Activation by anti-CD3 of tumor-draining lymph node cells for specific adoptive immunotherapy.

Lymph nodes draining progressive tumors contain tumor-sensitized but not functional preeffector T lymphocytes. These cells can acquire antitumor reactivity after stimulation with tumor cells and interleukin-2 (IL-2). We demonstrated here that, in the absence of tumor cells, preeffector cells could be stimulated and expanded by sequential culture with anti-CD3 monoclonal antibody and IL-2. The adoptive transfer of such activated cells mediated immunologically specific reductions of established pulmonary metastases. The therapeutic effects could be enhanced by the administration of IL-2. This activation represents a secondary immune response because effector cells could be generated only from tumor-draining but not from normal or adjuvant-stimulated lymph nodes. Furthermore, treatment of advanced metastases with these cells resulted in prolongation of survival and cure of the disease. Thus, anti-CD3 may serve as a universal reagent for activating tumor-sensitized T lymphocytes for cancer therapy.     

Successful adoptive immunotherapy of murine poorly immunogenic tumor with specific effector cells generated from gene-modified tumor-primed lymph node cells

We previously reported that cytokine gene transfer into weakly immunogenic tumor cells could enhance the generation of precursor cells of tumor-reactive T cells and subsequently augment antitumor efficacy of adoptive immunotherapy. We investigated whether such potent antitumor effector T cells could be generated from mice bearing poorly immunogenic tumors. In contrast to similarly modified weakly immunogenic tumors, MCA102 cells, which are chemically induced poorly immunogenic fibrosarcoma cells transfected with cDNA for IL-2, IL-4, IL-6, IFN-gamma, failed to augment the host immune reaction. Because priming of antitumor effector T cells in vivo requires two important signals provided by tumor-associated Ags and costimulatory molecules, these tumor cells were cotransfected with a B7-1 cDNA. Transfection of both IFN-gamma and B7-1 (MCA102/B7-1/IFN-gamma) resulted in regression of s.c. tumors, while tumor transfected with other combinations of cytokine and B7-1 showed progressive growth. Cotransfection of IFN-gamma and B7-1 into other poorly immunogenic tumor B16 and LLC cells also resulted in the regression of s.c. tumors. Cells derived from lymph nodes draining MCA102/B7-1/IFN-gamma tumors showed potent antitumor efficacy, eradicating established pulmonary metastases, but this effect was not seen with parental tumors. This mechanism of enhanced antitumor efficacy was further investigated, and T cells with down-regulated L-selectin expression, which constituted all the in vivo antitumor reactivity, were significantly increased in lymph nodes draining MCA102/B7-1/IFN-gamma tumors. These T cells developed into potent antitumor effector cells after in vitro activation with anti-CD3/IL-2. The strategy presented here may provide a basis for developing potent immunotherapy for human cancers.     

Combination of active specific immunotherapy or adoptive antibody or lymphocyte immunotherapy with chemotherapy in the treatment of cancer

Successful treatment of cancer patients with a combination of monoclonal antibodies (mAb) and chemotherapeutic drugs has spawned various other forms of additional combination therapies, including vaccines or adoptive lymphocyte transfer combined with chemotherapeutics. These therapies were effective against established tumors in animal models and showed promising results in initial clinical trials in cancer patients, awaiting testing in larger randomized controlled studies. Although combination between immunotherapy and chemotherapy has long been viewed as incompatible as chemotherapy, especially in high doses meant to increase anti-tumor efficacy, has induced immunosuppression, various mechanisms may explain the reported synergistic effects of the two types of therapies. Thus direct effects of chemotherapy on tumor or host environment, such as induction of tumor cell death, elimination of regulatory T cells, and/or enhancement of tumor cell sensitivity to lysis by CTL may account for enhancement of immunotherapy by chemotherapy. Furthermore, induction of lymphopenia by chemotherapy has increased the efficacy of adoptive lymphocyte transfer in cancer patients. On the other hand, immunotherapy may directly modulate the tumor’s sensitivity to chemotherapy. Thus, anti-tumor mAb can increase the sensitivity of tumor cells to chemotherapeutic drugs and patients treated first with immunotherapy followed by chemotherapy showed higher clinical response rates than patients that had received chemotherapy alone. In conclusion, combination of active specific immunotherapy or adoptive mAb or lymphocyte immunotherapy with chemotherapy has great potential for the treatment of cancer patients which needs to be confirmed in larger controlled and randomized Phase III trials.     

