Abstract
Despite improvements in treatment, the 5-year survival for metastatic colorectal cancer remains poor. Novel approaches such as gene immunotherapy are being investigated to improve treatment. Retroviral gene transfer methods have been shown to transduce primary human T lymphocytes effectively resulting in the expression of therapeutic genes. However, a number of defects have been identified in T lymphocytes isolated from patients bearing tumour, which may have critical implications for the development of gene-targeted T cells as an anticancer therapy. To address this issue, primary T lymphocytes were isolated from patients with advanced colorectal cancer and tested for their ability to be transduced and to express subsequently a chimeric immune receptor consisting of a single-chain antibody fragment antigen-binding moiety specific for carcinoembryonic antigen (CEA) fused to the T cell receptor (TCR) CD3ΞΆ chain. In 10 out of 10 patients, T lymphocytes were transduced, expanded in the absence of selection and tested for functional activity against CEA-expressing tumour cells. In each case, functional-specific cytotoxic activity was observed. Negligible activity was found in control cultures. This study highlights the feasibility of patient-derived T lymphocytes as a source of immune cells for autologous gene immunotherapy approaches.
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Colorectal cancer affects approximately 300β000 people in Europe and the US each year (Midgley and Kerr, 1999), accounting for 20β30β000 deaths in the UK alone (Curley and Vecchio, 1998). Surgery can cure selected patients with liver metastases (DeMatteo et al, 2000; Biasco and Gallerani, 2001). However, despite continued advances in systemic treatment, the overall 5-year survival has not improved significantly for advanced colorectal disease (Midgley and Kerr, 1999).
Our aim is to utilise the power of the immune system as a novel form of cancer therapy. Gene therapy techniques have been developed to modify T lymphocytes in order to target and lyse colorectal tumour cells through the development of chimeric immune receptors (CIRs) (Hombach et al, 1999; Nolan et al, 1999; Beecham et al, 2000; Daly et al, 2000). CIRs are composed of antigen binding domains, usually derived from single-chain antibody fragments (scFv) (Hawkins et al, 1998), fused to the cytosolic domains of important signalling receptors (Gross et al, 1989) (Figure 1A). Our present work has focused upon the targeting of carcinoembryonic antigen (CEA) through a CEA-specific scFv fused to the CD3ΞΆ chain. CD3ΞΆ is thought to play the predominant role in T-cell signalling resulting in T-cell effector activity (Haynes et al, 2001). Binding of CEA by the CEA-specific CIR generates downstream activation signals resulting in cytokine production and target cell cytotoxicity in the absence of the usual restrictive mechanisms required for T-cell activation (Hombach et al, 1999; Nolan et al, 1999; Beecham et al, 2000; Daly et al, 2000). This approach results in the generation of large numbers of antigen-specific T cells. Importantly, since the CIRs recognise whole-protein antigens, tumour cells should not be able to avoid immune detection by the downregulation of immunoregulatory molecules such as major histocompatibility (MHC) molecules.
The CIRs used in this study were either an anti-CEA-specific scFv, MFE23 (derived by phage display technology) (Chester et al, 1994; Begent et al, 1996) or a control scFv (anti-neural cell adhesion molecule (NCAM)) (D29) (Whittington et al, 2001) fused to the human CD3ΞΆ protein. Both receptors have been shown to be active when introduced into primary human T lymphocytes derived from healthy donors (Gilham et al, 2002). Importantly, in T cells derived from these normal, healthy donors, the presence of soluble CEA did not inhibit the cytolytic activity of the gene-modified T lymphocytes suggesting that high-serum CEA should not interfere with the activity of the anti-CEA CIR in patients.
