distance (i.e., extent of TCR pairing) between TCR and β chains. MelA/A2 TCRβ-positive Jurkat T cells were transduced with M1/A1 TCRβ or β: and were labeled with donor and acceptor conjugated Abs that corresponded either to correctly paired TCR transgenes (i.e., TCR-V19 and Vβ9 mAbs) or mispaired TCR transgenes (i.e., TCR-V19 and Vβ27 mAbs). It is important to note that FRET efficiencies >5% represent a significant association between the TCR chains under study, in case their surface expression levels are in a normal range (5 x 10⁴–5 x 10⁵ molecules per cell) and the applied fluorophores express average brightness. FRET efficiencies <5%, although not implying that there is no pairing of TCR chains, do not allow distinction between significant and nonsignificant interactions due to energy transfer by chance and experimental error (34, 37, 38). FRET values of Jurkat T cells expressing only M1/A1 TCRβ or β: (single TCR T cells) were used as a reference for correct and format-independent TCR pairing. In a dual TCR setting, we observed that correct pairing of M1/A1 TCR chains was statistically significantly impaired when introducing TCRβ but remained unchanged (relative to single TCR T cells) when introducing TCRβ: (Fig. 5, A and B). Consequently, TCR mispairing was only evident between M1/A1 TCR and MelA/A2 TCRβ, but not between M1/A1 TCR: and MelA/A2 TCRβ:, the latter combination showing background levels of energy transfer (Fig. 5C). Direct proof of lack of mispairing between TCR19: and β27 confirmed the observation that surface expression of TCRβ27 is not affected as a consequence of TCRβ: gene transfer (Fig. 2B). Moreover, the histogram distribution of FRET values, being broad and showing left-handed shoulders in the case of M1/A1 TCRβ, suggests that the majority of, but not all, M1/A1 TCR chains mispair. In contrast, measurements based on M1/A1 TCRβ: result in homogenous FRET histograms confirming a uniform pairing of TCR: and β: (Fig. 6).

View larger version (30K): [in this window] [in a new window]   FIGURE 6. Genetic introduction of TCRβ: but not TCRβ induces a homogenous distribution of FRET values between corresponding as well as noncorresponding TCR and β chains in dual TCR T cells. Jurkat T cells expressing either M1/A1 TCRβ (dotted gray line) or TCRβ: (black line) in the presence of MelA/A2 TCRβ, previously enriched by FACS using anti-TCR-V19 and Vβ9 mAbs, were stained with donor- and acceptor-conjugated anti-TCR and β Abs and analyzed for FRET efficiency using a FACSCalibur dual-laser flow cytometer as described in Materials and Methods. T cells were stained either with (A) Cy5-labeled anti-TCR V19 and PE-labeled anti-TCR Vβ9 mAbs (as a measure of correct TCR pairing), or (B) Cy5-labeled anti-TCR V19 and PE-labeled anti-TCR Vβ27 mAbs (as a measure of TCR mispairing). Histograms represent the distribution of FRET values on a cell-by-cell basis from one of two experiments with similar results.

TCRβ: assembles independently of CD3, , and in T cells

To better understand the mechanism underlying the highly preferred pairing between TCR: and β: transgenes, we decided to study the TCR/CD3 stoichiometry as a consequence of TCR format. First, cell lysates of TCR-transduced Jurkat T cells were immunoprecipitated with either anti-TCRVβ9, CD3, CD3, or CD3 Abs (Figs. 7, A and B). Following gel electrophoresis, Western blotting, and immunodetection with anti-CD3 Ab, we observed that TCRβ, but not TCRβ:, complexes associate with CD3, independent of the presence of a second TCRβ (see IP with anti-TCRVβ9 mAb) (Fig. 7A). As expected, CD3 and CD3 complexes were present in all samples (see IP with anti-CD3 and Abs) (Fig. 7B). Probing blots with anti-CD3 Ab revealed that endogenous CD3 forms complexes with TCRβ, but only to a limited extent with TCRβ:, and that CD3 was associated with CD3, CD3, and CD3 in TCRβ, but not TCRβ: complexes (Fig. 7, A and B). These co-IP experiments point to an assembly between TCRβ: and a limited amount of endogenous CD3 that is independent of CD3, , or . Second, we confirmed the absence of CD3 from intracellular TCRβ: complexes at the surface level by FRET analysis (Fig. 7C). It is noteworthy that CD3 is the only CD3 component with an extracellular epitope accessible for flow cytometry, thereby enabling the analysis described. Following labeling of TCR-transduced T cells with donor- and acceptor-conjugated anti-TCRVβ9 and CD3 Abs, clear energy transfer was only detected for TCRβ but not TCRβ: (Fig. 7C).