Preparing clinical grade Ag-specific T cells for adoptive immunotherapy trials

The production of clinical-grade T cells for adoptive immunotherapy has evolved from the ex vivo numerical expansion of tumor-infiltrating lymphocytes to sophisticated bioengineering processes often requiring cell selection, genetic modification and other extensive tissue culture manipulations, to produce desired cells with improved therapeutic potential. Advancements in understanding the biology of lymphocyte signaling, activation, homing and sustained in vivo proliferative potential have redefined the strategies used to produce T cells suitable for clinical investigation. When combined with new technical methods in cell processing and culturing, the therapeutic potential of T cells manufactured in academic centers has improved dramatically. Paralleling these technical achievements in cell manufacturing is the development of broadly applied regulatory standards that define the requirements for the clinical implementation of cell products with ever-increasing complexity. In concert with academic facilities operating in compliance with current good manufacturing practice, the prescribing physician can now infuse T cells with a highly selected or endowed phenotype that has been uniformly manufactured according to standard operating procedures and that meets federal guidelines for quality of investigational cell products. In this review we address salient issues related to the technical, immunologic, practical and regulatory aspects of manufacturing these advanced T-cell products for clinical use.     

Costimulation tunes tumor-specific activation of redirected T cells in adoptive immunotherapy

Redirecting T cell effector functions towards pre-defined target cells represents an attractive concept in the adoptive immunotherapy of malignant diseases. Our understanding of the mechanisms of T cell activation and costimulation as well as the design of recombinant T cell receptors have made major progress in the last years. Translating recent concepts of T cell stimulation into recombinant protein design provides the basis to engineer T cells with both pre-defined specificity and costimulatory capacity in order to enhance anti-tumor immunity and to break tolerance. Dual signaling immunoreceptors providing the CD3ζ signal simultaneously with an appropriate costimulatory signal moreover allows to modulate the quality of the anti-tumor T cell response in a predicted fashion. This article is a symposium paper from the conference “Cancer Immunotherapy 2006 Meets Strategies for Immune Therapy”, held in Mainz, Germany, on 4–5 May 2006.     

Dendritic cells for specific cancer immunotherapy

The characterization of tumor-associated antigens recognized by human T lymphocytes in a major histocompatibility complex (MHC)-restricted fashion has opened new possibilities for immunotherapeutic approaches to the treatment of human cancers. Dendritic cells (DC) are professional antigen presenting cells that are well suited to activate T cells toward various antigens, such as tumor-associated antigens, due to their potent costimulatory activity. The availability of large numbers of DC, generated either from hematopoietic progenitor cells or monocytes in vitro or isolated from peripheral blood, has profoundly changed pre-clinical research as well as the clinical evaluation of these cells. Accordingly, appropriately pulsed or transfected DC may be used for vaccination in the field of infectious diseases or tumor immunotherapy to induce antigen-specific T cell responses. These observations led to pilot clinical trials of DC vaccination for patients with cancer in order to investigate the feasibility, safety, as well as the immunologic and clinical effects of this approach. Initial clinical studies of human DC vaccines are generating encouraging preliminary results demonstrating induction of tumor-specific immune responses and tumor regression. Nevertheless, much work is still needed to address several variables that are critical for optimizing this approach and to determine the role of DC-based vaccines in tumor immunotherapy.     

Rapid expansion of tumor-reactive cells from HLA-matched siblings for adoptive immunotherapy of melanoma