However, important questions remain concerning the viability of this approach for clinical use. A number of studies have demonstrated that T lymphocytes isolated from tumour-bearing mice (Mizoguchi et al, 1992) and patients (Bukowski et al, 1998) are dysfunctional owing to altered expression of key proteins including members of the CD3 complex. T lymphocytes isolated from patients with advanced melanoma (Saito et al, 2000), and head and neck cancer (Hoffman et al, 2002) have also been shown to be more susceptible to spontaneous apoptosis thereby potentially compromising the patient's own immune competence. Furthermore, tumour-infiltrating lymphocytes isolated from colorectal hepatic metastases have been shown to have reduced CD3ΞΆ chain expression and, upon expansion, lack tumour-specific lytic activity (Yoong and Adams, 1998). In view of this work and to further determine the viability of our approach in a clinical setting, T lymphocytes were isolated from the peripheral blood of patients with advanced colorectal disease (hepatic colorectal metastases) in order to determine whether they could be efficiently gene modified to express a chimeric immune receptor. Subsequently, the functional activity of the CIR in T lymphocytes was assessed through its ability to induce cytolytic activity when challenged with tumour cell lines in vitro.
Materials and methods
Reagents
All chemical reagents except where stated were purchased from Sigma (Dorset, UK). Anti-CD3Ι (OKT3) was purchased from Orthobiotech (USA) and anti-hCD28 from R&D Systems (Minneapolis, MN, USA). Chiron (Amsterdam, The Netherlands) supplied the recombinant human IL-2.
Cell culture
All cell culture materials were obtained from Life Sciences (Paisley, Scotland). The human CEA-positive cell lines MKN45βK (human gastric carcinoma, kindly provided by Dr J Embleton, PICR), LS174T (human colon adenocarcinoma, ECACC No. 87060401), LoVo (human colon adenocarcinoma, ECACC No. 87060101), NCAM positive SK-N-BE (human neuroblastoma, ATCC No. CCRL-2271), PG13 retroviral producer cells (Miller et al, 1991) and HeLa (human cervix epithelial carcinoma, ECACC No. 93021013) cell lines were all cultured in Dulbecco's modified Eagle's medium (DMEM) with 10% foetal bovine serum (FBS, Life Technologies, Paisley, Scotland). Patient T lymphocytes were cultured in T-cell media (RPMI 1640, 25βmM HEPES, 2βmM glutamine and 5 Γ 105 2-mercaptoethanol with the addition of 10% FBS). All cells were maintained in a 37Β°C 5% CO2/air incubator.
Production of recombinant receptors encoding CIRs
Stable PG13 cell lines producing either rkat.MFE23.CD3ΞΆTDGA.IRES.EGFP and rkat.D29.CD3ΞΆTDGA.IRES.EGFP recombinant retroviruses have been previously described (Gilham et al, 2002). These vectors consist of the MFE23 scFv (specific for CEA) or the D29 scFv (specific for NCAM) fused to the CD3ΞΆ receptor protein with the enhanced green fluorescent protein (EGFP) coexpressed by means of an internal ribosome entry site (IRES) element. Cell culture media were aspirated from PG13 cell monolayers (approximately 70β80% confluent) and replaced with T-cell media. Retrovirus was collected after an overnight incubation and then filtered through a 0.45βΞΌm filter prior to its use in transduction. T-cell media were replaced onto the PG13 monolayer with more virus collected and filtered after an overnight incubation for second and subsequent transductions.
Patient details
All patients selected were due to undergo hepatic resection for colorectal liver metastases and were consented for the purposes of this study as approved by North and South Manchester Ethics committees. The median age of the patients was 66 years (range 42β73 years, mean 65.2Β±9.9 years). No patient had received any form of chemotherapy for at least 1 month prior to T lymphocyte harvest. Preoperative serum CEA levels and operations performed are listed in Table 1.