View larger version (37K): [in this window] [in a new window]   FIGURE 7. TCRβ: assembly and surface expression is independent of endogenous CD3, CD3 and CD3. A, M1/A1 TCRβ or TCRβ: are introduced in either TCR-negative Jurkat T cells (nos. 1 and 2, respectively) or Jurkat T cell that already express a MelA/A2 TCRβ (nos. 3 and 4, respectively). TCR-transduced Jurkat T cells were enriched by FACS using anti-TCR-V19 and TCRVβ9 mAbs (specific for M1/A1 TCR). Cells were lysed in Brij96 and IP with one of the following Abs (A) BL37.2 (TCR-Vβ9), OKT3 (CD3-containing dimers) and (B) HMT 3.2 (CD3) and APA 1.2 (CD3). Immunoprecipitates were subjected to 7–17% SDS-PAGE, transferred to nitrocellulose and immunoblotted with either anti-CD3 mAb (M20) or anti-CD3 Ab 448. H, indicates Ig H chain. *, The presence of TCRβ:. This blot represents one of two independent experiments with similar results. C, TCR-negative Jurkat T were transduced with M1/A1 TCRβ or TCRβ: and enriched by FACS using anti-TCR-V19 and TCRVβ9 mAbs. T cells were double-stained either with Cy3-labeled anti-TCR Vβ9 (BL37.2) and Cy5-labeled anti-CD3 (OKT3) () or Cy3-labeled anti-CD3 and Cy5-labeled anti-TCR Vβ9 () and analyzed for FRET efficiency by flow cytometry as described in the legend to Fig. 5. FRET values represent one of two independent experiments with similar results.

TCRβ:, in contrast to TCRβ, mediates potent intracellular signaling and does not compromise the signaling ability of endogenous TCRβ in dual TCR T cells

Next, the function of TCRβ: and its effect on that of endogenous TCRβ was tested in dual TCR T cells. To this end, TCR-mediated activation of NFAT was analyzed in Jurkat T cells following stimulation with TCRβ-specific Abs. NFAT activation upon stimulation with anti-TCR Vβ9 mAb was 1.7-fold higher in T cells expressing M1/A1 TCRβ: relative to TCRβ (Fig. 8). Furthermore, NFAT activation through M1/A1 TCRβ was decreased whereas activation through M1/A1 TCRβ: was not affected in the presence of MelA/A2 TCRβ; again, a 2.2-fold difference was observed when comparing TCRβ: vs TCRβ. The function of MelA/A2 TCRβ was measured following stimulation with anti-TCR Vβ27 mAb and appeared similarly sensitive to the format of the introduced TCR genes. NFAT activation through MelA/A2 TCRβ is somewhat decreased but clearly detectable in M1/A1 TCRβ:-transduced T cells, whereas it is almost absent and comparable to activation upon stimulation with irrelevant IgG in M1/A1 TCRβ-transduced T cells. Here, Jurkat T cells expressing TCRβ: showed a 2.7-fold higher level of NFAT activation upon activation with anti-TCR-Vβ27 mAb than Jurkat T cells expressing TCRβ (Fig. 8).

View larger version (24K): [in this window] [in a new window]   FIGURE 8. TCRβ: mediates potent NFAT activation and does not compromise activation of NFAT mediated by an already present TCRβ in dual TCR T cells. The following Jurkat T cells were nucleofected with an NFAT reporter and β-galactosidase construct as described in Materials and Methods: TCR-negative T cells (); single TCR T cells expressing either MelA/A2 TCRβ (), M1/A1 TCRβ () or M1/A1 TCRβ: (); and dual TCR T cells expressing either MelA/A2 TCRβ and M1/A1 TCRβ () or MelA/A2 TCRβ and M1/A1 TCRβ: (). Jurkat T cells were enriched by FACS using anti-TCR-V19 and TCRVβ9 mAbs before NFAT reporter assays. T cells were stimulated for 6 h with either anti-TCR Vβ9, Vβ27 or irrelevant Abs. Luciferase activities were determined in cell lysates, normalized for β-galactosidase activities, and expressed relative to a nonstimulated condition (i.e., medium only: RLU = 0.04 in presented experiment and is set to 1.0). The bars represent mean RLU values ± SEM of three independent measurements. Numbers above bars indicate the average fold difference between NFAT activation downstream of TCRβ: vs TCRβ.

View larger version (18K): [in this window] [in a new window]   FIGURE 9. TCRβ: mediates Ag-specific functions to a comparable extent as TCRβ in primary human T cells. The HLA-A1-restricted and MAGE-A1-specific cytolytic capacity of M1/A1 TCRβ: and M1/A1 TCRβ-positive T cells was analyzed in 4-h 51Cr-release assays, using M1/A1-positive MZ2-MEL3.0 melanoma cells as target cells. CTL 82/30 and mock-transduced lymphocytes were used as positive and negative controls, respectively. M1-negative/A1-positive tumor target cells were not killed by any effector T cells (data not shown). Results from one representative experiment (of three) are shown.