BACKGROUND: Administration of expanded tumor-infiltrating lymphocytes in association with lymphodepleting chemotherapy is effective in some patients with advanced malignant melanoma. However, obtaining lymphocytes and subsequent expansion is labor intensive, making it impractical for broad clinical application. Allogeneic transplantation may have anti-melanoma efficacy because of a graft vs. tumor effect. The disappointing tumor control observed post-transplant suggests that adoptive immunotherapy using melanoma-reactive cells will be essential for sustained responses. METHODS: Melanoma cell lines were grown from two patients with advanced disease. High-level CD80 and CD86 expression was obtained in the tumor lines using a retroviral vector for gene transfer. Transduced melanoma and controls were cultured with mononuclear cells from HLA-identical sibling donors. RESULTS: Expression of CD80 and CD86, particularly the former, promoted marked expansion of lymphocytes from HLA-matched sibling donors. Proliferation of up to 300-fold after 4 weeks of culture was observed. Lymphocytes from cultures stimulated with CD80 demonstrated cytotoxicity against recipient-untransfected melanoma (45-75% specific lysis at an E:T ratio of 50:1). Although expanded lymphocytes were predominantly CD4(+), cytotoxicity was greatest in the numerically smaller CD8(+) subpopulation. Both CD4(+) and CD8(+) cells secreted IFN-gamma (but not IL-4) on exposure to untransduced stimulator melanoma cells. DISCUSSION: Our strategy generates a large number of melanoma-reactive lymphocytes from HLA-identical siblings using a 4-week culture strategy. Lymphocytes expanded in this way offer an alternative to tumor-infiltrating lymphocytes for allogeneic cellular immunotherapy after stem cell transplantation in young patients.     

Generation and ex vivo expansion of HTLV-1 specific CD8+ cytotoxic T-lymphocytes for adoptive immunotherapy

CD8(+) cytotoxic T-lymphocytes (CTLs) have been proven, in multiple animal models, to be the most powerful antiviral and antitumor components of the immune system. We have developed a protocol to activate and expand tumor and virus peptide-specific CD8(+) T-lymphocytes from the peripheral blood of healthy, human trophic leukemia virus-1 (HTLV-1) seronegative human leucocyte antigen (HLA)-A*0201 individuals. A combination of density-based separation and culture conditions was employed to isolate dendritic cells (DCs), which are the most potent antigen-presenting cells (APCs), and T-lymphocytes. The DCs were pulsed with HLA-A*0201 binding peptides and cultured with autologous T-lymphocytes to generate peptide-specific CTLs. The CTLs were generated against a nine-amino-acid peptide from the Tax protein of HTLV-1. The CTLs were expanded according to a restimulation schedule employing peptide-pulsed autologous monocytes and low-dose interleukin-2 (IL-2) to numbers in excess of 100 x 10(6) cells following 5 weeks of culture. Expanded cells contained primarily CD3(+) T-cells, of which CD8(+) T-lymphocytes constituted greater than two-thirds of the cell population. Obtained CTLs exhibited potent antigen-specific lysis of peptide-pulsed target cells in a dose-dependent fashion in in vitro (51)Cr release cytotoxicity assay. This antigen-specific killing was shown to be HLA class I restricted and mediated by CD8(+) T-lymphocytes. Since the T-lymphocytes were obtained from HTLV-1 seronegative donors, the generation of peptide-specific CTLs represents reliable and reproducible elicitation of a primary immune response in vitro against naive antigens and subsequent expansion of generated CTLs for adoptive immunotherapy. (c) 1996 John Wiley & Sons, Inc.     

Irradiation of tumor cells up-regulates Fas and enhances CTL lytic activity and CTL adoptive immunotherapy

CD8(+) CTL play important roles against malignancy in both active and passive immunotherapy. Nonetheless, the success of antitumor CTL responses may be improved by additional therapeutic modalities. Radiotherapy, which has a long-standing use in treating neoplastic disease, has been found to induce unique biologic alterations in cancer cells affecting Fas gene expression, which, consequently, may influence the overall lytic efficiency of CTL. Here, in a mouse adenocarcinoma cell model, we examined whether exposure of these tumor cells to sublethal doses of irradiation 1) enhances Fas expression, leading to more efficient CTL killing via Fas-dependent mechanisms in vitro; and 2) improves antitumor activity in vivo by adoptive transfer of these Ag-specific CTL. Treatment of carcinoembryonic Ag-expressing MC38 adenocarcinoma cells with irradiation (20 Gy) in vitro enhanced Fas expression at molecular, phenotypic, and functional levels. Furthermore, irradiation sensitized these targets to Ag-specific CTL killing via the Fas/Fas ligand pathway. We examined the effect of localized irradiation of s.c. growing tumors on the efficiency of CTL adoptive immunotherapy. Irradiation caused up-regulation of Fas by these tumor cells in situ, based on immunohistochemistry. Moreover, localized irradiation of the tumor significantly potentiated tumor rejection by these carcinoembryonic Ag-specific CTL. Overall, these results showed for the first time that 1) regulation of the Fas pathway in tumor cells by irradiation plays an important role in their sensitization to Ag-specific CTL; and 2) a combination regimen of tumor-targeted irradiation and CTL promotes more effective antitumor responses in vivo, which may have implications for the combination of immunotherapy and radiation therapy.     