Patient T lymphocyte isolation and transduction
Approximately 20βml of venous blood was obtained from each patient approximately 2β3 weeks prior to hepatic resection. Heparinised venous blood was diluted 1β:β1 ratio with serum-free RPMI 1640 media and mononuclear cells isolated by Ficoll-density gradient centrifugation (FicollβHistopaque (density 1077βgβlβ1) Sigma, Dorset, UK). Monocytes were depleted by adherence to plastic by culture for 1βh in tissue culture flasks at 37Β°C. Nonadherent lymphocytes were isolated and activated in 6-well nontissue culture plates precoated antibody (OKT-3 and anti-CD28) with 100βIUβmlβ1 interleukin-2 (IL-2) for at least 3 days. After activation, T lymphocytes were ficolled to remove dead cells, washed and counted. 1β4.5 Γ 106βT lymphocytes were mixed with PG13-derived retroviral supernatant and polybrene (6βΞΌgβmlβ1) in a 50βml falcon tube and centrifuged for 2β3βh at 1400 Γ g. Mock-transduced cells were mixed with T-cell media with polybrene instead of retroviral supernatant and centrifuged. After centrifugation, T lymphocytes were cultured overnight at 5 Γ 105βml with 100βIUβmlβ1 IL-2. Centrifugal transduction was repeated the next day and the resulting cell populations were maintained at 5 Γ 105βcellsβmlβ1 in 100βIUβmlβ1 IL-2. Fresh media and IL-2 were added every 2β3 days.
Flow cytometry
Cells were washed with phosphate-buffered solution (PBS)/2% bovine serum albumin (BSA) and then resuspended in saturating concentrations of antibody (anti-CD3Ι, CD4, CD8 and suitable isotype controls (all R-Phycoerythrin conjugated) purchased from Pharmingen, Oxford, UK) on ice for 30βmin. Cells were then washed twice with PBS/2% BSA, fixed in 2% paraformaldehyde and analysed using a FACscan (Becton Dickenson, CA, USA) with winMDI version 2.8 analysis software.
Cytotoxicity assays
Three days prior to cytotoxicity assay, T lymphocytes were cultured in low IL-2 (20βIUβmlβ1) to reduce background lymphokine-activated killer (LAK) activity (Gilham et al, 2002). An 8-h chromium release assay was performed as previously described (Gilham et al, 2002) with effectorβ:βtarget ratios from 50β:β1 to 6.25β:β1. Maximal release was obtained by coculture with 100βΞΌl 2% Triton X-100/PBS and spontaneous release by target cell culture in media alone. Percentage-specific lysis was determined by the following formula:
Western blotting
Patient T lymphocytes were washed with PBS and lysed in RIPA buffer (150βmM NaCl, 1% NP-40, 0.5% deoxycholic acid, 0.5% sodium dodecyl sulphate (SDS) and 50βmM Tris-Cl pH 8.0) at the time of cytotoxicity assay and stored at β70Β°C. Approximately 5 Γ 105 cells were separated by standard techniques using SDS/PAGE on 10% resolving gels (Lamelli, 1970). Hybondβ’ ECLβ’ nitrocellulose membrane (Amersham Pharmacia Biotech, Buckinghamshire, UK) was used for blots with anti-CD3ΞΆ (clone 8D3) at 1β:β1000 dilution (Pharmingen, Oxford, UK) and a secondary of sheep anti-mouse HRP antibody at 1β:β2000 dilution (Sigma, Dorset, UK). Visualisation was performed using ECLβ’ reagents (Amersham Pharmacia Biotech, Buckinghamshire, UK).