	Discussion

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The following two strategies have been reported previously to address TCR mispairing. First, introduction of cysteines at structurally favorable positions in TCR-C and β (20) and second, replacement of TCR-C domains by the corresponding murine C domains (i.e., huV:muC) (21). Cysteine modification or murinization of TCR-C and β chains results in enhanced binding of pMHC as a measure of correct TCRβ pairing, and consequently in enhanced Ag-specific functions. A combination of both cysteine modification and murinization is reported to further improve binding of pMHC- and Ag-specific functions (39). A third strategy pursued to address TCR mispairing is represented by the introduction of reciprocal mutations in the TCR-C domains that prohibit binding to noncorresponding TCR chains, and although such a strategy is molecularly feasible it results in mutated TCR chains that express and functionally perform less than nonmodified TCR chains (55). TCR surface expression following gene transfer of only one modified TCR ( or β) chain modified by either one of these strategies or a combination of a modified TCR chain and the corresponding nonmodified TCR chain resulted in a reduced yet clearly detectable surface expression when compared with nonmodified TCRβ chains (20, 21). In addition, the ability of these modified TCRs to address TCR mispairing appears to depend on the TCR-V regions of the nonmodified TCR chains (22). In contrast, TCR: and TCRβ: do not mispair with endogenous TCRβ as evidenced by nonsurface expression of either of these chains following gene transfer of only one modified TCR chain and show a high and coordinated surface expression following gene transfer of both TCR: and TCRβ: chains (Fig. 2 and Table I). These data confirm our earlier findings (6) and were extended to three sets of TCRβs. Using TCRs specific for M1/A1, gp100/A2, and EBNA4/A11, we observed that the surface expression of an endogenous TCRβ (MelA/A2 TCR) was not compromised upon gene transfer of TCRβ: but not TCRβ (Fig. 4 and Table II, endogenous TCR). Consequently, the expression of the introduced TCRβ: was enhanced when compared with TCRβ for all three Ag specificities (Table II, exogenous TCR). Importantly, TCRβ genetically linked to CD3 represents the first strategy for which direct evidence is provided for highly preferred pairing between TCR: and TCRβ: using flow cytometry FRET and Abs directed either to corresponding or noncorresponding TCR and β chains. The energy transfer between corresponding TCR chains (i.e., M1/A1 TCR19 and β9) is significantly decreased in the case of TCRβ but not TCRβ: when comparing dual vs single TCR T cells (Fig. 5, A and B). Vice versa, the energy transfer between noncorresponding TCR chains (i.e., M1/A1 TCR19 and Mel/A2 TCRβ27) was only significantly detectable in case of TCRβ but not TCRβ: (Fig. 5C). Moreover, the histogram distribution of energy transfer values for TCRβ:, being homogenous and having a small width points to a more uniform pairing of TCRβ: when compared with TCRβ (see Fig. 6). We believe that TCRβ: successfully prevents TCR mispairing, although one cannot exclude that depending on TCR-V domains TCRβ: may pair to a small extent with some TCRβ, as suggested by a small but not statistically significant down-regulation of MelA/A2 TCRβ following introduction of TCRβ: specific for EBNA4/A11 (see Fig. 4 and Table II, endogenous TCR).