Ex vivo expansion of non-MHC-restricted cytotoxic effector cells as adoptive immunotherapy for myeloma

BACKGROUND: PBMC can be expanded ex vivo into aggressive cytotoxic effector cells (CEC) comprising T, NK and NKT cells. We identified the phenotype, cytotoxicity and mechanisms of killing of these CEC. METHODS: CY- and G-CSF-mobilized PBMC from myeloma patients were placed in Aim-V serum-free medium, IL-2 (50 IU/mL) and OKT-3 (50 ng/mL). Cytotoxicity was evaluated by selectively blocking the TCR, MHC class I or NKG2D receptor. RESULTS: The CEC expanded three-fold by day 7 and aggressively lysed myeloma cells (41.9%) compared with day 0 (4%; P=0.012). CD8+ CD56+ NKT cells performed the majority of lysis. The CD8+ cells greatly increased NKG2D expression during culture (P=0.005). Cytotoxicity correlated with target NKG2D ligand expression (P=0.0002). Blocking the TCR or MHC class I did not affect cytotoxicity (P>0.22). CD8+ cell-mediated lysis dropped 48% when the NKG2D receptor was blocked. Day 7 CEC aggressively lysed myeloma cells in an MHC- and non-MHC-restricted fashion, through the NKG2D receptor. DISCUSSION: Because MHC expression is often down-regulated on tumor cells and the NKG2D ligands are generally specific to malignant cells, the adoptive transfer of CEC that kill through different pathways may circumvent tumor-resistant mechanisms and improve outcomes.     

Gene gun application in the generation of effector T cells for adoptive immunotherapy

We utilized the gene gun to transfect subcutaneous D5 melanoma and MT-901 mammary carcinoma tumors in situ with a granulocyte/macrophage-colony-stimulating factor (GM-CSF) plasmid complexed to gold particles. There was diminished tumor growth following bombardment with GM-CSF plasmid, which was apparent only during the period of administration. Transgenic GM-CSF was produced by the skin overlying the tumors and not by the tumors themselves. GM-CSF plasmid bombardment resulted in increased cell yields within tumor-draining lymph nodes (TDLN) with at least a 12-fold increase in the percentage of dendritic cells (8.9%) compared to controls (0.7%). Secondarily activated TDLN cells from animals transfected with GM-CSF demonstrated enhanced cytokine release (interferon γ, GM-CSF and interleukin-10) in response to tumor stimulator cells compared to controls, and had an increased capacity to mediate tumor regression in adoptive immunotherapy. There was a small, but detectable, non-specific immune adjuvant effect observed with gold particle bombardment alone, which was less than with GM-CSF plasmid. The adjuvant effect of GM-CSF plasmid required peri-tumoral transgene expression since gene bombardment away from the tumor was ineffective. Received: 27 April 1999 / Accepted: 27 August 1999     

Memory T cells originate from adoptively transferred effectors and reconstituting host cells after sequential lymphodepletion and adoptive immunotherapy

Adoptive transfer of tumor-specific effector T cells induces regression of advanced tumors and induces a long term memory response; however, the origin of this response has not been clearly defined. In this study Thy1.2+ mice bearing advanced MCA-205 tumors were treated with sublethal total body irradiation, followed by adoptive transfer of congenic Thy1.1+ T cells that had been sensitized to tumor in vivo and then activated ex vivo with anti-CD3, IL-2, and IL-7. Splenocytes were recovered >140 days after the initial therapy, and the L-selectinlow memory cell subset was separated into host Thy1.2+ and transferred Thy1.1+ cells and restimulated ex vivo. Both adoptively transferred Thy1.1+ cells as well as reconstituted host Thy1.2+ cells could specifically eliminate MCA-205 pulmonary metastases. Interestingly, hosts with partial responses followed by tumor recurrence nevertheless harbored memory cells that could be isolated and numerically amplified ex vivo to regenerate potent effector function. Memory cells were recovered after adoptive transfer into lymphodepleted nontumor-bearing hosts, indicating that they were not dependent on continued Ag exposure. These experiments establish that rapid ex vivo expansion of tumor Ag-primed T cells does not abrogate their capacity to become long-lived memory cells. Moreover, immune-mediated tumor regression coincident with lymphoid reconstitution produces another wave of host memory cells. These data suggest an approach to rescuing antitumor immune function even in hosts with long-standing progressive tumor through restorative ex vivo activation.     