Tumour cell survival assay
Adherent tumour target cell lines (MKN45βK, LS174βT, LoVo and HeLa) were plated at a density of 5000 cells in 100βΞΌl of T cell media per well of flat-bottomed 96-well plates. These cells were allowed to adhere for 3βh at which point a further 100βΞΌl of T-cell media containing either varying numbers of transduced or control T lymphocytes or culture medium alone was added to the target cells to generate a final volume of 200βΞΌl. In some experiments, IL-2 was added to a final concentration of 100βIUβmlβ1. After a period of coculture, the supernatant containing nonadherent cells was removed and the remaining cells cultured in DMEM with 10% FBS without IL-2 for a further 5β6 days. The culture medium was aspirated, the cells washed once with PBS and 100βΞΌl of DMEM with 10% FBS containing a 40-fold dilution of Wst-1 reagent (Roche, Surrey, UK). At suitable time points, the optical density of the wells was determined using an ELISA plate reader (Molecular Devices, Sunnydale, CA, USA) set at 450β650βnm. Maximal cell growth was determined from the optical density reading of tumour cells cultured without T lymphocytes and minimal cell growth was determined from tumour cells cultured without T lymphocytes and lysed with 50βΞΌl of 2% Triton X-100/PBS. Relative tumour cell growth was estimated by the following equation:
Results
Transduction of patient T lymphocytes
Twenty millilitres of venous blood was obtained from patients 1 to 10 two to three weeks prior to the date of surgery. T lymphocytes were isolated and activated using immobilised anti-CD3 and anti-CD28 antibodies. After 3 days of antibody activation, 5β10 Γ 106 viable T cells were counted by trypan blue exclusion for each patient indicating that in 10 out of 10 samples, T lymphocytes were successfully activated. Transduction with retroviruses encoding the anti-CEA CIR, MFE23.CD3ΞΆTDGA or the anti-NCAM CIR, D29.CD3ΞΆTDGA (Figure 1A) was performed using centrifugation in the presence of polybrene. After transduction, patient T lymphocytes were expanded in number by 5β10-fold over the next 7β21 days in the presence of 100βIUβmlβ1 of IL-2 (data not shown). Flow cytometry analysis confirmed the cell populations to consist largely of CD3-positive T lymphocytes (87β99%, Table 1). The IL-2-based expansion protocol supported the growth of the polyclonal T lymphocyte populations, although there was a relative predominance of CD8+ over CD4+ T cells. The lowest ratio of CD8β:βCD4 was 1.5β:β1, while ratios in excess of 10β:β1 were recorded for two donors.
The level of retroviral transduction was estimated through the expression of the EGFP marker gene. A degree of heterogeneity was also observed with the levels of retroviral transduction varying between 2 and 33% (Table 1). In each patient sample, the ratio of transduced CD8 to transduced CD4 cells reflected the overall ratio of total CD8 to CD4βT cells in the total population suggesting there to be little bias in the susceptibility of either T-cell sub-type to transduction by the PG13-derived retroviruses.
Chimeric immune receptor expression in T lymphocytes was confirmed by Western blotting (Figure 1B). Nonreducing Western blots identified the formation of CIR homodimers and also heterodimers formed between the CIR and wild-type CD3ΞΆ. Reducing Western blots demonstrated an immunoreactive band at the predicted molecular mass of the CIR (43βkDa) with the native CD3ΞΆ protein present as a 16βkDa immunoreactive band.
Specific cytotoxicity of CEA-positive cells by patient-modified T lymphocytes
MFE23.CD3ΞΆTDGA-modified lymphocytes from patient 1 demonstrated specific cytotoxic activity against the CEA-expressing gastric tumour cell line MKN45βK and the colon adenocarcinoma LS174T cell line. Negligible cytotoxicity was observed when NCAM-targeted (D29.CD3ΞΆTDGA) and mock-transduced T lymphocytes were cocultured with the MKN45βK or LS174βT cell lines (Figures 2A and B). Specific CEA-targeted lysis was found to be increased by at least seven-fold over that of nontargeted lymphocytes.
The specificity of cell killing was confirmed by the cytotoxic activity of D29.CD3ΞΆTDGA-transduced T lymphocytes against NCAM-positive neuroblastoma SK-N-BE target cells (Figure 2C). In this case, low background activity was found when CEA-targeted (MFE23.CD3ΞΆTDGA) and mock-transduced T lymphocytes were cultured with CEA-negative SK-N-BE cells (Figure 2C). HeLa cells (NCAM- and CEA-negative) were used to demonstrate equivalent nonspecific killing by all three populations thereby confirming that the specific killing observed was because of CIR activity and not because of any altered killing properties of the individual lymphocyte populations (Figure 2D). The level of retroviral transduction (as assessed by the expression of EGFP) was 20% in the MFE23.CD3ΞΆTDGA CIR-expressing population generated from patient 1. This figure indicates that the maximal transduced effector to target ratio was 10β:β1 with highly specific cytolytic activity observed down to a ratio of 1.25 transduced effector cells per target (Figure 2A). In the case of NCAM-targeted cells (SK-N-BE, Figure 2C), the proportion of D29.CD3ΞΆTDGA-expressing cells was estimated to be 15%, hence, the transduced effector to target ratio was maximally 7.5β:β1 with clear specific cytolytic activity at the lowest ratio tested (0.9 transduced T cells per target cell).