Co-IP and FRET analyses point to an assembly between TCRβ: and a limited amount of endogenous CD3 that is independent of CD3 (Fig. 7). CD3-independent assembly/surface expression of TCRβ: may explain why this TCR format successfully prevents TCR mispairing and consequently results in high TCR surface expression. The TCR/CD3 complex is composed of different single-spanning transmembrane proteins: the TCRβ heterodimer that is responsible for pMHC ligand recognition, and the noncovalently associated CD3, CD3, and CD3 dimers. Upon ligand binding, a change in the conformation of the TCR with respect to the membrane is a likely first step in TCR signaling (40), thereby establishing a molecular platform for productive TCR engagement, allowing recruitment of Nck, CD3-ITAM phosphorylation, and subsequent docking and activation of a large number of signaling components (41, 42, 43). The assembly of the TCR/CD3 complex is governed by interactions between the transmembrane domains of TCRβ and CD3 dimers, and to some extent by interactions between ectodomains (40, 44). The interaction between CD3 and an extracellular loop in TCR-C helps stabilize CD3 within the complex (which interacts with a TCR-Cβ loop) and contributes to TCR-mediated signaling. Pairs of acidic transmembrane residues present in the CD3 dimers contact the basic TCR transmembrane residues (K and R) and direct TCR:CD3 assembly. In case of the TCRβ:, the extracellular TCR loops are present but the transmembrane domains of TCR and β are replaced by those of CD3, thereby providing residues including a cysteine that induces dimerization between TCR: and β: and at the same time prevent TCR docking of CD3 and CD3 dimers. TCRβ: (or CD3 for that matter) does not recruit CD3 which ensures expression of functional ER retention signals of CD3 assembly intermediates (45) and refrains CD3 and CD3 dimers from surface expression. Therefore, total TCRβ: surface expression appears not to be regulated by accessory molecules such as CD3 components and, as a consequence is regulated differently in comparison to total surface expression of nonmodified TCRβ. In support of this notion, TCRβ: but not TCRβ expresses at the surface of non-T cells (i.e., epithelial retroviral packaging cells 293T; data not shown). Some TCRs, as determined by their TCR-V regions, only show weak surface expression and are not able to replace other TCRs on the cell surface (41, 42). These TCRs, but not more dominant TCRs, are expected to benefit most from cysteine modification and/or murinization to result in exchange of Ag specificity following TCR gene transfer (46, 47). In contrast, TCRβ: does not compete for available CD3 subunits and appears not dominant over an endogenous TCRβ because both TCRs are coexpressed in a dual TCR T cells (see Fig. 3), making the TCRβ: strategy more universal with respect to TCR-V regions. In addition, the enhanced surface expression and function of TCRβ: may be linked to TCR-interacting molecule, an adaptor molecule that normally associates with CD3 and contributes to TCR expression and signaling (48). Also, the absence of glycosylation sites that are normally present in TCR-C and β (a total of four sites in human TCRβ) may result in enhanced expression and avidity of TCRβ: (55). To analyze the TCRβ: format in more detail, it is important to note that the TCR: and β: chains contain the cysteine residues responsible for the interchain disulphide bridge, but the extracellular connecting peptide motif, transmembrane and intracellular domains of TCR and β are replaced by CD3. Connecting peptide motifs and β may affect the calcium pathway (49, 50), the transmembrane and intracellular domains of TCRβ may recruit the adaptor CARMA-1 which feeds into the NF-B pathway (51), and the intracellular tail of TCR may affect CD3 phosphorylation and TCR down-regulation (52). Because each of the replaced domains is reported to contribute to Ag-specific responses in murine T cells, we functionally analyzed TCRβ: in dual TCR T cells. We observed that TCRβ: mediates potent NFAT activation and does not compromise NFAT activation of an already present TCRβ in dual TCR Jurkat T cells (Fig. 8), which makes it unlikely for TCRβ: to mediate impaired calcium signaling because calcium is a necessary upstream mediator of NFAT activation. In fact, TCRβ: results in enhanced NFAT activation when compared with nonmodified TCRβ (Fig. 8), possibly due to phosphorylation of three ITAMs, downstream activation of phospholipase C1 and calcium mobilization. Although we cannot exclude that TCRβ: affects NF-B signaling and/or TCR down-regulation, this TCR has been extensively validated for tumor Ag-specific responses in primary human T cells such cytotoxicity and IFN- and TNF- production (see Fig. 9 and Refs. 6 , 31 , 32). Also, TCR:CD8 interactions were studied in primary human T cells by FRET and revealed no differences between TCRβ: and TCRβ (data not shown). In fact, these findings extend earlier observations that T cells are operational in the absence of CD3 components and/or their phosphorylation motifs (53, 54). Current research aims at reintroduction of those TCR domains into the TCRβ: format that are responsible for association with endogenous CD3 components in an effort to generate a modified TCR that shows an improved functional versatility as well as an ability to down-regulate the expression of endogenous TCR and thereby limiting, at least theoretically, the self-reactivity of ignorant T cells (those T cells that have escaped mechanisms of tolerance).

In closing, the TCRβ: successfully prevents TCR mispairing, shows high surface expression on T cells, mediates Ag-specific functions in primary T cells, and does not compromise surface expression and function of an already present TCRβ. This TCR format warrants further studies into TCR engineering to improve safety and efficacy of TCR gene therapy.

	Disclosures

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The authors have no financial conflict of interest.

	Footnotes

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ This work was supported by a European Community 6th Framework Grant 018914, entitled "Adoptive Engineered T-Cell Targeting to Activate Cancer Killing (ATTACK)."

² Address correspondence and reprint requests to Dr. Reno Debets, Department of Medical Oncology, Erasmus Medical Center–Daniel den Hoed Cancer Center, Groene Hilledijk 301, Rotterdam 3075EA, The Netherlands. E-mail address: j.debets{at}erasmusmc.nl

³ Abbreviations used in this paper: FRET, fluorescence resonance energy transfer; IP, immune precipitation; pMHC, peptide-MHC; RLU, relative light unit; MFI, mean fluorescence intensity.

Received for publication December 13, 2007. Accepted for publication March 26, 2008.

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