Active specific immunotherapy with extracted tumor-specific transplantation antigen, cyclophosphamide, and adoptive transfer of tumor-specific cytotoxic T-cell clones

An L3T4-, Lyt2+ tumor-specific, cloned T-lymphocyte cell line (RTT-2) was isolated from a spleen cell population harvested from C3H/HeJ mice, following in vivo immunization against a syngeneic MCA-induced fibrosarcoma (MCA-F) and in vitro restimulation with 1-butanol-extracted, isoelectrophoretically purified MCA-F tumor-specific transplantation antigen (TSTA). RTT-2 required exposure to homotypic-extracted MCA-F TSTA in combination with low-dose IL-2 to maintain its specific cytotoxic activity in vitro. In vivo local adoptive transfer of RTT-2 caused specific neutralization of homotypic MCA-F, but not heterotypic MCA-D, tumor cells. Systemic in vivo transfer of RTT-2 alone augmented host resistance. In combination with a triple regimen of weekly doses of purified TSTA (1 microgram SC) and a single ip injection of CY (20 mg/kg), adoptive transfer of RTT-2 cells (1 X 10(7)) retarded the neoplastic outgrowth in and prolonged the survival of primary hosts bearing 3-, 7-, and 14-day established MCA-F tumors. In a spontaneous pulmonary metastasis model following amputation of a tumor-bearing limb, the triple regimen of TSTA/CY/RTT-2 markedly reduced the number of lung colonies. Thus RTT-2, which displays specific tumoricidal activity in vitro and in vivo, may afford a suitable tool to dissect T-cell receptors recognizing tumor markers on 1-butanol-extracted, MCA-F TSTA.     

Successful adoptive immunotherapy with OK432-inducible activated natural killer cells in tumor-bearing mice

We had demonstrated that the NK cell mediated cytotoxicity of murine spleen cells could be augmented byin vivo priming and subsequentin vitro challenge with a streptococcal preparation OK432, and the cell surface phenotype of induced killer cells was Thy-1⁺, asialo GM1⁺, suggesting that the activated cells were of NK lineage (OK-NK cell). We had also clarified that IL-2 played a major role in inducing the OK-NK cells via the production of IFN-. In this study, we examined the effect of adoptive transfer of OK-NK cells on syngeneic tumors in mice. Mice were implanted with SP2 myeloma cells intraperitoneally (i.p.), or C26 colon adenocarcinoma cells subcutaneously to make the models of peritonitis carcinomatosa or solid tumor, and the OK-NK cells were transferred i.p. or intratumorally, adoptively. By the adoptive transfer of OK-NK cells, 92% of mice bearing SP2-tumor had be cured. The tumor growth of C26-solid tumor was inhibited, and the survival rate of mice bearing C26-tumor was significantly increased. The intratumoral remnants of¹²⁵I-labelled OK-NK cells were 61, 27 and 8% at 4, 12 and 36h after intratumoral transfer, respectively. By multiple transfer of OK-NK cells, the antitumor effect was more effectively augmented than that of a single transfer. Results in this study suggested that OK-NK cells could be useful for the therapy of cancer patients.     

Adverse events following infusion of T cells for adoptive immunotherapy: a 10-year experience