Specific, targeted cytotoxicity was subsequently demonstrated for the remaining five patient lymphocyte samples against MKN45βK gastric carcinoma cells (Figure 3). In each case, specific, dose-dependent killing was observed. Furthermore, in each case, very low background levels of killing were observed (D29.CD3ΞΆTDGA and mock-transduced lymphocytes). This probably reflects the period of preculture in low concentrations of IL-2 reducing nonspecific cytokine-mediated killing activity. Equivalent specific lysis was observed between the various transduced cell populations when tested against CEA-negative, NCAM-negative target cells indicating there to be no difference in the overall killing activity of the modified or nonmodified T lymphocyte populations (data not shown).
A consideration of the level of retroviral transduction (as assessed by EGFP expression) did not appear to provide a clear relation between the levels of expression of the CIRs with the observed CIR-mediated cytotoxic activities. There was maximally a 6.6-fold difference between these six patient samples in retroviral transduction frequency, yet the cytotoxic activity varied only 1.6-fold. It was clear that the lowest level of transduction correlated with the weakest cytolytic activity (Patient 2; 5% CD3+, GFP+; 20.1% specific killing). However, there appeared little difference in cytolytic activity in these populations once a transduction level of 20% had been achieved.
Tumour cell survival after coculture with gene-modified T lymphocytes
Short-term assessments of cytolytic activity clearly demonstrated that CIR-expressing T-cell populations were functional against protein antigen targets in an MHC-independent manner. In an attempt to investigate and understand the functionality of these gene-modified cell populations further, and in an effort to quantify the overall efficiency of the targeted gene modified cells, longer-term tumour cell survival assays were used to assess the effectiveness of these T cells. Adherent tumour cell lines were cocultured with nonadherent T lymphocytes for set periods of time, after which the nonadherent cells were removed and the tumour cells cultured in media without cytokines to ensure that any remaining T cells would not survive. Five to six days, later, the growth of the tumour cells was assessed using an MTT-based assay (Mosmann, 1983).
Multiple cell lines were used in order to examine the activity of the anti-CEA-targeted T cells. The CEA-expressing human colon adenocarcinoma lines (LS174βT and LoVo) as well as the gastric carcinoma cell line (MKN45βK) were tested as targets along with HeLa cells used as a control since they do not express CEA. This subsequent work utilised T lymphocytes generated from four further patients (7β10, Table 1). The results depicted in Figure 4 represent the activity of cells generated from Patient 10 and are representative of experiments performed with Donors 7β10.
The first observation was that the cell lines used displayed a differential degree of susceptibility to coculture with transduced or control T lymphocytes. HeLa cells proved to be the most sensitive in that very low levels of target cell survival were recorded when cocultured for 24βh in the presence of T cells at an effectorβ:βtarget ratio approaching 1β:β1 (Figure 4D). However, it was clear that there existed no difference in the sensitivity of HeLa cells to either transduced or nontransduced T cells, indicating that there was equivalent nonspecific killing activity between the T-cell populations in agreement with the results observed in chromium release assay. The specific effect of T-cell targeting was observed in assays using CEA-expressing tumour cell lines. In each case, tumour cell survival was reduced in a dose-dependent manner when the target cells were cocultured with MFE23.CD3ΞΆTDGA T-cell populations as compared to either NCAM-targeted or control nontransduced T cells (Figure 4AβC). There was a clear difference in target cell growth observable at effectorβ:βtarget ratios of 10β:β1, which represented a transduced effectorβ:βtarget ratio of 1.4β:β1. However, only at the highest cell dose (80β:β1 total cells, 11.2β:β1 transduced effector:target ratio) there was no tumour cell growth observed by all three target cell lines after a 24-h period of coculture. The susceptibility of the gastric (MKN45βK) and adenocarcinoma (LoVo and LS174βT) cell lines to nonspecific killing was reduced compared to that of HeLa cells. However, in the case of LoVo and LS174βT cells, the highest dose of nontargeted control T cells resulted in a reduction in target cell survival to levels approximately 40% of maximal (Figures 4A and C). For MKN45βK target cells, there appeared to be an equivalent degree of antitumour activity in targeted (MFE23.CD3ΞΆTDGA) and nontargeted (D29.CD3ΞΆTDGA and mock-transduced T cells) at the maximum dose of effector cells (Figure 4B). Microscopic examination of the culture wells confirmed that large adherent tumour cells were present in the wells identified as having metabolic activity within the assay with few lymphocytic cells present. This indicated that attached lymphocytes made a minimal contribution to the metabolic activity of the wells in agreement to similar assays performed elsewhere (Hombach et al, 2001).
The inclusion of IL-2 during the period of coculture drastically enhanced the effectiveness of target cell killing. For control HeLa cell targets, a maximal repression of target cell growth was observed at an effectorβ:βtarget ratio of 20β:β1 compared to a ratio of 80β:β1 required in the absence of this cytokine. Once again, there was little difference between the effectiveness of each T-cell population in repressing HeLa cell growth (Figure 4H). A similar degree of enhanced antitumour activity was recorded after coculture of CEA-expressing cell lines with the T-cell populations. Maximal tumour cell growth repression was found at lower doses of effector cells than in the absence of IL-2. Total repression was found at effectorβ:βtarget ratios of 20β:β1 (2.8 transduced MFE23.CD3ΞΆTDGA cellsβ:β1 target) for both LS174βT and MKN45βK cells, while the low dose of 2.5β:β1 (0.4 transduced cells per effector target) resulted in maximal LoVo cell killing. The specificity of activity was maintained with a clear difference in the cytolytic activity of targeted and nontargeted (NCAM and mock-transduced cells) being evident (Figures 4EβG). However, enhanced nonspecific, cytokine-driven killing activity was observed against each cell line since a total repression of tumour cell growth occurred at lower effector doses than that observed in the absence of IL-2.
Discussion
Recent studies have shown that T lymphocytes can be redirected against cancer cell lines using CEA as a target antigen through the use of CIRs expressed in T cells isolated from healthy donors (Nolan et al, 1999; Beecham et al, 2000; Daly et al, 2000; Hombach et al, 2000). In our study, the chimeric receptor consisted of an extracellular antigen-binding domain (scFv) specific for CEA (Chester et al, 1994; Begent et al, 1996), attached to the CD3ΞΆ component of the T-cell receptor complex. This CIR has already been demonstrated to be effective in initiating cytokine secretion and the cytotoxic activities of normal donor T lymphocytes (Gilham et al, 2002).
In the light of published work demonstrating the dysfunctional properties of T lymphocytes isolated from patients with a cancer load (Rosenberg et al, 1994; Bukowski et al, 1998; Yoong and Adams, 1998), the aims of this project were to assess whether the conditions used to activate and transduce T lymphocytes from normal donors were equally effective in T lymphocytes from patients with advanced colorectal cancer. In addition, it is important to evaluate whether CIR crosslinking in the presence of antigen would generate a response in patient cells similar to that of normal donors.