Background aimsThe Food and Drug Administration (FDA) currently recommends at least 4 h of recipient monitoring after T cell infusions to detect early infusion reactions. Recent catastrophic reactions to ‘first-in-man’ biologic agents have emphasized the importance of this rule for initial studies of new products. The value of such monitoring for better established agents is less obvious.MethodsWe reviewed infusion-related adverse events (AE) following administration of ex vivo-expanded T cell products (antigen-specific cytotoxic T lymphocytes, allodepleted T cells, and genetically modified T cells) on investigational new drug (IND) studies in our center.ResultsFrom 1998 to 2008, we infused 381 T cell products to 180 recipients, enrolled on 18 studies, receiving T cells targeting malignancies or post-transplant viral infections. There were no grade 3–4 infusion reactions during initial monitoring or 24-h follow-up. Twenty-four mild (grade 1–2) AE occurred in 21 infusions either during or immediately following infusion (up to 6 h), most commonly nausea and vomiting (10/24, 41.6%), probably because of the dimethyl sulfoxide cryoprotectant, and hypotension (20.8%), attributable to diphenhydramine pre-medication. Twenty-two additional non-severe events were reported within 24 h of infusion, most commonly culture-negative fever, chills and nausea. An increased risk of adverse events was associated with age [incidence rate ratio (IRR) 0.98; 95% confidence interval (CI) 0.96–1.00, P = 0.05], while an increased risk of immediate infusion-related events was higher in patients reporting allergies (IRR 2.72, 95% CI 1.00–7.40, P = 0.05); sex, disease type and T cell source (allogeneic or autologous) had no effect on frequency of adverse events.ConclusionsInfusion of these T cell products was safe in the outpatient setting and associated with no severe reactions, so monitoring for 1 h after infusion is probably sufficient. As many of the AE were attributable to diphenhydramine premedication, a lower dose (0.25 mg/kg) should be selected.     

In vitro generation of influenza-specific polyfunctional CD4+ T cells suitable for adoptive immunotherapy

Background aimsInfluenza viruses cause potentially fatal respiratory infections in stem cell transplant patients. Specific T cells provide long-lived host adaptive immunity to influenza viruses, and the potential for generating such cells for clinical use was investigatedMethodsThe inactivated influenza vaccine (Fluvax) approved for human use was used as the antigen source. Monocyte-derived dendritic cells pulsed with Fluvax were used to stimulate autologous peripheral blood mononuclear cells (PBMC) on days 0 and 7. Cells were expanded with interleukin (IL)-2 from day 7 onwards. Cell numbers and phenotype were assessed on day 21. The presence of influenza virus-specific cells was assessed by cytokine production and proliferative responses following restimulation with influenza antigensResultsOver 21 days of culture, a mean fold increase of 26.3 in cell number was observed (n = 7). Cultures were predominantly effector and central memory CD4⁺ cells, and expressed a phenotype characteristic of activated antigen-specific cells capable of B-cell helper function. Cytotoxic CD4⁺ and CD8⁺ cells specific for influenza and a high percentage of CD4⁺ cells specific for each of three influenza viruses targeted by Fluvax (H1N1, H3N2 and Brisbane viruses) were generated. In addition, T cells expanded when restimulated with antigens derived from influenza viruses.ConclusionsWe have demonstrated a clinically usable method for producing influenza virus-specific T cells that yield high numbers of highly reactive CD4⁺ cells suitable for adoptive immunotherapy. We propose that reconstructing host immunity through adoptive transfer of influenza virus-specific T cells will reduce the frequency of influenza-related deaths in the period of severe immune suppression that follows stem cell transplantation.     

CTL adoptive immunotherapy concurrently mediates tumor regression and tumor escape

Tumor escape and recurrence are major impediments for successful immunotherapy. It is well-documented that the emergence of Ag-loss variants, as well as regulatory mechanisms suppressing T cell function, have been linked to inadequate antitumor activity. However, little is known regarding the role of Fas-mediated cytotoxicity by tumor-specific CD8(+) CTL in causing immune evasion of Fas resistant variants during adoptive immunotherapy. In this study, we made use of an adoptive transfer model of experimental lung metastasis using tumor-specific CTL as a relevant immune-based selective pressure, and wherein the Fas ligand pathway was involved in the antitumor response. Surviving tumor cells were recovered and examined for alterations in antigenic, functional, and biologic properties. We showed that diminished susceptibility to Fas-mediated cytotoxicity in vivo was an important determinant of tumor escape following CTL-based immunotherapy. Tumor escape variants (TEV) recovered from the lungs of CTL-treated mice exhibited more aggressive behavior in vivo. However, these TEV retained relevant MHC class I and tumor Ag expression and sensitivity to CTL via the perforin pathway but reduced susceptibility to Fas-mediated lysis. Moreover, TEV were significantly less responsive to eradication by CTL adoptive immunotherapy paradigms as a consequence of increased Fas resistance. Overall, we identified that Fas(low)-TEV emerged as a direct consequence of CTL-tumor interactions in vivo, and that such an altered neoplastic Fas phenotype compromised immunotherapy efficacy. Together, these findings may have important implications for both tumor progression and the design of immunotherapeutic interventions to confront these selective pressures or escape mechanisms.