Ten patients with advanced colorectal cancer were recruited into this study. T lymphocytes were successfully transduced with efficiencies ranging from 2 to 33% (mean 15Β±9%, n=20) for all viruses and from 5 to 33% (mean 19.4Β±7.8%) for MFE23.CD3ΞΆTDGA-transduced T cells (Table 1). It is clear that higher levels of transduction are preferable particularly with respect to use in a clinical context. Protocols have been devel-oped that have reported high-level gene transfer using longer antibody-mediated preactivation periods (Movassagh et al, 2000), through the use of retronectin to enhance infection (Hanenberg et al, 1996) or by preloading plates with retrovirus (Kuhlcke et al, 2002). The levels of retroviral transduction generated here represent those achieved using a short period of centrifugation (spin-fection) and is adaptable to transduction on a large scale. An over-riding issue concerns the development of such protocols into a clinically applicable process using good manufacturing process (GMP) guidelines. Clinical trials using chimeric receptor expressing T lymphocytes against HIV (Mitsuyasu et al, 2000) and current trials using plasmid-transfected T cells expressing chimeric receptors (Jensen et al, 2000) have demonstrated the feasibility of this approach, and efficient gene-transfer protocols are now being developed based upon this experience. As a result, the optimal protocol may or may not feature some of the methods described above. As such, the use of a spin-fection protocol permitted levels of transduction that were suitable to permit the analysis of CIR activity in primary patient T cells.
After transduction, all 10 of the patient T-cell samples were expanded using an IL-2-based expansion protocols. The level of expansion reported here using IL-2 alone ranged from five- to 10-fold above the starting number. For clinical application, an ideal scenario would involve the generation of large numbers of T cells from, for example, a single blood collection or leucophoresis. It would be anticipated that a larger scale expansion of patient-derived lymphocytes would be required. Preliminary studies have shown that the inclusion of soluble antibodies (OKT3 and anti-CD28) with IL-2 enhanced the level of expansion above that with IL-2 alone (data not shown). These experiments have used standard media with FBS and, as such, do not represent conditions proposed for use in a clinical situation. Our efforts are now directed to investigating the growth of patient-derived T lymphocytes using GMP conditions reported for the maximal growth of T lymphocytes elsewhere (Carlens et al, 2000). However, the fact that all 10 patient samples were successfully transduced and expanded was encouraging, considering the reported frailties of patient-derived T lymphocytes (Mizoguchi et al, 1992; Rosenberg et al, 1994; Bukowski et al, 1998).
The CIR-bearing cell populations responded to antigen present on cell lines through specific target cell lysis in an MHC-independent manner. Importantly, even in the T-cell population with the lowest transduction level, significant antigen-specific cytotoxic activity was observed. Interestingly, increasing the level of retroviral transduction did not result in an increasing functional cytotoxic activity. Once a transduction level of 20% had been achieved, there appeared to be little increase in overall antigen-specific cytotoxicity as assessed by chromium release assay. These observations, albeit on a restricted number of transduced patient samples, indicates that more complicated factors may be at work. Further work is required to determine whether the killing activity generated by the transduced population is mediated by a few modified cells acting with high efficiency or whether the majority of CIR-expressing cells are acting at lower efficiency in order to generate the antigen-specific cytotoxicity observed here. This is important because further development of this approach may require optimisation of the receptor in order to produce a stronger response in cells where killing efficiency is low, while a modification to T-cell activation and culture conditions may be required to generate a greater number of highly cytotoxic T cells.
Interestingly, the specific production of interferon gamma from the T-cell cultures in the presence of antigen was less clearcut. Although there was evidence of specific cytokine production from some donors, in others there was either high background or poor levels of overall cytokine secretion (data not shown). The reasons for this are unclear, but were not related to cytotoxic activity.
An alternative to the chromium release assay was used to further investigate the potential of the gene-modified T lymphocytes. Tumour cell survival was assessed after a period of coculture with T cells. These assays potentially assess the longer-term interactions of effector and target cells, which may affect target cell survival through processes such as the induction of apoptosis through cytokine activity or death receptor activation.
An important observation was the fact that there was a difference in the overall sensitivity of the individual tumour cell lines to coculture with allogeneic T cells. This feature may be reflected in vivo where tumours would most likely show a variation in susceptibility to T lymphocyte activity. HeLa cells proved to be most sensitive to nonspecific killing in the tumour cell survival assay. In comparison, the colon adenocarcinoma and gastric cell lines were more resistant to nonspecific killing, although these cell lines were efficiently targeted by anti-CEA CIR-expressing T-cell populations. Coculture in the presence of IL-2 drastically enhanced both the nonspecific and specific killing activities of the T-cell populations. A total repression of target cell growth was seen in effectorβ:βtarget ratios as low as 2.8 transduced T cells per target for MKN45βK and LS174βT cells and as low as 0.4 transduced cells per target for LoVo cells. It is not clear whether the enhanced cytolytic activity is through enhanced lymphokine-activated killer (LAK) activity of the T cells resulting in the T cells being more active in cytolytic assays or whether the IL-2 was acting as a survival factor effectively enhancing the survival of the T cells (which had previously been expanded in IL-2), thereby permitting an enhanced killing activity. In either case, it is clear that cytokine help is potentially of crucial importance in the clinical setting through the reduction of the number of T cells required to target a tumour mass.
From the in vitro data presented here, the addition of IL-2 resulted in at least a four-fold decrease in the cell number required to effect a total repression of tumour cell line growth. It is impossible to apply in vitro assay results directly to the problem of dealing with tumour masses in vivo. However, this work suggests that for CIR-expressing T lymphocytes to function in a practical form in vivo, the CIR-modified cells will require some help in the form of survival or activation signals. These signals may take the form of infusions of IL-2. However, IL-2 administration is associated with toxicity. Alternative studies in our own group have investigated the ability of antiapoptotic genes to act as survival factors which could be expressed from a single retroviral construct (Eaton et al, 2002). Recent developments in CIRs have also involved the generation of receptors composed of the CD3ΞΆ domain fused to the CD28 receptor signalling chain (Hombach et al, 2001; Maher et al, 2002). These fusion receptors generate both a cytotoxic response and a costimulatory signal (and therefore IL-2 production) in an attempt to more closely mimic the events that naturally occur when T cells encounter antigen-producing cells in order to produce an effective immune response.
Our data indicate that T lymphocytes derived from patients with advanced colorectal cancer are able to mount effective, MHC-independent, functional responses after transduction with CIR-encoding recombinant retroviruses. Other studies have shown that T lymphocytes isolated from patients with ovarian (Parker et al, 2000) and prostate (Gong et al, 1999) cancers are also susceptible to retroviral transduction and CIR-mediated functional activity. These studies together demonstrate that patient-derived T lymphocytes are indeed suitable as vehicles for this type of gene modification and that CIR technology is highly flexible through the use of antibody recognition enabling virtually any protein antigen to be targeted by T lymphocytes. However, it is also clear from this work that a further understanding of CD3ΞΆ-based CIR activities and aspects of manipulated T lymphocyte biology, particularly with respect to their function in vivo and the development of practical GMP-based handling methods, are required to ensure that this approach is fully adapted for clinical trial.
Change history
16 November 2011
This paper was modified 12 months after initial publication to switch to Creative Commons licence terms, as noted at publication
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Acknowledgements
AJS was supported by HALT (Help Against Liver Tumours, a registered Charity No. 1054556) and Cancer Research UK. DEG, JI and REH were supported by Cancer Research UK. We acknowledge the support of The Neuroblastoma Society and the assistance of A O'Neill with the retroviral vector constructions, N Kirillova with the initial T lymphocyte work and Dr R Guest for their valuable contributions.
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Sheen, A., Sherlock, D., Irlam, J. et al. T lymphocytes isolated from patients with advanced colorectal cancer are suitable for gene immunotherapy approaches. Br J Cancer 88, 1119β1127 (2003). https://doi.org/10.1038/sj.bjc.6600857
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DOI: https://doi.org/10.1038/sj.bjc.6600857
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